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=MNIST Convolutional Neural Network=
=Simple MNIST Convolutional Network=


Concept: Simple, end-to-end, LeNet-5-like convolutional MNIST model example. Meant as a tutorial for simple convolutional models.
==Input Function==


Link to code: https://github.com/tensorflow/models/blob/master/tutorials/image/mnist/convolutional.py
Define an input function. This has an internal function that parses the example data (one piece of data at a time) and one-hot encodes the labeled images with the digit it corresponds to.
 
Link to tutorial(s): https://www.tensorflow.org/tutorials/
 
Link to original data set: http://yann.lecun.com/exdb/mnist/
 
==License==
 
<pre>
# Copyright 2015 The TensorFlow Authors. 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.
# ==============================================================================
</pre>
 
==Import Statements and Variables==
 
Import statements:
 
<pre>
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
 
import argparse
import gzip
import os
import sys
import time
 
import numpy
from six.moves import urllib
from six.moves import xrange  # pylint: disable=redefined-builtin
import tensorflow as tf
</pre>
 
Variable definitions for use in the rest of the model:


<pre>
<pre>
SOURCE_URL = 'http://yann.lecun.com/exdb/mnist/'
def input_fn(mode, batch_size=1):
WORK_DIRECTORY = 'data'
  """A simple input_fn using the contrib.data input pipeline."""
IMAGE_SIZE = 28
NUM_CHANNELS = 1
PIXEL_DEPTH = 255
NUM_LABELS = 10
VALIDATION_SIZE = 5000  # Size of the validation set.
SEED = 66478  # Set to None for random seed.
BATCH_SIZE = 64
NUM_EPOCHS = 10
EVAL_BATCH_SIZE = 64
EVAL_FREQUENCY = 100  # Number of steps between evaluations.
FLAGS = None
</pre>


==Obtaining the Data==
  def example_parser(serialized_example):
    """Parses a single tf.Example into image and label tensors."""
    features = tf.parse_single_example(
        serialized_example,
        features={
            'image_raw': tf.FixedLenFeature([], tf.string),
            'label': tf.FixedLenFeature([], tf.int64),
        })
    image = tf.decode_raw(features['image_raw'], tf.uint8)
    image.set_shape([28 * 28])


Several functions are defined to help obtain the data. First, define the variable types we will use in the model:
    # Normalize the values of the image from the range [0, 255] to [-0.5, 0.5]
    image = tf.cast(image, tf.float32) / 255 - 0.5
    label = tf.cast(features['label'], tf.int32)
    return image, tf.one_hot(label, 10)


<pre>
   if mode == tf.estimator.ModeKeys.TRAIN:
def data_type():
     tfrecords_file = os.path.join(FLAGS.data_dir, 'train.tfrecords')
   """Return the type of the activations, weights, and placeholder variables."""
  if FLAGS.use_fp16:
     return tf.float16
   else:
   else:
     return tf.float32
     assert mode == tf.estimator.ModeKeys.EVAL, 'invalid mode'
</pre>
    tfrecords_file = os.path.join(FLAGS.data_dir, 'test.tfrecords')


Now define a function that will attempt to download the data if it does not already exist on disk. This uses urllib to obtain the MNIST files, and TensorFlow's gfile module to interact with the file and filesystem.
  assert tf.gfile.Exists(tfrecords_file), (
      'Run convert_to_records.py first to convert the MNIST data to TFRecord '
      'file format.')


<pre>
   dataset = tf.contrib.data.TFRecordDataset([tfrecords_file])
def maybe_download(filename):
  """Download the data from Yann's website, unless it's already here."""
  if not tf.gfile.Exists(WORK_DIRECTORY):
    tf.gfile.MakeDirs(WORK_DIRECTORY)
   filepath = os.path.join(WORK_DIRECTORY, filename)
  if not tf.gfile.Exists(filepath):
    filepath, _ = urllib.request.urlretrieve(SOURCE_URL + filename, filepath)
    with tf.gfile.GFile(filepath) as f:
      size = f.size()
    print('Successfully downloaded', filename, size, 'bytes.')
  return filepath
</pre>


