def test_build_stats_sparse(self):
history = self._build_history(1.145, cat_accuracy_sparse=.99988)
eval_output = self._build_eval_output(.928, 1.9844)
stats = common.build_stats(history, eval_output, None)
self.assertEqual(1.145, stats['loss'])
self.assertEqual(.99988, stats['training_accuracy_top_1'])
self.assertEqual(.928, stats['accuracy_top_1'])
self.assertEqual(1.9844, stats['eval_loss'])
def test_build_stats(self):
history = self._build_history(1.145, cat_accuracy=.99988)
eval_output = self._build_eval_output(.56432111, 5.990)
th = keras_utils.TimeHistory(128, 100)
th.timestamp_log = [
keras_utils.BatchTimestamp(0, 1),
keras_utils.BatchTimestamp(1, 2),
keras_utils.BatchTimestamp(2, 3)
]
th.train_finish_time = 12345
stats = common.build_stats(history, eval_output, [th])
self.assertEqual(1.145, stats['loss'])
self.assertEqual(.99988, stats['training_accuracy_top_1'])
self.assertEqual(.56432111, stats['accuracy_top_1'])
self.assertEqual(5.990, stats['eval_loss'])
self.assertEqual(3, stats['step_timestamp_log'][2].timestamp)
self.assertEqual(12345, stats['train_finish_time'])
def run(flags_obj):
"""Run ResNet ImageNet training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
common.set_gpu_thread_mode_and_count(flags_obj)
if flags_obj.data_delay_prefetch:
common.data_delay_prefetch()
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == 'float16':
policy = tf.keras.mixed_precision.experimental.Policy(
'infer_float32_vars')
tf.keras.mixed_precision.experimental.set_policy(policy)
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
# Configures cluster spec for distribution strategy.
num_workers = distribution_utils.configure_cluster(flags_obj.worker_hosts,
flags_obj.task_index)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
num_workers=num_workers,
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
# pylint: disable=protected-access
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
width=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
num_channels=imagenet_preprocessing.NUM_CHANNELS,
num_classes=imagenet_preprocessing.NUM_CLASSES,
dtype=dtype,
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = imagenet_preprocessing.input_fn
# When `enable_xla` is True, we always drop the remainder of the batches
# in the dataset, as XLA-GPU doesn't support dynamic shapes.
drop_remainder = flags_obj.enable_xla
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=imagenet_preprocessing.parse_record,
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
drop_remainder=drop_remainder,
tf_data_experimental_slack=flags_obj.tf_data_experimental_slack,
)
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=imagenet_preprocessing.parse_record,
dtype=dtype,
drop_remainder=drop_remainder)
lr_schedule = 0.1
if flags_obj.use_tensor_lr:
lr_schedule = common.PiecewiseConstantDecayWithWarmup(
batch_size=flags_obj.batch_size,
epoch_size=imagenet_preprocessing.NUM_IMAGES['train'],
warmup_epochs=LR_SCHEDULE[0][1],
boundaries=list(p[1] for p in LR_SCHEDULE[1:]),
multipliers=list(p[0] for p in LR_SCHEDULE),
compute_lr_on_cpu=True)
with strategy_scope:
optimizer = common.get_optimizer(lr_schedule)
if dtype == 'float16':
# TODO(reedwm): Remove manually wrapping optimizer once mixed precision
# can be enabled with a single line of code.
optimizer = tf.keras.mixed_precision.experimental.LossScaleOptimizer(
optimizer,
loss_scale=flags_core.get_loss_scale(flags_obj,
default_for_fp16=128))
if flags_obj.use_trivial_model:
model = trivial_model.trivial_model(
imagenet_preprocessing.NUM_CLASSES, dtype)
else:
model = resnet_model.resnet50(
num_classes=imagenet_preprocessing.NUM_CLASSES, dtype=dtype)
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
if flags_obj.force_v2_in_keras_compile is not None:
model.compile(
loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=(['sparse_categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=flags_obj.
force_v2_in_keras_compile)
else:
model.compile(
loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=(['sparse_categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly)
callbacks = common.get_callbacks(
learning_rate_schedule, imagenet_preprocessing.NUM_IMAGES['train'])
train_steps = (imagenet_preprocessing.NUM_IMAGES['train'] //
flags_obj.batch_size)
train_epochs = flags_obj.train_epochs
if flags_obj.train_steps:
train_steps = min(flags_obj.train_steps, train_steps)
train_epochs = 1
num_eval_steps = (imagenet_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
# Only build the training graph. This reduces memory usage introduced by
# control flow ops in layers that have different implementations for
# training and inference (e.g., batch norm).
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
if not strategy and flags_obj.explicit_gpu_placement:
# TODO(b/135607227): Add device scope automatically in Keras training loop
# when not using distribition strategy.
no_dist_strat_device = tf.device('/device:GPU:0')
no_dist_strat_device.__enter__()
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=train_steps // 15,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=1)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=1)
if not strategy and flags_obj.explicit_gpu_placement:
no_dist_strat_device.__exit__()
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet ImageNet training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(
enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
common.set_gpu_thread_mode_and_count(flags_obj)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == tf.float16:
loss_scale = flags_core.get_loss_scale(flags_obj, default_for_fp16=128)
policy = tf.compat.v2.keras.mixed_precision.experimental.Policy(
'mixed_float16', loss_scale=loss_scale)
tf.compat.v2.keras.mixed_precision.experimental.set_policy(policy)
if not keras_utils.is_v2_0():
raise ValueError('--dtype=fp16 is not supported in TensorFlow 1.')
