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Example using TensorFlow Estimator, Experiment & Dataset on MNIST data.
"""Script to illustrate usage of tf.estimator.Estimator in TF v1.3"""
import tensorflow as tf
from tensorflow.examples.tutorials.mnist import input_data as mnist_data
from tensorflow.contrib import slim
from tensorflow.contrib.learn import ModeKeys
from tensorflow.contrib.learn import learn_runner
# Show debugging output
tf.logging.set_verbosity(tf.logging.DEBUG)
# Set default flags for the output directories
FLAGS = tf.app.flags.FLAGS
tf.app.flags.DEFINE_string(
flag_name='model_dir', default_value='./mnist_training',
docstring='Output directory for model and training stats.')
tf.app.flags.DEFINE_string(
flag_name='data_dir', default_value='./mnist_data',
docstring='Directory to download the data to.')
# Define and run experiment ###############################
def run_experiment(argv=None):
"""Run the training experiment."""
# Define model parameters
params = tf.contrib.training.HParams(
learning_rate=0.002,
n_classes=10,
train_steps=5000,
min_eval_frequency=100
)
# Set the run_config and the directory to save the model and stats
run_config = tf.contrib.learn.RunConfig()
run_config = run_config.replace(model_dir=FLAGS.model_dir)
learn_runner.run(
experiment_fn=experiment_fn, # First-class function
run_config=run_config, # RunConfig
schedule="train_and_evaluate", # What to run
hparams=params # HParams
)
def experiment_fn(run_config, params):
"""Create an experiment to train and evaluate the model.
Args:
run_config (RunConfig): Configuration for Estimator run.
params (HParam): Hyperparameters
Returns:
(Experiment) Experiment for training the mnist model.
"""
# You can change a subset of the run_config properties as
run_config = run_config.replace(
save_checkpoints_steps=params.min_eval_frequency)
# Define the mnist classifier
estimator = get_estimator(run_config, params)
# Setup data loaders
mnist = mnist_data.read_data_sets(FLAGS.data_dir, one_hot=False)
train_input_fn, train_input_hook = get_train_inputs(
batch_size=128, mnist_data=mnist)
eval_input_fn, eval_input_hook = get_test_inputs(
batch_size=128, mnist_data=mnist)
# Define the experiment
experiment = tf.contrib.learn.Experiment(
estimator=estimator, # Estimator
train_input_fn=train_input_fn, # First-class function
eval_input_fn=eval_input_fn, # First-class function
train_steps=params.train_steps, # Minibatch steps
min_eval_frequency=params.min_eval_frequency, # Eval frequency
train_monitors=[train_input_hook], # Hooks for training
eval_hooks=[eval_input_hook], # Hooks for evaluation
eval_steps=None # Use evaluation feeder until its empty
)
return experiment
# Define model ############################################
def get_estimator(run_config, params):
"""Return the model as a Tensorflow Estimator object.
Args:
run_config (RunConfig): Configuration for Estimator run.
params (HParams): hyperparameters.
"""
return tf.estimator.Estimator(
model_fn=model_fn, # First-class function
params=params, # HParams
config=run_config # RunConfig
)
def model_fn(features, labels, mode, params):
"""Model function used in the estimator.
Args:
features (Tensor): Input features to the model.
labels (Tensor): Labels tensor for training and evaluation.
mode (ModeKeys): Specifies if training, evaluation or prediction.
params (HParams): hyperparameters.
Returns:
(EstimatorSpec): Model to be run by Estimator.
"""
is_training = mode == ModeKeys.TRAIN
# Define model's architecture
logits = architecture(features, is_training=is_training)
predictions = tf.argmax(logits, axis=-1)
# Loss, training and eval operations are not needed during inference.
loss = None
train_op = None
eval_metric_ops = {}
if mode != ModeKeys.INFER:
loss = tf.losses.sparse_softmax_cross_entropy(
labels=tf.cast(labels, tf.int32),
logits=logits)
train_op = get_train_op_fn(loss, params)
eval_metric_ops = get_eval_metric_ops(labels, predictions)
return tf.estimator.EstimatorSpec(
mode=mode,
predictions=predictions,
loss=loss,
train_op=train_op,
eval_metric_ops=eval_metric_ops
)
def get_train_op_fn(loss, params):
"""Get the training Op.
Args:
loss (Tensor): Scalar Tensor that represents the loss function.
params (HParams): Hyperparameters (needs to have `learning_rate`)
Returns:
Training Op
"""
return tf.contrib.layers.optimize_loss(
loss=loss,
global_step=tf.contrib.framework.get_global_step(),
optimizer=tf.train.AdamOptimizer,
learning_rate=params.learning_rate
)
def get_eval_metric_ops(labels, predictions):
"""Return a dict of the evaluation Ops.
Args:
labels (Tensor): Labels tensor for training and evaluation.
predictions (Tensor): Predictions Tensor.
Returns:
Dict of metric results keyed by name.