Once the data is downloaded, it must be converted to a format convenient for Tensorflow - in particular, a 4D tensor in which the first index is the image number, the second and third are the width and height, and the fourth dimension is each channel of the image.
  # For training, repeat the dataset forever
  if mode == tf.estimator.ModeKeys.TRAIN:
    dataset = dataset.repeat()


These values are then normalized and re-scaled.
  # Map example_parser over dataset, and batch results by up to batch_size
  dataset = dataset.map(
      example_parser, num_threads=1, output_buffer_size=batch_size)
  dataset = dataset.batch(batch_size)
  images, labels = dataset.make_one_shot_iterator().get_next()


<pre>
   return images, labels
def extract_data(filename, num_images):
   """Extract the images into a 4D tensor [image index, y, x, channels].
  Values are rescaled from [0, 255] down to [-0.5, 0.5].
  """
  print('Extracting', filename)
  with gzip.open(filename) as bytestream:
    bytestream.read(16)
    buf = bytestream.read(IMAGE_SIZE * IMAGE_SIZE * num_images * NUM_CHANNELS)
    data = numpy.frombuffer(buf, dtype=numpy.uint8).astype(numpy.float32)
    data = (data - (PIXEL_DEPTH / 2.0)) / PIXEL_DEPTH
    data = data.reshape(num_images, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS)
    return data
</pre>
</pre>


The labels - the predictions - must also be put into a format conducive for TensorFlow - a 1D vector:
==Prepare Model==
 
<pre>
def extract_labels(filename, num_images):
  """Extract the labels into a vector of int64 label IDs."""
  print('Extracting', filename)
  with gzip.open(filename) as bytestream:
    bytestream.read(8)
    buf = bytestream.read(1 * num_images)
    labels = numpy.frombuffer(buf, dtype=numpy.uint8).astype(numpy.int64)
  return labels
</pre>
 
There's also a utility for creating a fake data set.
 
==Error Rate==
 
There is a function defined to compute the error rate. It computes the accuracy first: sums up the number of correctly-labeled digits, divides by the total number of digits, multiplies by 100 to convert to percent. Last, it subtracts the accuracy from 100 to get a percent error.


<pre>
<pre>
def error_rate(predictions, labels):
def mnist_model(inputs, mode):
   """Return the error rate based on dense predictions and sparse labels."""
   """Takes the MNIST inputs and mode and outputs a tensor of logits."""
   return 100.0 - (
   # Input Layer
      100.0 *
  # Reshape X to 4-D tensor: [batch_size, width, height, channels]
      numpy.sum(numpy.argmax(predictions, 1) == labels) /
  # MNIST images are 28x28 pixels, and have one color channel
      predictions.shape[0])
  inputs = tf.reshape(inputs, [-1, 28, 28, 1])
</pre>
  data_format = FLAGS.data_format
 
Note that this metric is NOT used for training the convolutional network, it is only used for printing purposes.
 
==Main Method==


===Get Data===
  if data_format is None:
    # When running on GPU, transpose the data from channels_last (NHWC) to
    # channels_first (NCHW) to improve performance.
    # See https://www.tensorflow.org/performance/performance_guide#data_formats
    data_format = ('channels_first' if tf.test.is_built_with_cuda() else
                  'channels_last')


The main method starts by checking if it is in self-test mode (debug mode), in which case, it generates fake data:
   if data_format == 'channels_first':
 
     inputs = tf.transpose(inputs, [0, 3, 1, 2])
<pre>
   if FLAGS.self_test:
    print('Running self-test.')
     train_data, train_labels = fake_data(256)
    validation_data, validation_labels = fake_data(EVAL_BATCH_SIZE)
    test_data, test_labels = fake_data(EVAL_BATCH_SIZE)
    num_epochs = 1
</pre>
</pre>


Otherwise, it extracts data from the downloaded training/testing MNIST images. None of this is using TensorFlow functionality yet.
==Construct Model==


