berak · December 13, 2015 19:33
diff --git a/cifar10.py b/cifar10.py
 # Copyright 2015 Google Inc. All Rights Reserved.
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #     http://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.
 # ==============================================================================
 """Builds the CIFAR-10 network.
 Summary of available functions:
 # Compute input images and labels for training. If you would like to run
 # evaluations, use input() instead.
 inputs, labels = distorted_inputs()
 # Compute inference on the model inputs to make a prediction.
 predictions = inference(inputs)
 # Compute the total loss of the prediction with respect to the labels.
 loss = loss(predictions, labels)
 # Create a graph to run one step of training with respect to the loss.
 train_op = train(loss, global_step)
 """
 # pylint: disable=missing-docstring
 from __future__ import absolute_import
 from __future__ import division
 from __future__ import print_function
 import gzip
 import os
 import re
 import sys
 import tarfile
 import tensorflow.python.platform
 from six.moves import urllib
 from six.moves import xrange  # pylint: disable=redefined-builtin
 import tensorflow as tf
 from tensorflow.models.image.cifar10 import cifar10_input
 from tensorflow.python.platform import gfile
 FLAGS = tf.app.flags.FLAGS
 # Basic model parameters.
 tf.app.flags.DEFINE_integer('batch_size', 128,
                            """Number of images to process in a batch.""")
 tf.app.flags.DEFINE_string('data_dir', '/tmp/cifar10_data',
                           """Path to the CIFAR-10 data directory.""")
 # Process images of this size. Note that this differs from the original CIFAR
 # image size of 32 x 32. If one alters this number, then the entire model
 # architecture will change and any model would need to be retrained.
 IMAGE_SIZE = 24
 # Global constants describing the CIFAR-10 data set.
 NUM_CLASSES = 10
 NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN = 50000
 NUM_EXAMPLES_PER_EPOCH_FOR_EVAL = 10000
 # Constants describing the training process.
 MOVING_AVERAGE_DECAY = 0.9999     # The decay to use for the moving average.
 NUM_EPOCHS_PER_DECAY = 350.0      # Epochs after which learning rate decays.
 LEARNING_RATE_DECAY_FACTOR = 0.1  # Learning rate decay factor.
 INITIAL_LEARNING_RATE = 0.1       # Initial learning rate.
 # If a model is trained with multiple GPU's prefix all Op names with tower_name
 # to differentiate the operations. Note that this prefix is removed from the
 # names of the summaries when visualizing a model.
 TOWER_NAME = 'tower'
 DATA_URL = 'http://www.cs.toronto.edu/~kriz/cifar-10-binary.tar.gz'
 def _activation_summary(x):
  """Helper to create summaries for activations.
  Creates a summary that provides a histogram of activations.
  Creates a summary that measure the sparsity of activations.
  Args:
    x: Tensor
  Returns:
    nothing
  """
  # Remove 'tower_[0-9]/' from the name in case this is a multi-GPU training
  # session. This helps the clarity of presentation on tensorboard.
  tensor_name = re.sub('%s_[0-9]*/' % TOWER_NAME, '', x.op.name)
  tf.histogram_summary(tensor_name + '/activations', x)
  tf.scalar_summary(tensor_name + '/sparsity', tf.nn.zero_fraction(x))
 def _variable_on_cpu(name, shape, initializer):
  """Helper to create a Variable stored on CPU memory.
  Args:
    name: name of the variable
    shape: list of ints
    initializer: initializer for Variable
  Returns:
    Variable Tensor
  """
  with tf.device('/cpu:0'):
    var = tf.get_variable(name, shape, initializer=initializer)
  return var
 def _variable_with_weight_decay(name, shape, stddev, wd):
  """Helper to create an initialized Variable with weight decay.
  Note that the Variable is initialized with a truncated normal distribution.
  A weight decay is added only if one is specified.
  Args:
    name: name of the variable
    shape: list of ints
    stddev: standard deviation of a truncated Gaussian
    wd: add L2Loss weight decay multiplied by this float. If None, weight
        decay is not added for this Variable.
  Returns:
    Variable Tensor
  """
  var = _variable_on_cpu(name, shape,
                         tf.truncated_normal_initializer(stddev=stddev))
  if wd:
    weight_decay = tf.mul(tf.nn.l2_loss(var), wd, name='weight_loss')
    tf.add_to_collection('losses', weight_decay)
  return var
 def _generate_image_and_label_batch(image, label, min_queue_examples):
  """Construct a queued batch of images and labels.