"""
return {
'Accuracy': tf.metrics.accuracy(
labels=labels,
predictions=predictions,
name='accuracy')
}
def architecture(inputs, is_training, scope='MnistConvNet'):
"""Return the output operation following the network architecture.
Args:
inputs (Tensor): Input Tensor
is_training (bool): True iff in training mode
scope (str): Name of the scope of the architecture
Returns:
Logits output Op for the network.
"""
with tf.variable_scope(scope):
with slim.arg_scope(
[slim.conv2d, slim.fully_connected],
weights_initializer=tf.contrib.layers.xavier_initializer()):
net = slim.conv2d(inputs, 20, [5, 5], padding='VALID',
scope='conv1')
net = slim.max_pool2d(net, 2, stride=2, scope='pool2')
net = slim.conv2d(net, 40, [5, 5], padding='VALID',
scope='conv3')
net = slim.max_pool2d(net, 2, stride=2, scope='pool4')
net = tf.reshape(net, [-1, 4 * 4 * 40])
net = slim.fully_connected(net, 256, scope='fn5')
net = slim.dropout(net, is_training=is_training,
scope='dropout5')
net = slim.fully_connected(net, 256, scope='fn6')
net = slim.dropout(net, is_training=is_training,
scope='dropout6')
net = slim.fully_connected(net, 10, scope='output',
activation_fn=None)
return net
# Define data loaders #####################################
class IteratorInitializerHook(tf.train.SessionRunHook):
"""Hook to initialise data iterator after Session is created."""
def __init__(self):
super(IteratorInitializerHook, self).__init__()
self.iterator_initializer_func = None
def after_create_session(self, session, coord):
"""Initialise the iterator after the session has been created."""
self.iterator_initializer_func(session)
# Define the training inputs
def get_train_inputs(batch_size, mnist_data):
"""Return the input function to get the training data.
Args:
batch_size (int): Batch size of training iterator that is returned
by the input function.
mnist_data (Object): Object holding the loaded mnist data.
Returns:
(Input function, IteratorInitializerHook):
- Function that returns (features, labels) when called.
- Hook to initialise input iterator.
"""
iterator_initializer_hook = IteratorInitializerHook()
def train_inputs():
"""Returns training set as Operations.
Returns:
(features, labels) Operations that iterate over the dataset
on every evaluation
"""
with tf.name_scope('Training_data'):
# Get Mnist data
images = mnist_data.train.images.reshape([-1, 28, 28, 1])
labels = mnist_data.train.labels
# Define placeholders
images_placeholder = tf.placeholder(
images.dtype, images.shape)
labels_placeholder = tf.placeholder(
labels.dtype, labels.shape)
# Build dataset iterator
dataset = tf.contrib.data.Dataset.from_tensor_slices(
(images_placeholder, labels_placeholder))
dataset = dataset.repeat(None) # Infinite iterations
dataset = dataset.shuffle(buffer_size=10000)
dataset = dataset.batch(batch_size)
iterator = dataset.make_initializable_iterator()
next_example, next_label = iterator.get_next()
# Set runhook to initialize iterator
iterator_initializer_hook.iterator_initializer_func = \
lambda sess: sess.run(
iterator.initializer,
feed_dict={images_placeholder: images,
labels_placeholder: labels})
# Return batched (features, labels)
return next_example, next_label
# Return function and hook
return train_inputs, iterator_initializer_hook
def get_test_inputs(batch_size, mnist_data):
"""Return the input function to get the test data.
Args:
batch_size (int): Batch size of training iterator that is returned
by the input function.
mnist_data (Object): Object holding the loaded mnist data.
Returns:
(Input function, IteratorInitializerHook):
- Function that returns (features, labels) when called.
- Hook to initialise input iterator.
"""
iterator_initializer_hook = IteratorInitializerHook()
def test_inputs():
"""Returns training set as Operations.
Returns:
(features, labels) Operations that iterate over the dataset
on every evaluation
"""
with tf.name_scope('Test_data'):
# Get Mnist data
images = mnist_data.test.images.reshape([-1, 28, 28, 1])
labels = mnist_data.test.labels
# Define placeholders
images_placeholder = tf.placeholder(
images.dtype, images.shape)
labels_placeholder = tf.placeholder(
labels.dtype, labels.shape)
# Build dataset iterator
dataset = tf.contrib.data.Dataset.from_tensor_slices(
(images_placeholder, labels_placeholder))
dataset = dataset.batch(batch_size)
iterator = dataset.make_initializable_iterator()
next_example, next_label = iterator.get_next()
# Set runhook to initialize iterator
iterator_initializer_hook.iterator_initializer_func = \
lambda sess: sess.run(
iterator.initializer,
feed_dict={images_placeholder: images,
labels_placeholder: labels})
return next_example, next_label
# Return function and hook
return test_inputs, iterator_initializer_hook
# Run script ##############################################
if __name__ == "__main__":
tf.app.run(
main=run_experiment
)
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