<pre>
<pre>
   else:
   # Convolutional Layer #1
    # Get the data.
  # Computes 32 features using a 5x5 filter with ReLU activation.
    train_data_filename = maybe_download('train-images-idx3-ubyte.gz')
  # Padding is added to preserve width and height.
    train_labels_filename = maybe_download('train-labels-idx1-ubyte.gz')
  # Input Tensor Shape: [batch_size, 28, 28, 1]
    test_data_filename = maybe_download('t10k-images-idx3-ubyte.gz')
  # Output Tensor Shape: [batch_size, 28, 28, 32]
    test_labels_filename = maybe_download('t10k-labels-idx1-ubyte.gz')
  conv1 = tf.layers.conv2d(
 
      inputs=inputs,
    # Extract it into numpy arrays.
      filters=32,
    train_data = extract_data(train_data_filename, 60000)
      kernel_size=[5, 5],
    train_labels = extract_labels(train_labels_filename, 60000)
      padding='same',
    test_data = extract_data(test_data_filename, 10000)
      activation=tf.nn.relu,
    test_labels = extract_labels(test_labels_filename, 10000)
      data_format=data_format)
 
    # Generate a validation set.
    validation_data = train_data[:VALIDATION_SIZE, ...]
    validation_labels = train_labels[:VALIDATION_SIZE]
    train_data = train_data[VALIDATION_SIZE:, ...]
    train_labels = train_labels[VALIDATION_SIZE:]
    num_epochs = NUM_EPOCHS
  train_size = train_labels.shape[0]
</pre>
 
===Variable Definitions===
 
To use the input variables we have on the computational graph that TensorFlow will build, we have to declare those input variables. We do that using a TensorFlow placeholder type.
 
We also created a placeholder variable in the [[TensorFlow/Adversarial Crypto]] class, in the [[TensorFlow/Adversarial_Crypto#AdversarialCrypto_Class_-_Creation_of_Message_and_Key|Creation of Message and Key]] section. There, the placeholder variable was batch size. (However, the input variables in that network were different because we used that somewhat mysterious function, "tf.contrib.framework.arg_scope()", and passed it TensorFlow variables to initialize on each of the three graph we had.)
 
Here, we are explicitly creating a variable placeholder for the trianing data (inputs), training labels (outputs), and evaluation data. (Remember, the data_type() function was defined above and just returns a float16 or float32 type.)


Again, notice the four dimensions - meaning train_data_node is a placeholder representing a 4D tensor.
  # Pooling Layer #1
  # First max pooling layer with a 2x2 filter and stride of 2
  # Input Tensor Shape: [batch_size, 28, 28, 32]
  # Output Tensor Shape: [batch_size, 14, 14, 32]
  pool1 = tf.layers.max_pooling2d(inputs=conv1, pool_size=[2, 2], strides=2,
                                  data_format=data_format)


<pre>
  # Convolutional Layer #2
   # This is where training samples and labels are fed to the graph.
   # Computes 64 features using a 5x5 filter.
   # These placeholder nodes will be fed a batch of training data at each
  # Padding is added to preserve width and height.
   # training step using the {feed_dict} argument to the Run() call below.
   # Input Tensor Shape: [batch_size, 14, 14, 32]
   train_data_node = tf.placeholder(
   # Output Tensor Shape: [batch_size, 14, 14, 64]
       data_type(),
   conv2 = tf.layers.conv2d(
       shape=(BATCH_SIZE, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS))
       inputs=pool1,
  train_labels_node = tf.placeholder(tf.int64, shape=(BATCH_SIZE,))
       filters=64,
  eval_data = tf.placeholder(
      kernel_size=[5, 5],
      data_type(),
      padding='same',
       shape=(EVAL_BATCH_SIZE, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS))
      activation=tf.nn.relu,
</pre>
       data_format=data_format)


Next, we create a set of tensors that will hold the weights and biases of the convolutional neural network layers. (When we use high-level neural net APIs like [[Keras]], this is all taken care of for us, but here we do it all manually.)
  # Pooling Layer #2
  # Second max pooling layer with a 2x2 filter and stride of 2
  # Input Tensor Shape: [batch_size, 14, 14, 64]
  # Output Tensor Shape: [batch_size, 7, 7, 64]
  pool2 = tf.layers.max_pooling2d(inputs=conv2, pool_size=[2, 2], strides=2,
                                  data_format=data_format)