  Args:
    image: 3-D Tensor of [IMAGE_SIZE, IMAGE_SIZE, 3] of type.float32.
    label: 1-D Tensor of type.int32
    min_queue_examples: int32, minimum number of samples to retain
      in the queue that provides of batches of examples.
  Returns:
    images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
    labels: Labels. 1D tensor of [batch_size] size.
  """
  # Create a queue that shuffles the examples, and then
  # read 'FLAGS.batch_size' images + labels from the example queue.
  num_preprocess_threads = 16
  images, label_batch = tf.train.shuffle_batch(
      [image, label],
      batch_size=FLAGS.batch_size,
      num_threads=num_preprocess_threads,
      capacity=min_queue_examples + 3 * FLAGS.batch_size,
      min_after_dequeue=min_queue_examples)
  # Display the training images in the visualizer.
  tf.image_summary('images', images)
  return images, tf.reshape(label_batch, [FLAGS.batch_size])
 def distorted_inputs():
  """Construct distorted input for CIFAR training using the Reader ops.
  Raises:
    ValueError: if no data_dir
  Returns:
    images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
    labels: Labels. 1D tensor of [batch_size] size.
  """
  filenames = [os.path.join(FLAGS.data_dir, 'cifar-10-batches-bin',
                            'data_batch_%d.bin' % i)
               for i in xrange(1, 6)]
  for f in filenames:
    if not gfile.Exists(f):
      raise ValueError('Failed to find file: ' + f)
  # Create a queue that produces the filenames to read.
  filename_queue = tf.train.string_input_producer(filenames)
  # Read examples from files in the filename queue.
  read_input = cifar10_input.read_cifar10(filename_queue)
  reshaped_image = tf.cast(read_input.uint8image, tf.float32)
  height = IMAGE_SIZE
  width = IMAGE_SIZE
  # Image processing for training the network. Note the many random
  # distortions applied to the image.
  # Randomly crop a [height, width] section of the image.
  distorted_image = tf.image.random_crop(reshaped_image, [height, width])
  # Randomly flip the image horizontally.
  distorted_image = tf.image.random_flip_left_right(distorted_image)
  # Because these operations are not commutative, consider randomizing
  # randomize the order their operation.
  distorted_image = tf.image.random_brightness(distorted_image,
                                               max_delta=63)
  distorted_image = tf.image.random_contrast(distorted_image,
                                             lower=0.2, upper=1.8)
  # Subtract off the mean and divide by the variance of the pixels.
  float_image = tf.image.per_image_whitening(distorted_image)
  # Ensure that the random shuffling has good mixing properties.
  min_fraction_of_examples_in_queue = 0.4
  min_queue_examples = int(NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN *
                           min_fraction_of_examples_in_queue)
  print ('Filling queue with %d CIFAR images before starting to train. '
         'This will take a few minutes.' % min_queue_examples)
  # Generate a batch of images and labels by building up a queue of examples.
  return _generate_image_and_label_batch(float_image, read_input.label,
                                         min_queue_examples)
 def inputs(eval_data):
  """Construct input for CIFAR evaluation using the Reader ops.
  Args:
    eval_data: bool, indicating if one should use the train or eval data set.
  Raises:
    ValueError: if no data_dir
  Returns:
    images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
    labels: Labels. 1D tensor of [batch_size] size.
  """
  if not FLAGS.data_dir:
    raise ValueError('Please supply a data_dir')
  if not eval_data:
    filenames = [os.path.join(FLAGS.data_dir, 'cifar-10-batches-bin',
                              'data_batch_%d.bin' % i)
                 for i in xrange(1, 6)]
    num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN
  else:
    filenames = [os.path.join(FLAGS.data_dir, 'cifar-10-batches-bin',
                              'test_batch.bin')]
    num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_EVAL
  for f in filenames:
    if not gfile.Exists(f):
      raise ValueError('Failed to find file: ' + f)
  # Create a queue that produces the filenames to read.
  filename_queue = tf.train.string_input_producer(filenames)
  # Read examples from files in the filename queue.
  read_input = cifar10_input.read_cifar10(filename_queue)
  reshaped_image = tf.cast(read_input.uint8image, tf.float32)
  height = IMAGE_SIZE
  width = IMAGE_SIZE
  # Image processing for evaluation.
  # Crop the central [height, width] of the image.
  resized_image = tf.image.resize_image_with_crop_or_pad(reshaped_image,
                                                         width, height)
  # Subtract off the mean and divide by the variance of the pixels.
  float_image = tf.image.per_image_whitening(resized_image)
  # Ensure that the random shuffling has good mixing properties.
  min_fraction_of_examples_in_queue = 0.4
  min_queue_examples = int(num_examples_per_epoch *
                           min_fraction_of_examples_in_queue)
  # Generate a batch of images and labels by building up a queue of examples.
  return _generate_image_and_label_batch(float_image, read_input.label,
                                         min_queue_examples)
 def inference(images):
  """Build the CIFAR-10 model.
