cifar10_input.py
# 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. # ============================================================================== """Routine for decoding the CIFAR-10 binary file format.""" from __future__ import absolute_import from __future__ import division from __future__ import print_function import os from six.moves import xrange # pylint: disable=redefined-builtin import tensorflow as tf # 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 def read_cifar10(filename_queue): """Reads and parses examples from CIFAR10 data files. Recommendation: if you want N-way read parallelism, call this function N times. This will give you N independent Readers reading different files & positions within those files, which will give better mixing of examples. Args: filename_queue: A queue of strings with the filenames to read from. Returns: An object representing a single example, with the following fields: height: number of rows in the result (32) width: number of columns in the result (32) depth: number of color channels in the result (3) key: a scalar string Tensor describing the filename & record number for this example. label: an int32 Tensor with the label in the range 0..9. uint8image: a [height, width, depth] uint8 Tensor with the image data """ class CIFAR10Record(object): pass result = CIFAR10Record() # Dimensions of the images in the CIFAR-10 dataset. # See http://www.cs.toronto.edu/~kriz/cifar.html for a description of the # input format. label_bytes = 1 # 2 for CIFAR-100 result.height = 32 result.width = 32 result.depth = 3 image_bytes = result.height * result.width * result.depth # Every record consists of a label followed by the image, with a # fixed number of bytes for each. record_bytes = label_bytes + image_bytes # Read a record, getting filenames from the filename_queue. No # header or footer in the CIFAR-10 format, so we leave header_bytes # and footer_bytes at their default of 0. reader = tf.FixedLengthRecordReader(record_bytes=record_bytes) result.key, value = reader.read(filename_queue) # Convert from a string to a vector of uint8 that is record_bytes long. record_bytes = tf.decode_raw(value, tf.uint8) # The first bytes represent the label, which we convert from uint8->int32. result.label = tf.cast( tf.strided_slice(record_bytes, [0], [label_bytes]), tf.int32) # The remaining bytes after the label represent the image, which we reshape # from [depth * height * width] to [depth, height, width]. depth_major = tf.reshape( tf.strided_slice(record_bytes, [label_bytes], [label_bytes + image_bytes]), [result.depth, result.height, result.width]) # Convert from [depth, height, width] to [height, width, depth]. result.uint8image = tf.transpose(depth_major, [1, 2, 0]) return result def _generate_image_and_label_batch(image, label, min_queue_examples, batch_size, shuffle): """Construct a queued batch of images and labels. Args: image: 3-D Tensor of [height, width, 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. batch_size: Number of images per batch. shuffle: boolean indicating whether to use a shuffling queue. Returns: images: Images. 4D tensor of [batch_size, height, width, 3] size. labels: Labels. 1D tensor of [batch_size] size. """ # Create a queue that shuffles the examples, and then # read 'batch_size' images + labels from the example queue. num_preprocess_threads = 16 if shuffle: images, label_batch = tf.train.shuffle_batch( [image, label], batch_size=batch_size, num_threads=num_preprocess_threads, capacity=min_queue_examples + 3 * batch_size, min_after_dequeue=min_queue_examples) else: images, label_batch = tf.train.batch( [image, label], batch_size=batch_size, num_threads=num_preprocess_threads, capacity=min_queue_examples + 3 * batch_size) # Display the training images in the visualizer. tf.summary.image('images', images) return images, tf.reshape(label_batch, [batch_size]) def distorted_inputs(data_dir, batch_size): """Construct distorted input for CIFAR training using the Reader ops. Args: data_dir: Path to the CIFAR-10 data directory. batch_size: Number of images per batch. 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(data_dir, 'data_batch_%d.bin' % i) for i in xrange(1, 6)] for f in filenames: if not tf.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) with tf.name_scope('data_augmentation'): # Read examples from files in the filename queue. read_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.random_crop(reshaped_image, [height, width, 3]) # Randomly flip the image horizontally. distorted_image = tf.image.random_flip_left_right(distorted_image) # Because these operations are not commutative, consider randomizing # the order their operation. # NOTE: since per_image_standardization zeros the mean and makes # the stddev unit, this likely has no effect see tensorflow#1458. 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_standardization(distorted_image) # Set the shapes of tensors. float_image.set_shape([height, width, 3]) read_input.label.set_shape([1]) # 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, batch_size, shuffle=True) def inputs(eval_data, data_dir, batch_size): """Construct input for CIFAR evaluation using the Reader ops. Args: eval_data: bool, indicating if one should use the train or eval data set. data_dir: Path to the CIFAR-10 data directory. batch_size: Number of images per batch. Returns: images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size. labels: Labels. 1D tensor of [batch_size] size. """ if not eval_data: filenames = [os.path.join(data_dir, '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(data_dir, 'test_batch.bin')] num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_EVAL for f in filenames: if not tf.gfile.Exists(f): raise ValueError('Failed to find file: ' + f) with tf.name_scope('input'): # 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 = 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, height, width) # Subtract off the mean and divide by the variance of the pixels. float_image = tf.image.per_image_standardization(resized_image) # Set the shapes of tensors. float_image.set_shape([height, width, 3]) read_input.label.set_shape([1]) # 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, batch_size, shuffle=False)