elif dtype == tf.bfloat16:
policy = tf.compat.v2.keras.mixed_precision.experimental.Policy(
'mixed_bfloat16')
tf.compat.v2.keras.mixed_precision.experimental.set_policy(policy)
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
# Configures cluster spec for distribution strategy.
num_workers = distribution_utils.configure_cluster(flags_obj.worker_hosts,
flags_obj.task_index)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
num_workers=num_workers,
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs,
tpu_address=flags_obj.tpu)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional
)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
# pylint: disable=protected-access
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
width=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
num_channels=imagenet_preprocessing.NUM_CHANNELS,
num_classes=imagenet_preprocessing.NUM_CLASSES,
dtype=dtype,
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = imagenet_preprocessing.input_fn
# When `enable_xla` is True, we always drop the remainder of the batches
# in the dataset, as XLA-GPU doesn't support dynamic shapes.
drop_remainder = flags_obj.enable_xla
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=imagenet_preprocessing.parse_record,
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
drop_remainder=drop_remainder,
tf_data_experimental_slack=flags_obj.tf_data_experimental_slack,
training_dataset_cache=flags_obj.training_dataset_cache,
)
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=imagenet_preprocessing.parse_record,
dtype=dtype,
drop_remainder=drop_remainder)
lr_schedule = 0.1
if flags_obj.use_tensor_lr:
lr_schedule = common.PiecewiseConstantDecayWithWarmup(
batch_size=flags_obj.batch_size,
epoch_size=imagenet_preprocessing.NUM_IMAGES['train'],
warmup_epochs=common.LR_SCHEDULE[0][1],
boundaries=list(p[1] for p in common.LR_SCHEDULE[1:]),
multipliers=list(p[0] for p in common.LR_SCHEDULE),
compute_lr_on_cpu=True)
with strategy_scope:
optimizer = common.get_optimizer(lr_schedule)
if flags_obj.fp16_implementation == 'graph_rewrite':
# Note: when flags_obj.fp16_implementation == "graph_rewrite", dtype as
# determined by flags_core.get_tf_dtype(flags_obj) would be 'float32'
# which will ensure tf.compat.v2.keras.mixed_precision and
# tf.train.experimental.enable_mixed_precision_graph_rewrite do not double
# up.
optimizer = tf.train.experimental.enable_mixed_precision_graph_rewrite(
optimizer)
# TODO(hongkuny): Remove trivial model usage and move it to benchmark.
if flags_obj.use_trivial_model:
model = trivial_model.trivial_model(
imagenet_preprocessing.NUM_CLASSES)
else:
model = resnet_model.resnet50(
num_classes=imagenet_preprocessing.NUM_CLASSES)
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
if flags_obj.force_v2_in_keras_compile is not None:
model.compile(
loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=(['sparse_categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=flags_obj.force_v2_in_keras_compile)
else:
model.compile(
loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=(['sparse_categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly)
steps_per_epoch = (
imagenet_preprocessing.NUM_IMAGES['train'] // flags_obj.batch_size)
train_epochs = flags_obj.train_epochs
callbacks = common.get_callbacks(steps_per_epoch,
common.learning_rate_schedule)
if flags_obj.enable_checkpoint_and_export:
ckpt_full_path = os.path.join(flags_obj.model_dir, 'model.ckpt-{epoch:04d}')
callbacks.append(tf.keras.callbacks.ModelCheckpoint(ckpt_full_path,
save_weights_only=True))
# if mutliple epochs, ignore the train_steps flag.
if train_epochs <= 1 and flags_obj.train_steps:
steps_per_epoch = min(flags_obj.train_steps, steps_per_epoch)
train_epochs = 1
num_eval_steps = (
imagenet_preprocessing.NUM_IMAGES['validation'] // flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
# Only build the training graph. This reduces memory usage introduced by
# control flow ops in layers that have different implementations for
# training and inference (e.g., batch norm).
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
if not strategy and flags_obj.explicit_gpu_placement:
# TODO(b/135607227): Add device scope automatically in Keras training loop
# when not using distribition strategy.
no_dist_strat_device = tf.device('/device:GPU:0')
no_dist_strat_device.__enter__()
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=steps_per_epoch,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=2)
if flags_obj.enable_checkpoint_and_export:
if dtype == tf.bfloat16:
logging.warning("Keras model.save does not support bfloat16 dtype.")
else:
# Keras model.save assumes a float32 input designature.
export_path = os.path.join(flags_obj.model_dir, 'saved_model')
model.save(export_path, include_optimizer=False)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
if not strategy and flags_obj.explicit_gpu_placement:
no_dist_strat_device.__exit__()
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet Cifar-10 training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(
enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
keras_utils.set_gpu_thread_mode_and_count(
per_gpu_thread_count=flags_obj.per_gpu_thread_count,
gpu_thread_mode=flags_obj.tf_gpu_thread_mode,
num_gpus=flags_obj.num_gpus,
datasets_num_private_threads=flags_obj.datasets_num_private_threads)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == 'fp16':
raise ValueError('dtype fp16 is not supported in Keras. Use the default '
'value(fp32).')