====Variables for Convolutional Layers====
  # Flatten tensor into a batch of vectors
  # Input Tensor Shape: [batch_size, 7, 7, 64]
  # Output Tensor Shape: [batch_size, 7 * 7 * 64]
  pool2_flat = tf.reshape(pool2, [-1, 7 * 7 * 64])


First, convolutional layer 1: in this layer we are defining a 5 x 5 filter - meaning the 28 x 28 pixel images in the NIST data set will be convoluted down to a 5 x 5 image set. But the number of feature maps is 32, meaning we're going to convolute the 28 x 28 pixel images down into 32 different 5 x 5 pixel images. The idea is that each of those feature maps will pick out a particular feature about the image topology that is important, and "represent" it, or "allow" that signal to pass through the first layer of the convolutional neural network.  
  # Dense Layer
  # Densely connected layer with 1024 neurons
  # Input Tensor Shape: [batch_size, 7 * 7 * 64]
  # Output Tensor Shape: [batch_size, 1024]
  dense = tf.layers.dense(inputs=pool2_flat, units=1024,
                          activation=tf.nn.relu)


The bias determines the importance of each of those feature maps, so we need the number of biases to match the number of feature maps (32).
  # Add dropout operation; 0.6 probability that element will be kept
  dropout = tf.layers.dropout(
      inputs=dense, rate=0.4, training=(mode == tf.estimator.ModeKeys.TRAIN))


<pre>
   # Logits layer
   # The variables below hold all the trainable weights. They are passed an
   # Input Tensor Shape: [batch_size, 1024]
   # initial value which will be assigned when we call:
   # Output Tensor Shape: [batch_size, 10]
   # {tf.global_variables_initializer().run()}
   logits = tf.layers.dense(inputs=dropout, units=10)
   conv1_weights = tf.Variable(
   return logits
      tf.truncated_normal([5, 5, NUM_CHANNELS, 32],  # 5x5 filter, depth 32.
                          stddev=0.1,
                          seed=SEED, dtype=data_type()))
   conv1_biases = tf.Variable(tf.zeros([32], dtype=data_type()))
</pre>
</pre>


We do the same thing with the second convolutional layer. This time there is no number of channels showing up in the size.
==Get Estimator==


<pre>
<pre>
  conv2_weights = tf.Variable(tf.truncated_normal(
def mnist_model_fn(features, labels, mode):
      [5, 5, 32, 64], stddev=0.1,
  """Model function for MNIST."""
      seed=SEED, dtype=data_type()))
   logits = mnist_model(features, mode)
   conv2_biases = tf.Variable(tf.constant(0.1, shape=[64], dtype=data_type()))
</pre>


The truncated_normal variable types refer to how the variables are initialized - they are initialized with values drawn from a (truncated) normal distribution. Truncated simply means that they cannot go above 1 or below 0, which makes it easier for the machine learning algorithm.
  predictions = {
      'classes': tf.argmax(input=logits, axis=1),
      'probabilities': tf.nn.softmax(logits, name='softmax_tensor')
  }


Link to truncated_normal documentation: https://www.tensorflow.org/api_docs/python/tf/truncated_normal
  if mode == tf.estimator.ModeKeys.PREDICT:
    return tf.estimator.EstimatorSpec(mode=mode, predictions=predictions)


====Variables for Fully Connected Layers====
  loss = tf.losses.softmax_cross_entropy(onehot_labels=labels, logits=logits)


Next come the two fully connected (FC) layers, which re-assemble the feature maps that were detected in the convolutional layers. The fully connected layer creates 64 neurons for every 4 x 4 square of pixels in the original image, with a depth of 512 neurons each.
  # Configure the training op
  if mode == tf.estimator.ModeKeys.TRAIN:
    optimizer = tf.train.AdamOptimizer(learning_rate=1e-4)
    train_op = optimizer.minimize(loss, tf.train.get_or_create_global_step())
  else:
    train_op = None