  Args:
    images: Images returned from distorted_inputs() or inputs().
  Returns:
    Logits.
  """
  # We instantiate all variables using tf.get_variable() instead of
  # tf.Variable() in order to share variables across multiple GPU training runs.
  # If we only ran this model on a single GPU, we could simplify this function
  # by replacing all instances of tf.get_variable() with tf.Variable().
  #
  # conv1
  with tf.variable_scope('conv1') as scope:
    kernel = _variable_with_weight_decay('weights', shape=[5, 5, 3, 64],
                                         stddev=1e-4, wd=0.0)
    conv = tf.nn.conv2d(images, kernel, [1, 1, 1, 1], padding='SAME')
    biases = _variable_on_cpu('biases', [64], tf.constant_initializer(0.0))
    bias = tf.nn.bias_add(conv, biases)
    conv1 = tf.nn.relu(bias, name=scope.name)
    _activation_summary(conv1)
  # pool1
  pool1 = tf.nn.max_pool(conv1, ksize=[1, 3, 3, 1], strides=[1, 2, 2, 1],
                         padding='SAME', name='pool1')
  # norm1
  norm1 = tf.nn.lrn(pool1, 4, bias=1.0, alpha=0.001 / 9.0, beta=0.75,
                    name='norm1')
  # conv2
  with tf.variable_scope('conv2') as scope:
    kernel = _variable_with_weight_decay('weights', shape=[5, 5, 64, 64],
                                         stddev=1e-4, wd=0.0)
    conv = tf.nn.conv2d(norm1, kernel, [1, 1, 1, 1], padding='SAME')
    biases = _variable_on_cpu('biases', [64], tf.constant_initializer(0.1))
    bias = tf.nn.bias_add(conv, biases)
    conv2 = tf.nn.relu(bias, name=scope.name)
    _activation_summary(conv2)
  # norm2
  norm2 = tf.nn.lrn(conv2, 4, bias=1.0, alpha=0.001 / 9.0, beta=0.75,
                    name='norm2')
  # pool2
  pool2 = tf.nn.max_pool(norm2, ksize=[1, 3, 3, 1],
                         strides=[1, 2, 2, 1], padding='SAME', name='pool2')
  # local3
  with tf.variable_scope('local3') as scope:
    # Move everything into depth so we can perform a single matrix multiply.
    dim = 1
    for d in pool2.get_shape()[1:].as_list():
      dim *= d
    reshape = tf.reshape(pool2, [FLAGS.batch_size, dim])
    weights = _variable_with_weight_decay('weights', shape=[dim, 384],
                                          stddev=0.04, wd=0.004)
    biases = _variable_on_cpu('biases', [384], tf.constant_initializer(0.1))
    local3 = tf.nn.relu_layer(reshape, weights, biases, name=scope.name)
    _activation_summary(local3)
  # local4
  with tf.variable_scope('local4') as scope:
    weights = _variable_with_weight_decay('weights', shape=[384, 192],
                                          stddev=0.04, wd=0.004)
    biases = _variable_on_cpu('biases', [192], tf.constant_initializer(0.1))
    local4 = tf.nn.relu_layer(local3, weights, biases, name=scope.name)
    _activation_summary(local4)
  # softmax, i.e. softmax(WX + b)
  with tf.variable_scope('softmax_linear') as scope:
    weights = _variable_with_weight_decay('weights', [192, NUM_CLASSES],
                                          stddev=1/192.0, wd=0.0)
    biases = _variable_on_cpu('biases', [NUM_CLASSES],
                              tf.constant_initializer(0.0))
    softmax_linear = tf.nn.xw_plus_b(local4, weights, biases, name=scope.name)
    _activation_summary(softmax_linear)
  return softmax_linear
 def loss(logits, labels):
  """Add L2Loss to all the trainable variables.
  Add summary for for "Loss" and "Loss/avg".
  Args:
    logits: Logits from inference().
    labels: Labels from distorted_inputs or inputs(). 1-D tensor
            of shape [batch_size]
  Returns:
    Loss tensor of type float.