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional
)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=cifar_preprocessing.HEIGHT,
width=cifar_preprocessing.WIDTH,
num_channels=cifar_preprocessing.NUM_CHANNELS,
num_classes=cifar_preprocessing.NUM_CLASSES,
dtype=flags_core.get_tf_dtype(flags_obj),
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = cifar_preprocessing.input_fn
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
parse_record_fn=cifar_preprocessing.parse_record,
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
# Setting drop_remainder to avoid the partial batch logic in normalization
# layer, which triggers tf.where and leads to extra memory copy of input
# sizes between host and GPU.
drop_remainder=(not flags_obj.enable_get_next_as_optional))
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
parse_record_fn=cifar_preprocessing.parse_record)
steps_per_epoch = (
cifar_preprocessing.NUM_IMAGES['train'] // flags_obj.batch_size)
lr_schedule = 0.1
if flags_obj.use_tensor_lr:
initial_learning_rate = common.BASE_LEARNING_RATE * flags_obj.batch_size / 128
lr_schedule = tf.keras.optimizers.schedules.PiecewiseConstantDecay(
boundaries=list(p[1] * steps_per_epoch for p in LR_SCHEDULE),
values=[initial_learning_rate] +
list(p[0] * initial_learning_rate for p in LR_SCHEDULE))
with strategy_scope:
optimizer = common.get_optimizer(lr_schedule)
model = resnet_cifar_model.resnet56(classes=cifar_preprocessing.NUM_CLASSES)
model.compile(
loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=(['sparse_categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly)
train_epochs = flags_obj.train_epochs
callbacks = common.get_callbacks(steps_per_epoch)
if not flags_obj.use_tensor_lr:
lr_callback = LearningRateBatchScheduler(
schedule=learning_rate_schedule,
batch_size=flags_obj.batch_size,
steps_per_epoch=steps_per_epoch)
callbacks.append(lr_callback)
# if mutliple epochs, ignore the train_steps flag.
if train_epochs <= 1 and flags_obj.train_steps:
steps_per_epoch = min(flags_obj.train_steps, steps_per_epoch)
train_epochs = 1
num_eval_steps = (cifar_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
if not strategy and flags_obj.explicit_gpu_placement:
# TODO(b/135607227): Add device scope automatically in Keras training loop
# when not using distribition strategy.
no_dist_strat_device = tf.device('/device:GPU:0')
no_dist_strat_device.__enter__()
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=steps_per_epoch,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=2)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
if not strategy and flags_obj.explicit_gpu_placement:
no_dist_strat_device.__exit__()
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet ImageNet training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
NotImplementedError: If some features are not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
keras_utils.set_gpu_thread_mode_and_count(
per_gpu_thread_count=flags_obj.per_gpu_thread_count,
gpu_thread_mode=flags_obj.tf_gpu_thread_mode,
num_gpus=flags_obj.num_gpus,
datasets_num_private_threads=flags_obj.datasets_num_private_threads
)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
performance.set_mixed_precision_policy(
flags_core.get_tf_dtype(flags_obj),
flags_core.get_loss_scale(flags_obj, default_for_fp16=128))
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
# Configures cluster spec for distribution strategy.
_ = distribution_utils.configure_cluster(flags_obj.worker_hosts,
flags_obj.task_index)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs,
tpu_address=flags_obj.tpu)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
# pylint: disable=protected-access
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
width=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
num_channels=imagenet_preprocessing.NUM_CHANNELS,
num_classes=imagenet_preprocessing.NUM_CLASSES,
dtype=dtype,
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = imagenet_preprocessing.input_fn
# When `enable_xla` is True, we always drop the remainder of the batches
# in the dataset, as XLA-GPU doesn't support dynamic shapes.
drop_remainder = flags_obj.enable_xla
# Current resnet_model.resnet50 input format is always channel-last.
# We use keras_application mobilenet model which input format is depends on
# the keras beckend image data format.
# This use_keras_image_data_format flags indicates whether image preprocessor
# output format should be same as the keras backend image data format or just
# channel-last format.
use_keras_image_data_format = (flags_obj.model == 'mobilenet')
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
parse_record_fn=imagenet_preprocessing.get_parse_record_fn(
use_keras_image_data_format=use_keras_image_data_format),
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
drop_remainder=drop_remainder,
tf_data_experimental_slack=flags_obj.tf_data_experimental_slack,
training_dataset_cache=flags_obj.training_dataset_cache,
)
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
parse_record_fn=imagenet_preprocessing.get_parse_record_fn(
use_keras_image_data_format=use_keras_image_data_format),
dtype=dtype,
drop_remainder=drop_remainder)
lr_schedule = common.PiecewiseConstantDecayWithWarmup(
batch_size=flags_obj.batch_size,
epoch_size=imagenet_preprocessing.NUM_IMAGES['train'],
warmup_epochs=common.LR_SCHEDULE[0][1],
boundaries=list(p[1] for p in common.LR_SCHEDULE[1:]),
multipliers=list(p[0] for p in common.LR_SCHEDULE),
compute_lr_on_cpu=True)
steps_per_epoch = (imagenet_preprocessing.NUM_IMAGES['train'] //
flags_obj.batch_size)
with strategy_scope:
if flags_obj.optimizer == 'resnet50_default':
optimizer = common.get_optimizer(lr_schedule)
elif flags_obj.optimizer == 'mobilenet_default':
initial_learning_rate = \
flags_obj.initial_learning_rate_per_sample * flags_obj.batch_size
optimizer = tf.keras.optimizers.SGD(
learning_rate=tf.keras.optimizers.schedules.ExponentialDecay(
initial_learning_rate,
decay_steps=steps_per_epoch *
flags_obj.num_epochs_per_decay,
decay_rate=flags_obj.lr_decay_factor,
staircase=True),
momentum=0.9)
if flags_obj.fp16_implementation == 'graph_rewrite':