(NOTE: This doesn't make sense. There's waaaaaay too many neurons here.)
  accuracy = tf.metrics.accuracy(
      tf.argmax(labels, axis=1), predictions['classes'])
  metrics = {'accuracy': accuracy}


(It may be that this is the number of inputs, then the number of outputs - as in, there are (size/4)*(size/4)*64 inputs on one side, 512 outputs on the other side.)
  # Create a tensor named train_accuracy for logging purposes
  tf.identity(accuracy[1], name='train_accuracy')
  tf.summary.scalar('train_accuracy', accuracy[1])


<pre>
   return tf.estimator.EstimatorSpec(
   fc1_weights = tf.Variable( # fully connected, depth 512.
      mode=mode,
       tf.truncated_normal([IMAGE_SIZE // 4 * IMAGE_SIZE // 4 * 64, 512],
       predictions=predictions,
                          stddev=0.1,
      loss=loss,
                          seed=SEED,
      train_op=train_op,
                          dtype=data_type()))
      eval_metric_ops=metrics)
</pre>
</pre>


The second (last) fully connected layer is a 512-wide layer that has a depth equal to the number of labels - in this case, 10 corresponding to 10 digits.
==Main Function==
 
(Again, this looks like 512 inputs connecting to NUM_LABELS outputs.)


<pre>
<pre>
  fc2_weights = tf.Variable(tf.truncated_normal([512, NUM_LABELS],
def main(unused_argv):
                                                stddev=0.1,
  # Create the Estimator
                                                seed=SEED,
   mnist_classifier = tf.estimator.Estimator(
                                                dtype=data_type()))
       model_fn=mnist_model_fn, model_dir=FLAGS.model_dir)
   fc2_biases = tf.Variable(tf.constant(
       0.1, shape=[NUM_LABELS], dtype=data_type()))
</pre>
 
===Neural Network Layers===
 
The next step in the script is to use the variables defined above to construct the neural network layers themselves.


Starting with function header:
  # Train the model
  tensors_to_log = {
      'train_accuracy': 'train_accuracy'
  }


<pre>
   logging_hook = tf.train.LoggingTensorHook(
   def model(data, train=False):
      tensors=tensors_to_log, every_n_iter=100)
    """The Model definition."""
</pre>


We first construct the first convolutional layer of the network:
  batches_per_epoch = _NUM_IMAGES['train'] / FLAGS.batch_size


<pre>
  mnist_classifier.train(
    # 2D convolution, with 'SAME' padding (i.e. the output feature map has
      input_fn=lambda: input_fn(tf.estimator.ModeKeys.TRAIN, FLAGS.batch_size),
https://www.tensorflow.org/api_docs/python/tf/truncated_normal    # the same size as the input). Note that {strides} is a 4D array whose
       steps=FLAGS.train_epochs * batches_per_epoch,
    # shape matches the data layout: [image index, y, x, depth].
       hooks=[logging_hook])
    conv = tf.nn.conv2d(data,
                        conv1_weights,
                        strides=[1, 1, 1, 1],
                        padding='SAME')
</pre>
 
We pass in the convolution layer 1 weights variable created above.
 
After the convolution layer comes a rectifier layer:
 
<pre>
    # Bias and rectified linear non-linearity.
    relu = tf.nn.relu(tf.nn.bias_add(conv, conv1_biases))
</pre>
 
then a max pooling layer to apply the biases:
 
<pre>
    # Max pooling. The kernel size spec {ksize} also follows the layout of
    # the data. Here we have a pooling window of 2, and a stride of 2.
    pool = tf.nn.max_pool(relu,
                          ksize=[1, 2, 2, 1],
                          strides=[1, 2, 2, 1],
                          padding='SAME')
</pre>
 
Then comes the second convolutional layer:
 
<pre>
    conv = tf.nn.conv2d(pool,
                        conv2_weights,
                        strides=[1, 1, 1, 1],
                        padding='SAME')
    relu = tf.nn.relu(tf.nn.bias_add(conv, conv2_biases))
    pool = tf.nn.max_pool(relu,
                          ksize=[1, 2, 2, 1],
                          strides=[1, 2, 2, 1],
                          padding='SAME')
</pre>
 
Now the pool layer is a 4D tensor. We have to reshape it into a 2D matrix so that its shape matches the shape of the fully connected layer. Just take the 2nd, 3rd, and 4th dimensions and stretch them all out into a single dimension.
 