  """
  # Reshape the labels into a dense Tensor of
  # shape [batch_size, NUM_CLASSES].
  sparse_labels = tf.reshape(labels, [FLAGS.batch_size, 1])
  indices = tf.reshape(tf.range(FLAGS.batch_size), [FLAGS.batch_size, 1])
  concated = tf.concat(1, [indices, sparse_labels])
  dense_labels = tf.sparse_to_dense(concated,
                                    [FLAGS.batch_size, NUM_CLASSES],
                                    1.0, 0.0)
  # Calculate the average cross entropy loss across the batch.
  cross_entropy = tf.nn.softmax_cross_entropy_with_logits(
      logits, dense_labels, name='cross_entropy_per_example')
  cross_entropy_mean = tf.reduce_mean(cross_entropy, name='cross_entropy')
  tf.add_to_collection('losses', cross_entropy_mean)
  # The total loss is defined as the cross entropy loss plus all of the weight
  # decay terms (L2 loss).
  return tf.add_n(tf.get_collection('losses'), name='total_loss')
 def _add_loss_summaries(total_loss):
  """Add summaries for losses in CIFAR-10 model.
  Generates moving average for all losses and associated summaries for
  visualizing the performance of the network.
  Args:
    total_loss: Total loss from loss().
  Returns:
    loss_averages_op: op for generating moving averages of losses.
  """
  # Compute the moving average of all individual losses and the total loss.
  loss_averages = tf.train.ExponentialMovingAverage(0.9, name='avg')
  losses = tf.get_collection('losses')
  loss_averages_op = loss_averages.apply(losses + [total_loss])
  # Attach a scalar summmary to all individual losses and the total loss; do the
  # same for the averaged version of the losses.
  for l in losses + [total_loss]:
    # Name each loss as '(raw)' and name the moving average version of the loss
    # as the original loss name.
    tf.scalar_summary(l.op.name +' (raw)', l)
    tf.scalar_summary(l.op.name, loss_averages.average(l))
  return loss_averages_op
 def train(total_loss, global_step):
  """Train CIFAR-10 model.
  Create an optimizer and apply to all trainable variables. Add moving
  average for all trainable variables.
  Args:
    total_loss: Total loss from loss().
    global_step: Integer Variable counting the number of training steps
      processed.
  Returns:
    train_op: op for training.
  """
  # Variables that affect learning rate.
  num_batches_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN / FLAGS.batch_size
  decay_steps = int(num_batches_per_epoch * NUM_EPOCHS_PER_DECAY)
  # Decay the learning rate exponentially based on the number of steps.
  lr = tf.train.exponential_decay(INITIAL_LEARNING_RATE,
                                  global_step,
                                  decay_steps,
                                  LEARNING_RATE_DECAY_FACTOR,
                                  staircase=True)
  tf.scalar_summary('learning_rate', lr)
  # Generate moving averages of all losses and associated summaries.
  loss_averages_op = _add_loss_summaries(total_loss)
  # Compute gradients.
  with tf.control_dependencies([loss_averages_op]):
    opt = tf.train.GradientDescentOptimizer(lr)
    grads = opt.compute_gradients(total_loss)
  # Apply gradients.
  apply_gradient_op = opt.apply_gradients(grads, global_step=global_step)
  # Add histograms for trainable variables.
  for var in tf.trainable_variables():
    tf.histogram_summary(var.op.name, var)
  # Add histograms for gradients.
  for grad, var in grads:
    if grad:
      tf.histogram_summary(var.op.name + '/gradients', grad)
  # Track the moving averages of all trainable variables.
  variable_averages = tf.train.ExponentialMovingAverage(
      MOVING_AVERAGE_DECAY, global_step)
  variables_averages_op = variable_averages.apply(tf.trainable_variables())
  with tf.control_dependencies([apply_gradient_op, variables_averages_op]):
    train_op = tf.no_op(name='train')
  return train_op
 def maybe_download_and_extract():
  """Download and extract the tarball from Alex's website."""
  dest_directory = FLAGS.data_dir
  if not os.path.exists(dest_directory):
    os.makedirs(dest_directory)
  filename = DATA_URL.split('/')[-1]
  filepath = os.path.join(dest_directory, filename)
  if not os.path.exists(filepath):
    def _progress(count, block_size, total_size):
      sys.stdout.write('\r>> Downloading %s %.1f%%' % (filename,
          float(count * block_size) / float(total_size) * 100.0))
      sys.stdout.flush()
    filepath, _ = urllib.request.urlretrieve(DATA_URL, filepath,
                                             reporthook=_progress)
    print()
    statinfo = os.stat(filepath)
    print('Succesfully downloaded', filename, statinfo.st_size, 'bytes.')
    tarfile.open(filepath, 'r:gz').extractall(dest_directory)
	# Copyright 2015 Google Inc. All Rights Reserved.
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# http://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.