# Note: when flags_obj.fp16_implementation == "graph_rewrite", dtype as
# determined by flags_core.get_tf_dtype(flags_obj) would be 'float32'
# which will ensure tf.compat.v2.keras.mixed_precision and
# tf.train.experimental.enable_mixed_precision_graph_rewrite do not double
# up.
optimizer = tf.train.experimental.enable_mixed_precision_graph_rewrite(
optimizer)
# TODO(hongkuny): Remove trivial model usage and move it to benchmark.
if flags_obj.use_trivial_model:
model = trivial_model.trivial_model(
imagenet_preprocessing.NUM_CLASSES)
elif flags_obj.model == 'resnet50_v1.5':
resnet_model.change_keras_layer(flags_obj.use_tf_keras_layers)
model = resnet_model.resnet50(
num_classes=imagenet_preprocessing.NUM_CLASSES)
elif flags_obj.model == 'mobilenet':
# TODO(kimjaehong): Remove layers attribute when minimum TF version
# support 2.0 layers by default.
model = tf.keras.applications.mobilenet.MobileNet(
weights=None,
classes=imagenet_preprocessing.NUM_CLASSES,
layers=tf.keras.layers)
if flags_obj.pretrained_filepath:
model.load_weights(flags_obj.pretrained_filepath)
if flags_obj.pruning_method == 'polynomial_decay':
if dtype != tf.float32:
raise NotImplementedError(
'Pruning is currently only supported on dtype=tf.float32.')
pruning_params = {
'pruning_schedule':
tfmot.sparsity.keras.PolynomialDecay(
initial_sparsity=flags_obj.pruning_initial_sparsity,
final_sparsity=flags_obj.pruning_final_sparsity,
begin_step=flags_obj.pruning_begin_step,
end_step=flags_obj.pruning_end_step,
frequency=flags_obj.pruning_frequency),
}
model = tfmot.sparsity.keras.prune_low_magnitude(
model, **pruning_params)
elif flags_obj.pruning_method:
raise NotImplementedError(
'Only polynomial_decay is currently supported.')
model.compile(loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=(['sparse_categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly)
train_epochs = flags_obj.train_epochs
callbacks = common.get_callbacks(
steps_per_epoch=steps_per_epoch,
pruning_method=flags_obj.pruning_method,
enable_checkpoint_and_export=flags_obj.enable_checkpoint_and_export,
model_dir=flags_obj.model_dir)
# if mutliple epochs, ignore the train_steps flag.
if train_epochs <= 1 and flags_obj.train_steps:
steps_per_epoch = min(flags_obj.train_steps, steps_per_epoch)
train_epochs = 1
num_eval_steps = (imagenet_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
# Only build the training graph. This reduces memory usage introduced by
# control flow ops in layers that have different implementations for
# training and inference (e.g., batch norm).
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
if not strategy and flags_obj.explicit_gpu_placement:
# TODO(b/135607227): Add device scope automatically in Keras training loop
# when not using distribition strategy.
no_dist_strat_device = tf.device('/device:GPU:0')
no_dist_strat_device.__enter__()
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=steps_per_epoch,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=2)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
if flags_obj.pruning_method:
model = tfmot.sparsity.keras.strip_pruning(model)
if flags_obj.enable_checkpoint_and_export:
if dtype == tf.bfloat16:
logging.warning(
'Keras model.save does not support bfloat16 dtype.')
else:
# Keras model.save assumes a float32 input designature.
export_path = os.path.join(flags_obj.model_dir, 'saved_model')
model.save(export_path, include_optimizer=False)
if not strategy and flags_obj.explicit_gpu_placement:
no_dist_strat_device.__exit__()
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet ImageNet training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
keras_utils.set_gpu_thread_mode_and_count(
per_gpu_thread_count=flags_obj.per_gpu_thread_count,
gpu_thread_mode=flags_obj.tf_gpu_thread_mode,
num_gpus=flags_obj.num_gpus,
datasets_num_private_threads=flags_obj.datasets_num_private_threads
)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == tf.float16:
loss_scale = flags_core.get_loss_scale(flags_obj, default_for_fp16=128)
policy = tf.compat.v2.keras.mixed_precision.experimental.Policy(
'mixed_float16', loss_scale=loss_scale)
tf.compat.v2.keras.mixed_precision.experimental.set_policy(policy)
if not keras_utils.is_v2_0():
raise ValueError('--dtype=fp16 is not supported in TensorFlow 1.')