<pre>
    # Reshape the feature map cuboid into a 2D matrix to feed it to the
    # fully connected layers.
    pool_shape = pool.get_shape().as_list()
    reshape = tf.reshape(
        pool,
        [pool_shape[0], pool_shape[1] * pool_shape[2] * pool_shape[3]])
</pre>
 
The final step is the last fully connected layer, which will output 10 signals to 10 neurons, each corresponding to our 10 classes/digits.
 
<pre>
    # Fully connected layer. Note that the '+' operation automatically
    # broadcasts the biases.
    hidden = tf.nn.relu(tf.matmul(reshape, fc1_weights) + fc1_biases)
    # Add a 50% dropout during training only. Dropout also scales
    # activations such that no rescaling is needed at evaluation time.
    if train:
       hidden = tf.nn.dropout(hidden, 0.5, seed=SEED)
 
    return tf.matmul(hidden, fc2_weights) + fc2_biases
</pre>
 
===Why Separate Variable Definitions and Model Creation===
 
The reason this network separates the variable creation, which initializes TensorFlow variables representing weights and biases, and the model creation, which is contained in a function that assembles a neural net layer by layer, is because the model will be used in two different contexts: training, and prediction.
 
The model construction always uses the same variables, no matter what the model is going to be used for. By separating variable creation from model construction, we allow the training and evaluation steps to use the same network architecture and the same weights.
 
===Training Model===
 
The training procedure starts by creating a model (calling the model() function):
 
<pre>
  # Training computation: logits + cross-entropy loss.
  logits = model(train_data_node, True)
</pre>
 
The loss function is defined as a function that seeks to minimize the cross-entropy:
 
<pre>
  loss = tf.reduce_mean(tf.nn.sparse_softmax_cross_entropy_with_logits(
      labels=train_labels_node, logits=logits))
</pre>
 
L2 regulizers are used to ensure we do not get spurious fits of constants (i.e., it will minimize the number of constants needed to fit data):
 
<prE>
  # L2 regularization for the fully connected parameters.
  regularizers = (tf.nn.l2_loss(fc1_weights) + tf.nn.l2_loss(fc1_biases) +
                  tf.nn.l2_loss(fc2_weights) + tf.nn.l2_loss(fc2_biases))
  # Add the regularization term to the loss.
  loss += 5e-4 * regularizers
</pre>
 
The L2 loss function is part of the neural network (nn) module in TensorFlow.
 
Link to nn module documentation: https://www.tensorflow.org/versions/master/api_docs/python/tf/nn
 
Last, the training schedule is set: an exponential decay schedule is used, wherein each round/batch will reduce the learning rate.
 
<pre>
  # Optimizer: set up a variable that's incremented once per batch and
  # controls the learning rate decay.
  batch = tf.Variable(0, dtype=data_type())
  # Decay once per epoch, using an exponential schedule starting at 0.01.
  learning_rate = tf.train.exponential_decay(
      0.01,                # Base learning rate.
      batch * BATCH_SIZE,  # Current index into the dataset.
      train_size,          # Decay step.
      0.95,               # Decay rate.
       staircase=True)
</pre>
 
The optimizer object is set, and it works by minimizing the loss function (the mean of the cross entropy function):
 
<pre>
  # Use simple momentum for the optimization.
  optimizer = tf.train.MomentumOptimizer(learning_rate,
                                        0.9).minimize(loss,
                                                      global_step=batch)
</pre>
 
===Evaluation Model===
 
<pre>
  # Predictions for the current training minibatch.
  train_prediction = tf.nn.softmax(logits)