	# ==============================================================================
	"""Builds the CIFAR-10 network.
	Summary of available functions:
	# Compute input images and labels for training. If you would like to run
	# evaluations, use input() instead.
	inputs, labels = distorted_inputs()
	# Compute inference on the model inputs to make a prediction.
	predictions = inference(inputs)
	# Compute the total loss of the prediction with respect to the labels.
	loss = loss(predictions, labels)
	# Create a graph to run one step of training with respect to the loss.
	train_op = train(loss, global_step)
	"""
	# pylint: disable=missing-docstring
	from __future__ import absolute_import
	from __future__ import division
	from __future__ import print_function
	import gzip
	import os
	import re
	import sys
	import tarfile
	import tensorflow.python.platform
	from six.moves import urllib
	from six.moves import xrange # pylint: disable=redefined-builtin
	import tensorflow as tf
	from tensorflow.models.image.cifar10 import cifar10_input
	from tensorflow.python.platform import gfile
	FLAGS = tf.app.flags.FLAGS
	# Basic model parameters.
	tf.app.flags.DEFINE_integer('batch_size', 128,
	"""Number of images to process in a batch.""")
	tf.app.flags.DEFINE_string('data_dir', '/tmp/cifar10_data',
	"""Path to the CIFAR-10 data directory.""")
	# Process images of this size. Note that this differs from the original CIFAR
	# image size of 32 x 32. If one alters this number, then the entire model
	# architecture will change and any model would need to be retrained.
	IMAGE_SIZE = 24
	# Global constants describing the CIFAR-10 data set.
	NUM_CLASSES = 10
	NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN = 50000
	NUM_EXAMPLES_PER_EPOCH_FOR_EVAL = 10000
	# Constants describing the training process.
	MOVING_AVERAGE_DECAY = 0.9999 # The decay to use for the moving average.
	NUM_EPOCHS_PER_DECAY = 350.0 # Epochs after which learning rate decays.
	LEARNING_RATE_DECAY_FACTOR = 0.1 # Learning rate decay factor.
	INITIAL_LEARNING_RATE = 0.1 # Initial learning rate.
	# If a model is trained with multiple GPU's prefix all Op names with tower_name
	# to differentiate the operations. Note that this prefix is removed from the
	# names of the summaries when visualizing a model.
	TOWER_NAME = 'tower'
	DATA_URL = 'http://www.cs.toronto.edu/~kriz/cifar-10-binary.tar.gz'
	def _activation_summary(x):
	"""Helper to create summaries for activations.
	Creates a summary that provides a histogram of activations.
	Creates a summary that measure the sparsity of activations.
	Args:
	x: Tensor
	Returns:
	nothing
	"""
	# Remove 'tower_[0-9]/' from the name in case this is a multi-GPU training
	# session. This helps the clarity of presentation on tensorboard.
	tensor_name = re.sub('%s_[0-9]*/' % TOWER_NAME, '', x.op.name)
	tf.histogram_summary(tensor_name + '/activations', x)
	tf.scalar_summary(tensor_name + '/sparsity', tf.nn.zero_fraction(x))
	def _variable_on_cpu(name, shape, initializer):
	"""Helper to create a Variable stored on CPU memory.
	Args:
	name: name of the variable
	shape: list of ints
	initializer: initializer for Variable
	Returns:
	Variable Tensor
	"""
	with tf.device('/cpu:0'):
	var = tf.get_variable(name, shape, initializer=initializer)
	return var
	def _variable_with_weight_decay(name, shape, stddev, wd):
	"""Helper to create an initialized Variable with weight decay.
	Note that the Variable is initialized with a truncated normal distribution.
	A weight decay is added only if one is specified.
	Args:
	name: name of the variable
	shape: list of ints
	stddev: standard deviation of a truncated Gaussian
	wd: add L2Loss weight decay multiplied by this float. If None, weight
	decay is not added for this Variable.
	Returns:
	Variable Tensor
	"""
	var = _variable_on_cpu(name, shape,
	tf.truncated_normal_initializer(stddev=stddev))
	if wd:
	weight_decay = tf.mul(tf.nn.l2_loss(var), wd, name='weight_loss')
	tf.add_to_collection('losses', weight_decay)
	return var
	def _generate_image_and_label_batch(image, label, min_queue_examples):
	"""Construct a queued batch of images and labels.