elif dtype == tf.bfloat16:
policy = tf.compat.v2.keras.mixed_precision.experimental.Policy(
'mixed_bfloat16')
tf.compat.v2.keras.mixed_precision.experimental.set_policy(policy)
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
preprocessing_seed = 12345
# pylint: disable=protected-access
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
width=imagenet_preprocessing.DEFAULT_IMAGE_SIZE,
num_channels=imagenet_preprocessing.NUM_CHANNELS,
num_classes=imagenet_preprocessing.NUM_CLASSES,
dtype=dtype,
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = imagenet_preprocessing.input_fn
# When `enable_xla` is True, we always drop the remainder of the batches
# in the dataset, as XLA-GPU doesn't support dynamic shapes.
drop_remainder = flags_obj.enable_xla
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=imagenet_preprocessing.parse_record,
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
drop_remainder=drop_remainder,
random_seed=preprocessing_seed, #addition
num_workers=current_cluster_size(), #addition
worker_ID=current_rank(), #addition
tf_data_experimental_slack=flags_obj.tf_data_experimental_slack,
training_dataset_cache=flags_obj.training_dataset_cache,
)
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=imagenet_preprocessing.parse_record,
dtype=dtype,
drop_remainder=drop_remainder)
lr_schedule = 0.1
if flags_obj.use_tensor_lr:
lr_schedule = common.PiecewiseConstantDecayWithWarmup(
batch_size=flags_obj.batch_size,
epoch_size=imagenet_preprocessing.NUM_IMAGES['train'],
warmup_epochs=common.LR_SCHEDULE[0][1],
boundaries=list(p[1] for p in common.LR_SCHEDULE[1:]),
multipliers=list(p[0] for p in common.LR_SCHEDULE),
compute_lr_on_cpu=True)
# Build KungFu optimizer
opt = common.get_optimizer(lr_schedule)
# logging.info(opt.__dict__)
optimizer = SynchronousSGDOptimizer(opt, reshape=False, use_locking=True)
optimizer._hyper = opt._hyper
# logging.info(optimizer.__dict__)
if flags_obj.fp16_implementation == 'graph_rewrite':
# Note: when flags_obj.fp16_implementation == "graph_rewrite", dtype as
# determined by flags_core.get_tf_dtype(flags_obj) would be 'float32'
# which will ensure tf.compat.v2.keras.mixed_precision and
# tf.train.experimental.enable_mixed_precision_graph_rewrite do not double
# up.
optimizer = tf.train.experimental.enable_mixed_precision_graph_rewrite(
optimizer)
# TODO(hongkuny): Remove trivial model usage and move it to benchmark.
if flags_obj.use_trivial_model:
model = trivial_model.trivial_model(imagenet_preprocessing.NUM_CLASSES)
else:
model = resnet_model.resnet50(
num_classes=imagenet_preprocessing.NUM_CLASSES)
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
metrics = (['sparse_categorical_accuracy'])
metrics.append('sparse_top_k_categorical_accuracy')
if flags_obj.force_v2_in_keras_compile is not None:
model.compile(
loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=metrics,
run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=flags_obj.force_v2_in_keras_compile)
else:
model.compile(loss='sparse_categorical_crossentropy',
optimizer=optimizer,
metrics=metrics,
run_eagerly=flags_obj.run_eagerly)
# adjust number of steps
cluster_size = current_cluster_size()
steps_per_epoch = (imagenet_preprocessing.NUM_IMAGES['train'] //
flags_obj.batch_size)
steps_per_epoch = steps_per_epoch // cluster_size
train_epochs = flags_obj.train_epochs
callbacks = common.get_callbacks(steps_per_epoch, current_rank(),
cluster_size,
common.learning_rate_schedule)
# Broadcast variables for KungFu
callbacks.append(BroadcastGlobalVariablesCallback())
# Checkpoint callback only on worker 0
if flags_obj.enable_checkpoint_and_export and current_rank() == 0:
ckpt_full_path = os.path.join(flags_obj.model_dir,
'model.ckpt-{epoch:04d}')
callbacks.append(
tf.keras.callbacks.ModelCheckpoint(ckpt_full_path,
save_weights_only=True))
if flags_obj.train_steps:
steps_per_epoch = min(flags_obj.train_steps, steps_per_epoch)
num_eval_steps = (imagenet_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
# Only build the training graph. This reduces memory usage introduced by
# control flow ops in layers that have different implementations for
# training and inference (e.g., batch norm).
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=steps_per_epoch,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=2)
# Checkpoint only on 0th worker
if flags_obj.enable_checkpoint_and_export and current_rank() == 0:
if dtype == tf.bfloat16:
logging.warning(
"Keras model.save does not support bfloat16 dtype.")
else:
# Keras model.save assumes a float32 input designature.
export_path = os.path.join(flags_obj.model_dir, 'saved_model')
model.save(export_path, include_optimizer=False)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet Cifar-10 training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
common.set_gpu_thread_mode_and_count(flags_obj)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == 'fp16':
raise ValueError(
'dtype fp16 is not supported in Keras. Use the default '
'value(fp32).')
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
num_workers=distribution_utils.configure_cluster(),
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=cifar_preprocessing.HEIGHT,
width=cifar_preprocessing.WIDTH,
num_channels=cifar_preprocessing.NUM_CHANNELS,
num_classes=cifar_preprocessing.NUM_CLASSES,
dtype=flags_core.get_tf_dtype(flags_obj),
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = cifar_preprocessing.input_fn
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=cifar_preprocessing.parse_record,
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
# Setting drop_remainder to avoid the partial batch logic in normalization
# layer, which triggers tf.where and leads to extra memory copy of input
# sizes between host and GPU.
drop_remainder=(not flags_obj.enable_get_next_as_optional))
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=cifar_preprocessing.parse_record)
with strategy_scope:
optimizer = common.get_optimizer(learning_rate=0.1 * hvd.size())