   # Predictions for the test and validation, which we'll compute less often.
   # Evaluate the model and print results
  eval_prediction = tf.nn.softmax(model(eval_data))
  eval_results = mnist_classifier.evaluate(
      input_fn=lambda: input_fn(tf.estimator.ModeKeys.EVAL))
  print()
  print('Evaluation results:\n    %s' % eval_results)
</pre>
</pre>


Latest revision as of 01:44, 28 October 2017

Simple MNIST Convolutional Network

Input Function

Define an input function. This has an internal function that parses the example data (one piece of data at a time) and one-hot encodes the labeled images with the digit it corresponds to. 

def input_fn(mode, batch_size=1):
  """A simple input_fn using the contrib.data input pipeline."""

  def example_parser(serialized_example):
    """Parses a single tf.Example into image and label tensors."""
    features = tf.parse_single_example(
        serialized_example,
        features={
            'image_raw': tf.FixedLenFeature([], tf.string),
            'label': tf.FixedLenFeature([], tf.int64),
        })
    image = tf.decode_raw(features['image_raw'], tf.uint8)
    image.set_shape([28 * 28])

    # Normalize the values of the image from the range [0, 255] to [-0.5, 0.5]
    image = tf.cast(image, tf.float32) / 255 - 0.5
    label = tf.cast(features['label'], tf.int32)
    return image, tf.one_hot(label, 10)

  if mode == tf.estimator.ModeKeys.TRAIN:
    tfrecords_file = os.path.join(FLAGS.data_dir, 'train.tfrecords')
  else:
    assert mode == tf.estimator.ModeKeys.EVAL, 'invalid mode'
    tfrecords_file = os.path.join(FLAGS.data_dir, 'test.tfrecords')

  assert tf.gfile.Exists(tfrecords_file), (
      'Run convert_to_records.py first to convert the MNIST data to TFRecord '
      'file format.')

  dataset = tf.contrib.data.TFRecordDataset([tfrecords_file])

  # For training, repeat the dataset forever
  if mode == tf.estimator.ModeKeys.TRAIN:
    dataset = dataset.repeat()

  # Map example_parser over dataset, and batch results by up to batch_size
  dataset = dataset.map(
      example_parser, num_threads=1, output_buffer_size=batch_size)
  dataset = dataset.batch(batch_size)
  images, labels = dataset.make_one_shot_iterator().get_next()

  return images, labels

Prepare Model

def mnist_model(inputs, mode):
  """Takes the MNIST inputs and mode and outputs a tensor of logits."""
  # Input Layer
  # Reshape X to 4-D tensor: [batch_size, width, height, channels]
  # MNIST images are 28x28 pixels, and have one color channel
  inputs = tf.reshape(inputs, [-1, 28, 28, 1])
  data_format = FLAGS.data_format

  if data_format is None:
    # When running on GPU, transpose the data from channels_last (NHWC) to
    # channels_first (NCHW) to improve performance.
    # See https://www.tensorflow.org/performance/performance_guide#data_formats
    data_format = ('channels_first' if tf.test.is_built_with_cuda() else
                   'channels_last')

  if data_format == 'channels_first':
    inputs = tf.transpose(inputs, [0, 3, 1, 2])

Construct Model

  # Convolutional Layer #1
  # Computes 32 features using a 5x5 filter with ReLU activation.
  # Padding is added to preserve width and height.
  # Input Tensor Shape: [batch_size, 28, 28, 1]
  # Output Tensor Shape: [batch_size, 28, 28, 32]
  conv1 = tf.layers.conv2d(
      inputs=inputs,
      filters=32,
      kernel_size=[5, 5],
      padding='same',
      activation=tf.nn.relu,
      data_format=data_format)

  # Pooling Layer #1
  # First max pooling layer with a 2x2 filter and stride of 2
  # Input Tensor Shape: [batch_size, 28, 28, 32]
  # Output Tensor Shape: [batch_size, 14, 14, 32]
  pool1 = tf.layers.max_pooling2d(inputs=conv1, pool_size=[2, 2], strides=2,
                                  data_format=data_format)