	Args:
	image: 3-D Tensor of [IMAGE_SIZE, IMAGE_SIZE, 3] of type.float32.
	label: 1-D Tensor of type.int32
	min_queue_examples: int32, minimum number of samples to retain
	in the queue that provides of batches of examples.
	Returns:
	images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
	labels: Labels. 1D tensor of [batch_size] size.
	"""
	# Create a queue that shuffles the examples, and then
	# read 'FLAGS.batch_size' images + labels from the example queue.
	num_preprocess_threads = 16
	images, label_batch = tf.train.shuffle_batch(
	[image, label],
	batch_size=FLAGS.batch_size,
	num_threads=num_preprocess_threads,
	capacity=min_queue_examples + 3 * FLAGS.batch_size,
	min_after_dequeue=min_queue_examples)
	# Display the training images in the visualizer.
	tf.image_summary('images', images)
	return images, tf.reshape(label_batch, [FLAGS.batch_size])
	def distorted_inputs():
	"""Construct distorted input for CIFAR training using the Reader ops.
	Raises:
	ValueError: if no data_dir
	Returns:
	images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
	labels: Labels. 1D tensor of [batch_size] size.
	"""
	filenames = [os.path.join(FLAGS.data_dir, 'cifar-10-batches-bin',
	'data_batch_%d.bin' % i)
	for i in xrange(1, 6)]
	for f in filenames:
	if not gfile.Exists(f):
	raise ValueError('Failed to find file: ' + f)
	# Create a queue that produces the filenames to read.
	filename_queue = tf.train.string_input_producer(filenames)
	# Read examples from files in the filename queue.
	read_input = cifar10_input.read_cifar10(filename_queue)
	reshaped_image = tf.cast(read_input.uint8image, tf.float32)
	height = IMAGE_SIZE
	width = IMAGE_SIZE
	# Image processing for training the network. Note the many random
	# distortions applied to the image.
	# Randomly crop a [height, width] section of the image.
	distorted_image = tf.image.random_crop(reshaped_image, [height, width])
	# Randomly flip the image horizontally.
	distorted_image = tf.image.random_flip_left_right(distorted_image)
	# Because these operations are not commutative, consider randomizing
	# randomize the order their operation.
	distorted_image = tf.image.random_brightness(distorted_image,
	max_delta=63)
	distorted_image = tf.image.random_contrast(distorted_image,
	lower=0.2, upper=1.8)
	# Subtract off the mean and divide by the variance of the pixels.
	float_image = tf.image.per_image_whitening(distorted_image)
	# Ensure that the random shuffling has good mixing properties.
	min_fraction_of_examples_in_queue = 0.4
	min_queue_examples = int(NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN *
	min_fraction_of_examples_in_queue)
	print ('Filling queue with %d CIFAR images before starting to train. '
	'This will take a few minutes.' % min_queue_examples)
	# Generate a batch of images and labels by building up a queue of examples.
	return _generate_image_and_label_batch(float_image, read_input.label,
	min_queue_examples)
	def inputs(eval_data):
	"""Construct input for CIFAR evaluation using the Reader ops.
	Args:
	eval_data: bool, indicating if one should use the train or eval data set.
	Raises:
	ValueError: if no data_dir
	Returns:
	images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
	labels: Labels. 1D tensor of [batch_size] size.
	"""
	if not FLAGS.data_dir:
	raise ValueError('Please supply a data_dir')
	if not eval_data:
	filenames = [os.path.join(FLAGS.data_dir, 'cifar-10-batches-bin',
	'data_batch_%d.bin' % i)
	for i in xrange(1, 6)]
	num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN
	else:
	filenames = [os.path.join(FLAGS.data_dir, 'cifar-10-batches-bin',
	'test_batch.bin')]
	num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_EVAL
	for f in filenames:
	if not gfile.Exists(f):
	raise ValueError('Failed to find file: ' + f)
	# Create a queue that produces the filenames to read.
	filename_queue = tf.train.string_input_producer(filenames)
	# Read examples from files in the filename queue.
	read_input = cifar10_input.read_cifar10(filename_queue)
	reshaped_image = tf.cast(read_input.uint8image, tf.float32)
	height = IMAGE_SIZE
	width = IMAGE_SIZE
	# Image processing for evaluation.
	# Crop the central [height, width] of the image.
	resized_image = tf.image.resize_image_with_crop_or_pad(reshaped_image,
	width, height)
	# Subtract off the mean and divide by the variance of the pixels.
	float_image = tf.image.per_image_whitening(resized_image)
	# Ensure that the random shuffling has good mixing properties.
	min_fraction_of_examples_in_queue = 0.4
	min_queue_examples = int(num_examples_per_epoch *
	min_fraction_of_examples_in_queue)
	# Generate a batch of images and labels by building up a queue of examples.
	return _generate_image_and_label_batch(float_image, read_input.label,
	min_queue_examples)
	def inference(images):
	"""Build the CIFAR-10 model.