# Horovod: add Horovod DistributedOptimizer.
optimizer = hvd.DistributedOptimizer(optimizer)
model = resnet_cifar_model.resnet56(
classes=cifar_preprocessing.NUM_CLASSES)
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
if flags_obj.force_v2_in_keras_compile is not None:
model.compile(
loss='categorical_crossentropy',
optimizer=optimizer,
metrics=(['categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
#run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=False)
else:
model.compile(
loss='categorical_crossentropy',
optimizer=optimizer,
metrics=(['categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
#run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=False)
callbacks = common.get_callbacks(learning_rate_schedule,
cifar_preprocessing.NUM_IMAGES['train'])
train_steps = cifar_preprocessing.NUM_IMAGES[
'train'] // flags_obj.batch_size
train_epochs = flags_obj.train_epochs
if flags_obj.train_steps:
train_steps = min(flags_obj.train_steps, train_steps)
train_epochs = 1
num_eval_steps = (cifar_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
if not strategy and flags_obj.explicit_gpu_placement:
# TODO(b/135607227): Add device scope automatically in Keras training loop
# when not using distribition strategy.
no_dist_strat_device = tf.device('/device:GPU:0')
no_dist_strat_device.__enter__()
callbacks = [
# Horovod: broadcast initial variable states from rank 0 to all other processes.
# This is necessary to ensure consistent initialization of all workers when
# training is started with random weights or restored from a checkpoint.
hvd.callbacks.BroadcastGlobalVariablesCallback(0),
# Horovod: average metrics among workers at the end of every epoch.
#
# Note: This callback must be in the list before the ReduceLROnPlateau,
# TensorBoard or other metrics-based callbacks.
hvd.callbacks.MetricAverageCallback(),
# Horovod: using `lr = 1.0 * hvd.size()` from the very beginning leads to worse final
# accuracy. Scale the learning rate `lr = 1.0` ---> `lr = 1.0 * hvd.size()` during
# the first three epochs. See https://arxiv.org/abs/1706.02677 for details.
hvd.callbacks.LearningRateWarmupCallback(warmup_epochs=3, verbose=1),
]
# Horovod: save checkpoints only on worker 0 to prevent other workers from corrupting them.
if hvd.rank() == 0:
callbacks.append(
tf.keras.callbacks.ModelCheckpoint('./checkpoint-{epoch}.h5'))
# Horovod: write logs on worker 0.
verbose = 1 if hvd.rank() == 0 else 0
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=train_steps,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=verbose)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
if not strategy and flags_obj.explicit_gpu_placement:
no_dist_strat_device.__exit__()
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet Cifar-10 training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
common.set_gpu_thread_mode_and_count(flags_obj)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == 'fp16':
raise ValueError(
'dtype fp16 is not supported in Keras. Use the default '
'value(fp32).')
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
num_workers=distribution_utils.configure_cluster(),
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=cifar_preprocessing.HEIGHT,
width=cifar_preprocessing.WIDTH,
num_channels=cifar_preprocessing.NUM_CHANNELS,
num_classes=cifar_preprocessing.NUM_CLASSES,
dtype=flags_core.get_tf_dtype(flags_obj),
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = cifar_preprocessing.input_fn
train_input_dataset = input_fn(
is_training=True,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=cifar_preprocessing.parse_record,
datasets_num_private_threads=flags_obj.datasets_num_private_threads,
dtype=dtype,
# Setting drop_remainder to avoid the partial batch logic in normalization
# layer, which triggers tf.where and leads to extra memory copy of input
# sizes between host and GPU.
drop_remainder=(not flags_obj.enable_get_next_as_optional))
options = tf.data.Options()
options.experimental_distribute.auto_shard = False
train_input_dataset = train_input_dataset.with_options(options)
eval_input_dataset = None
if not flags_obj.skip_eval:
eval_input_dataset = input_fn(
is_training=False,
data_dir=flags_obj.data_dir,
batch_size=flags_obj.batch_size,
num_epochs=flags_obj.train_epochs,
parse_record_fn=cifar_preprocessing.parse_record)
eval_input_dataset = eval_input_dataset.with_options(options)
with strategy_scope:
optimizer = common.get_optimizer()
model = resnet_cifar_model.resnet56(
classes=cifar_preprocessing.NUM_CLASSES)
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
if flags_obj.force_v2_in_keras_compile is not None:
model.compile(
loss='categorical_crossentropy',
optimizer=optimizer,
metrics=(['categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=flags_obj.
force_v2_in_keras_compile)
else:
model.compile(
loss='categorical_crossentropy',
optimizer=optimizer,
metrics=(['categorical_accuracy']
if flags_obj.report_accuracy_metrics else None),
run_eagerly=flags_obj.run_eagerly)
callbacks = common.get_callbacks(learning_rate_schedule,
cifar_preprocessing.NUM_IMAGES['train'])
train_steps = cifar_preprocessing.NUM_IMAGES[
'train'] // flags_obj.batch_size
train_epochs = flags_obj.train_epochs
if flags_obj.train_steps:
train_steps = min(flags_obj.train_steps, train_steps)
train_epochs = 1
num_eval_steps = (cifar_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
validation_data = eval_input_dataset
if flags_obj.skip_eval:
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
if not strategy and flags_obj.explicit_gpu_placement:
# TODO(b/135607227): Add device scope automatically in Keras training loop
# when not using distribition strategy.
no_dist_strat_device = tf.device('/device:GPU:0')
no_dist_strat_device.__enter__()
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=train_steps,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=validation_data,
validation_freq=flags_obj.epochs_between_evals,
verbose=2)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
if not strategy and flags_obj.explicit_gpu_placement:
no_dist_strat_device.__exit__()
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj, datasets_override=None, strategy_override=None):
"""Run MNIST model training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
datasets_override: A pair of `tf.data.Dataset` objects to train the model,
representing the train and test sets.
strategy_override: A `tf.distribute.Strategy` object to use for model.