  # Convolutional Layer #2
  # Computes 64 features using a 5x5 filter.
  # Padding is added to preserve width and height.
  # Input Tensor Shape: [batch_size, 14, 14, 32]
  # Output Tensor Shape: [batch_size, 14, 14, 64]
  conv2 = tf.layers.conv2d(
      inputs=pool1,
      filters=64,
      kernel_size=[5, 5],
      padding='same',
      activation=tf.nn.relu,
      data_format=data_format)

  # Pooling Layer #2
  # Second max pooling layer with a 2x2 filter and stride of 2
  # Input Tensor Shape: [batch_size, 14, 14, 64]
  # Output Tensor Shape: [batch_size, 7, 7, 64]
  pool2 = tf.layers.max_pooling2d(inputs=conv2, pool_size=[2, 2], strides=2,
                                  data_format=data_format)

  # Flatten tensor into a batch of vectors
  # Input Tensor Shape: [batch_size, 7, 7, 64]
  # Output Tensor Shape: [batch_size, 7 * 7 * 64]
  pool2_flat = tf.reshape(pool2, [-1, 7 * 7 * 64])

  # Dense Layer
  # Densely connected layer with 1024 neurons
  # Input Tensor Shape: [batch_size, 7 * 7 * 64]
  # Output Tensor Shape: [batch_size, 1024]
  dense = tf.layers.dense(inputs=pool2_flat, units=1024,
                          activation=tf.nn.relu)

  # Add dropout operation; 0.6 probability that element will be kept
  dropout = tf.layers.dropout(
      inputs=dense, rate=0.4, training=(mode == tf.estimator.ModeKeys.TRAIN))

  # Logits layer
  # Input Tensor Shape: [batch_size, 1024]
  # Output Tensor Shape: [batch_size, 10]
  logits = tf.layers.dense(inputs=dropout, units=10)
  return logits

Get Estimator

def mnist_model_fn(features, labels, mode):
  """Model function for MNIST."""
  logits = mnist_model(features, mode)

  predictions = {
      'classes': tf.argmax(input=logits, axis=1),
      'probabilities': tf.nn.softmax(logits, name='softmax_tensor')
  }

  if mode == tf.estimator.ModeKeys.PREDICT:
    return tf.estimator.EstimatorSpec(mode=mode, predictions=predictions)

  loss = tf.losses.softmax_cross_entropy(onehot_labels=labels, logits=logits)

  # Configure the training op
  if mode == tf.estimator.ModeKeys.TRAIN:
    optimizer = tf.train.AdamOptimizer(learning_rate=1e-4)
    train_op = optimizer.minimize(loss, tf.train.get_or_create_global_step())
  else:
    train_op = None

  accuracy = tf.metrics.accuracy(
      tf.argmax(labels, axis=1), predictions['classes'])
  metrics = {'accuracy': accuracy}

  # Create a tensor named train_accuracy for logging purposes
  tf.identity(accuracy[1], name='train_accuracy')
  tf.summary.scalar('train_accuracy', accuracy[1])

  return tf.estimator.EstimatorSpec(
      mode=mode,
      predictions=predictions,
      loss=loss,
      train_op=train_op,
      eval_metric_ops=metrics)

Main Function

def main(unused_argv):
  # Create the Estimator
  mnist_classifier = tf.estimator.Estimator(
      model_fn=mnist_model_fn, model_dir=FLAGS.model_dir)

  # Train the model
  tensors_to_log = {
      'train_accuracy': 'train_accuracy'
  }

  logging_hook = tf.train.LoggingTensorHook(
      tensors=tensors_to_log, every_n_iter=100)

  batches_per_epoch = _NUM_IMAGES['train'] / FLAGS.batch_size

  mnist_classifier.train(
      input_fn=lambda: input_fn(tf.estimator.ModeKeys.TRAIN, FLAGS.batch_size),
      steps=FLAGS.train_epochs * batches_per_epoch,
      hooks=[logging_hook])

  # Evaluate the model and print results
  eval_results = mnist_classifier.evaluate(
      input_fn=lambda: input_fn(tf.estimator.ModeKeys.EVAL))
  print()
  print('Evaluation results:\n    %s' % eval_results)

Flags

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