	Args:
	images: Images returned from distorted_inputs() or inputs().
	Returns:
	Logits.
	"""
	# We instantiate all variables using tf.get_variable() instead of
	# tf.Variable() in order to share variables across multiple GPU training runs.
	# If we only ran this model on a single GPU, we could simplify this function
	# by replacing all instances of tf.get_variable() with tf.Variable().
	#
	# conv1
	with tf.variable_scope('conv1') as scope:
	kernel = _variable_with_weight_decay('weights', shape=[5, 5, 3, 64],
	stddev=1e-4, wd=0.0)
	conv = tf.nn.conv2d(images, kernel, [1, 1, 1, 1], padding='SAME')
	biases = _variable_on_cpu('biases', [64], tf.constant_initializer(0.0))
	bias = tf.nn.bias_add(conv, biases)
	conv1 = tf.nn.relu(bias, name=scope.name)
	_activation_summary(conv1)
	# pool1
	pool1 = tf.nn.max_pool(conv1, ksize=[1, 3, 3, 1], strides=[1, 2, 2, 1],
	padding='SAME', name='pool1')
	# norm1
	norm1 = tf.nn.lrn(pool1, 4, bias=1.0, alpha=0.001 / 9.0, beta=0.75,
	name='norm1')
	# conv2
	with tf.variable_scope('conv2') as scope:
	kernel = _variable_with_weight_decay('weights', shape=[5, 5, 64, 64],
	stddev=1e-4, wd=0.0)
	conv = tf.nn.conv2d(norm1, kernel, [1, 1, 1, 1], padding='SAME')
	biases = _variable_on_cpu('biases', [64], tf.constant_initializer(0.1))
	bias = tf.nn.bias_add(conv, biases)
	conv2 = tf.nn.relu(bias, name=scope.name)
	_activation_summary(conv2)
	# norm2
	norm2 = tf.nn.lrn(conv2, 4, bias=1.0, alpha=0.001 / 9.0, beta=0.75,
	name='norm2')
	# pool2
	pool2 = tf.nn.max_pool(norm2, ksize=[1, 3, 3, 1],
	strides=[1, 2, 2, 1], padding='SAME', name='pool2')
	# local3
	with tf.variable_scope('local3') as scope:
	# Move everything into depth so we can perform a single matrix multiply.
	dim = 1
	for d in pool2.get_shape()[1:].as_list():
	dim *= d
	reshape = tf.reshape(pool2, [FLAGS.batch_size, dim])
	weights = _variable_with_weight_decay('weights', shape=[dim, 384],
	stddev=0.04, wd=0.004)
	biases = _variable_on_cpu('biases', [384], tf.constant_initializer(0.1))
	local3 = tf.nn.relu_layer(reshape, weights, biases, name=scope.name)
	_activation_summary(local3)
	# local4
	with tf.variable_scope('local4') as scope:
	weights = _variable_with_weight_decay('weights', shape=[384, 192],
	stddev=0.04, wd=0.004)
	biases = _variable_on_cpu('biases', [192], tf.constant_initializer(0.1))
	local4 = tf.nn.relu_layer(local3, weights, biases, name=scope.name)
	_activation_summary(local4)
	# softmax, i.e. softmax(WX + b)
	with tf.variable_scope('softmax_linear') as scope:
	weights = _variable_with_weight_decay('weights', [192, NUM_CLASSES],
	stddev=1/192.0, wd=0.0)
	biases = _variable_on_cpu('biases', [NUM_CLASSES],
	tf.constant_initializer(0.0))
	softmax_linear = tf.nn.xw_plus_b(local4, weights, biases, name=scope.name)
	_activation_summary(softmax_linear)
	return softmax_linear
	def loss(logits, labels):
	"""Add L2Loss to all the trainable variables.
	Add summary for for "Loss" and "Loss/avg".
	Args:
	logits: Logits from inference().
	labels: Labels from distorted_inputs or inputs(). 1-D tensor
	of shape [batch_size]
	Returns:
	Loss tensor of type float.