Returns:
Dictionary of training and eval stats.
"""
strategy = strategy_override or distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
tpu_address=flags_obj.tpu)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
mnist = tfds.builder('mnist', data_dir=flags_obj.data_dir)
if flags_obj.download:
mnist.download_and_prepare()
mnist_train, mnist_test = datasets_override or mnist.as_dataset(
split=['train', 'test'],
decoders={'image': decode_image()}, # pylint: disable=no-value-for-parameter
as_supervised=True)
train_input_dataset = mnist_train.cache().repeat().shuffle(
buffer_size=50000).batch(flags_obj.batch_size)
eval_input_dataset = mnist_test.cache().repeat().batch(
flags_obj.batch_size)
with strategy_scope:
lr_schedule = tf.keras.optimizers.schedules.ExponentialDecay(
0.05, decay_steps=100000, decay_rate=0.96)
optimizer = tf.keras.optimizers.SGD(learning_rate=lr_schedule)
model = build_model()
model.compile(optimizer=optimizer,
loss='sparse_categorical_crossentropy',
metrics=['sparse_categorical_accuracy'])
num_train_examples = mnist.info.splits['train'].num_examples
train_steps = num_train_examples // flags_obj.batch_size
train_epochs = flags_obj.train_epochs
ckpt_full_path = os.path.join(flags_obj.model_dir,
'model.ckpt-{epoch:04d}')
callbacks = [
tf.keras.callbacks.ModelCheckpoint(ckpt_full_path,
save_weights_only=True),
tf.keras.callbacks.TensorBoard(log_dir=flags_obj.model_dir),
]
num_eval_examples = mnist.info.splits['test'].num_examples
num_eval_steps = num_eval_examples // flags_obj.batch_size
history = model.fit(train_input_dataset,
epochs=train_epochs,
steps_per_epoch=train_steps,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=eval_input_dataset,
validation_freq=flags_obj.epochs_between_evals)
export_path = os.path.join(flags_obj.model_dir, 'saved_model')
model.save(export_path, include_optimizer=False)
eval_output = model.evaluate(eval_input_dataset,
steps=num_eval_steps,
verbose=2)
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj, datasets_override=None, strategy_override=None):
"""Run Malaria model training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
datasets_override: A pair of `tf.data.Dataset` objects to train the model,
representing the train and test sets.
strategy_override: A `tf.distribute.Strategy` object to use for model.
Returns:
Dictionary of training and eval stats.
"""
strategy = strategy_override or distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
tpu_address=flags_obj.tpu)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
train_ds, val_ds = tfds.load('malaria',
split=['train[:5%]', 'train[90%:92%]'],
shuffle_files=True,
download=False,
as_supervised=True,
data_dir=flags_obj.data_dir)
padded_train_ds = (train_ds.cache().map(pad).batch(BATCH_SIZE))
padded_val_ds = (val_ds.cache().map(pad).batch(BATCH_SIZE))
ckpt_full_path = os.path.join(flags_obj.model_dir,
'model.ckpt-{epoch:04d}')
with strategy_scope:
lr_schedule = tf.keras.optimizers.schedules.ExponentialDecay(
0.05, decay_steps=100000, decay_rate=0.96)
checkpoint_cb = tf.keras.callbacks.ModelCheckpoint(ckpt_full_path,
save_best_only=True)
#optimizer = tf.keras.optimizers.SGD(learning_rate=lr_schedule)
model = build_model()
model.compile(optimizer='adam',
loss='binary_crossentropy',
metrics=['accuracy'])
train_steps = train_length // flags_obj.batch_size
train_epochs = flags_obj.train_epochs
#num_eval_examples = val_ds.info.splits['train'].num_examples
num_eval_steps = test_length // flags_obj.batch_size
callbacks = [checkpoint_cb]
history = model.fit(padded_train_ds,
epochs=3,
callbacks=callbacks,
validation_data=padded_val_ds)
export_path = os.path.join(flags_obj.model_dir, 'saved_model')
model.save(export_path, include_optimizer=False)
eval_output = model.evaluate(padded_val_ds,
steps=num_eval_steps,
verbose=2)
stats = common.build_stats(history, eval_output, callbacks)
return stats
def run(flags_obj):
"""Run ResNet Cifar-10 training and eval loop using native Keras APIs.
Args:
flags_obj: An object containing parsed flag values.
Raises:
ValueError: If fp16 is passed as it is not currently supported.
Returns:
Dictionary of training and eval stats.