	"""
	# Reshape the labels into a dense Tensor of
	# shape [batch_size, NUM_CLASSES].
	sparse_labels = tf.reshape(labels, [FLAGS.batch_size, 1])
	indices = tf.reshape(tf.range(FLAGS.batch_size), [FLAGS.batch_size, 1])
	concated = tf.concat(1, [indices, sparse_labels])
	dense_labels = tf.sparse_to_dense(concated,
	[FLAGS.batch_size, NUM_CLASSES],
	1.0, 0.0)
	# Calculate the average cross entropy loss across the batch.
	cross_entropy = tf.nn.softmax_cross_entropy_with_logits(
	logits, dense_labels, name='cross_entropy_per_example')
	cross_entropy_mean = tf.reduce_mean(cross_entropy, name='cross_entropy')
	tf.add_to_collection('losses', cross_entropy_mean)
	# The total loss is defined as the cross entropy loss plus all of the weight
	# decay terms (L2 loss).
	return tf.add_n(tf.get_collection('losses'), name='total_loss')
	def _add_loss_summaries(total_loss):
	"""Add summaries for losses in CIFAR-10 model.
	Generates moving average for all losses and associated summaries for
	visualizing the performance of the network.
	Args:
	total_loss: Total loss from loss().
	Returns:
	loss_averages_op: op for generating moving averages of losses.
	"""
	# Compute the moving average of all individual losses and the total loss.
	loss_averages = tf.train.ExponentialMovingAverage(0.9, name='avg')
	losses = tf.get_collection('losses')
	loss_averages_op = loss_averages.apply(losses + [total_loss])
	# Attach a scalar summmary to all individual losses and the total loss; do the
	# same for the averaged version of the losses.
	for l in losses + [total_loss]:
	# Name each loss as '(raw)' and name the moving average version of the loss
	# as the original loss name.
	tf.scalar_summary(l.op.name +' (raw)', l)
	tf.scalar_summary(l.op.name, loss_averages.average(l))
	return loss_averages_op
	def train(total_loss, global_step):
	"""Train CIFAR-10 model.
	Create an optimizer and apply to all trainable variables. Add moving
	average for all trainable variables.
	Args:
	total_loss: Total loss from loss().
	global_step: Integer Variable counting the number of training steps
	processed.
	Returns:
	train_op: op for training.
	"""
	# Variables that affect learning rate.
	num_batches_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN / FLAGS.batch_size
	decay_steps = int(num_batches_per_epoch * NUM_EPOCHS_PER_DECAY)
	# Decay the learning rate exponentially based on the number of steps.
	lr = tf.train.exponential_decay(INITIAL_LEARNING_RATE,
	global_step,
	decay_steps,
	LEARNING_RATE_DECAY_FACTOR,
	staircase=True)
	tf.scalar_summary('learning_rate', lr)
	# Generate moving averages of all losses and associated summaries.
	loss_averages_op = _add_loss_summaries(total_loss)
	# Compute gradients.
	with tf.control_dependencies([loss_averages_op]):
	opt = tf.train.GradientDescentOptimizer(lr)
	grads = opt.compute_gradients(total_loss)
	# Apply gradients.
	apply_gradient_op = opt.apply_gradients(grads, global_step=global_step)
	# Add histograms for trainable variables.
	for var in tf.trainable_variables():
	tf.histogram_summary(var.op.name, var)
	# Add histograms for gradients.
	for grad, var in grads:
	if grad:
	tf.histogram_summary(var.op.name + '/gradients', grad)
	# Track the moving averages of all trainable variables.
	variable_averages = tf.train.ExponentialMovingAverage(
	MOVING_AVERAGE_DECAY, global_step)
	variables_averages_op = variable_averages.apply(tf.trainable_variables())
	with tf.control_dependencies([apply_gradient_op, variables_averages_op]):
	train_op = tf.no_op(name='train')
	return train_op
	def maybe_download_and_extract():
	"""Download and extract the tarball from Alex's website."""
	dest_directory = FLAGS.data_dir
	if not os.path.exists(dest_directory):
	os.makedirs(dest_directory)
	filename = DATA_URL.split('/')[-1]
	filepath = os.path.join(dest_directory, filename)
	if not os.path.exists(filepath):
	def _progress(count, block_size, total_size):
	sys.stdout.write('\r>> Downloading %s %.1f%%' % (filename,
	float(count * block_size) / float(total_size) * 100.0))
	sys.stdout.flush()
	filepath, _ = urllib.request.urlretrieve(DATA_URL, filepath,
	reporthook=_progress)
	print()
	statinfo = os.stat(filepath)
	print('Succesfully downloaded', filename, statinfo.st_size, 'bytes.')
	tarfile.open(filepath, 'r:gz').extractall(dest_directory)
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