"""
keras_utils.set_session_config(enable_eager=flags_obj.enable_eager,
enable_xla=flags_obj.enable_xla)
# Execute flag override logic for better model performance
if flags_obj.tf_gpu_thread_mode:
keras_utils.set_gpu_thread_mode_and_count(
per_gpu_thread_count=flags_obj.per_gpu_thread_count,
gpu_thread_mode=flags_obj.tf_gpu_thread_mode,
num_gpus=flags_obj.num_gpus,
datasets_num_private_threads=flags_obj.datasets_num_private_threads
)
common.set_cudnn_batchnorm_mode()
dtype = flags_core.get_tf_dtype(flags_obj)
if dtype == 'fp16':
raise ValueError(
'dtype fp16 is not supported in Keras. Use the default '
'value(fp32).')
data_format = flags_obj.data_format
if data_format is None:
data_format = ('channels_first'
if tf.test.is_built_with_cuda() else 'channels_last')
tf.keras.backend.set_image_data_format(data_format)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=flags_obj.distribution_strategy,
num_gpus=flags_obj.num_gpus,
num_workers=distribution_utils.configure_cluster(),
all_reduce_alg=flags_obj.all_reduce_alg,
num_packs=flags_obj.num_packs)
if strategy:
# flags_obj.enable_get_next_as_optional controls whether enabling
# get_next_as_optional behavior in DistributedIterator. If true, last
# partial batch can be supported.
strategy.extended.experimental_enable_get_next_as_optional = (
flags_obj.enable_get_next_as_optional)
strategy_scope = distribution_utils.get_strategy_scope(strategy)
if flags_obj.use_synthetic_data:
distribution_utils.set_up_synthetic_data()
input_fn = common.get_synth_input_fn(
height=cifar_preprocessing.HEIGHT,
width=cifar_preprocessing.WIDTH,
num_channels=cifar_preprocessing.NUM_CHANNELS,
num_classes=cifar_preprocessing.NUM_CLASSES,
dtype=flags_core.get_tf_dtype(flags_obj),
drop_remainder=True)
else:
distribution_utils.undo_set_up_synthetic_data()
input_fn = cifar_preprocessing.input_fn
#train_input_dataset = input_fn(
# is_training=True,
# data_dir=flags_obj.data_dir,
# batch_size=flags_obj.batch_size,
# num_epochs=flags_obj.train_epochs,
# parse_record_fn=cifar_preprocessing.parse_record,
# datasets_num_private_threads=flags_obj.datasets_num_private_threads,
# dtype=dtype,
# # Setting drop_remainder to avoid the partial batch logic in normalization
# # layer, which triggers tf.where and leads to extra memory copy of input
# # sizes between host and GPU.
# drop_remainder=(not flags_obj.enable_get_next_as_optional))
# eval_input_dataset = None
# if not flags_obj.skip_eval:
# eval_input_dataset = input_fn(
# is_training=False,
# data_dir=flags_obj.data_dir,
# batch_size=flags_obj.batch_size,
# num_epochs=flags_obj.train_epochs,
# parse_record_fn=cifar_preprocessing.parse_record)
(x_train, y_train), (x_test,
y_test) = tf.keras.datasets.cifar10.load_data()
x_train = x_train.astype('float32')
x_test = x_test.astype('float32')
x_train /= 255
x_test /= 255
y_train = tf.keras.utils.to_categorical(y_train, num_classes)
y_test = tf.keras.utils.to_categorical(y_test, num_classes)
# optimizer = common.get_optimizer()
opt = tf.keras.optimizers.SGD(learning_rate=0.1)
logging.info(opt.__dict__)
optimizer = SynchronousSGDOptimizer(opt, use_locking=True)
optimizer._hyper = opt._hyper
logging.info(optimizer.__dict__)
model = Conv4_model(x_train, num_classes)
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
if flags_obj.force_v2_in_keras_compile is not None:
model.compile(
loss='categorical_crossentropy',
optimizer=optimizer,
metrics=(['accuracy']),
run_eagerly=flags_obj.run_eagerly,
experimental_run_tf_function=flags_obj.force_v2_in_keras_compile)
else:
model.compile(loss='categorical_crossentropy',
optimizer=optimizer,
metrics=(['accuracy']),
run_eagerly=flags_obj.run_eagerly)
cluster_size = current_cluster_size()
steps_per_epoch = (cifar_preprocessing.NUM_IMAGES['train'] //
flags_obj.batch_size)
steps_per_epoch = steps_per_epoch // cluster_size
train_epochs = flags_obj.train_epochs
callbacks = common.get_callbacks(steps_per_epoch, current_rank(),
cluster_size, learning_rate_schedule)
callbacks.append(BroadcastGlobalVariablesCallback())
if flags_obj.train_steps:
steps_per_epoch = min(flags_obj.train_steps, steps_per_epoch)
num_eval_steps = (cifar_preprocessing.NUM_IMAGES['validation'] //
flags_obj.batch_size)
# validation_data = eval_input_dataset
if flags_obj.skip_eval:
if flags_obj.set_learning_phase_to_train:
# TODO(haoyuzhang): Understand slowdown of setting learning phase when
# not using distribution strategy.
tf.keras.backend.set_learning_phase(1)
num_eval_steps = None
validation_data = None
tf.compat.v1.logging.info(x_train.shape)
history = model.fit(x_train,
y_train,
batch_size=flags_obj.batch_size,
epochs=train_epochs,
steps_per_epoch=steps_per_epoch,
callbacks=callbacks,
validation_steps=num_eval_steps,
validation_data=(x_test, y_test),
validation_freq=flags_obj.epochs_between_evals,
verbose=2)
eval_output = None
if not flags_obj.skip_eval:
eval_output = model.evaluate((x_test, y_test),
steps=num_eval_steps,
verbose=2)
stats = common.build_stats(history, eval_output, callbacks)
return stats