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# 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. | |
# ============================================================================== | |
r"""Simple transfer learning with Inception v3 or Mobilenet models. | |
With support for TensorBoard. | |
This example shows how to take a Inception v3 or Mobilenet model trained on | |
ImageNet images, and train a new top layer that can recognize other classes of | |
images. | |
The top layer receives as input a 2048-dimensional vector (1001-dimensional for | |
Mobilenet) for each image. We train a softmax layer on top of this | |
representation. Assuming the softmax layer contains N labels, this corresponds | |
to learning N + 2048*N (or 1001*N) model parameters corresponding to the | |
learned biases and weights. | |
Here's an example, which assumes you have a folder containing class-named | |
subfolders, each full of images for each label. The example folder flower_photos | |
should have a structure like this: | |
~/flower_photos/daisy/photo1.jpg | |
~/flower_photos/daisy/photo2.jpg | |
... | |
~/flower_photos/rose/anotherphoto77.jpg | |
... | |
~/flower_photos/sunflower/somepicture.jpg | |
The subfolder names are important, since they define what label is applied to | |
each image, but the filenames themselves don't matter. Once your images are | |
prepared, you can run the training with a command like this: | |
```bash | |
bazel build tensorflow/examples/image_retraining:retrain && \ | |
bazel-bin/tensorflow/examples/image_retraining/retrain \ | |
--image_dir ~/flower_photos | |
``` | |
Or, if you have a pip installation of tensorflow, `retrain.py` can be run | |
without bazel: | |
```bash | |
python tensorflow/examples/image_retraining/retrain.py \ | |
--image_dir ~/flower_photos | |
``` | |
You can replace the image_dir argument with any folder containing subfolders of | |
images. The label for each image is taken from the name of the subfolder it's | |
in. | |
This produces a new model file that can be loaded and run by any TensorFlow | |
program, for example the label_image sample code. | |
By default this script will use the high accuracy, but comparatively large and | |
slow Inception v3 model architecture. It's recommended that you start with this | |
to validate that you have gathered good training data, but if you want to deploy | |
on resource-limited platforms, you can try the `--architecture` flag with a | |
Mobilenet model. For example: | |
```bash | |
python tensorflow/examples/image_retraining/retrain.py \ | |
--image_dir ~/flower_photos --architecture mobilenet_1.0_224 | |
``` | |
There are 32 different Mobilenet models to choose from, with a variety of file | |
size and latency options. The first number can be '1.0', '0.75', '0.50', or | |
'0.25' to control the size, and the second controls the input image size, either | |
'224', '192', '160', or '128', with smaller sizes running faster. See | |
https://research.googleblog.com/2017/06/mobilenets-open-source-models-for.html | |
for more information on Mobilenet. | |
To use with TensorBoard: | |
By default, this script will log summaries to /tmp/retrain_logs directory | |
Visualize the summaries with this command: | |
tensorboard --logdir /tmp/retrain_logs | |
""" | |
from __future__ import absolute_import | |
from __future__ import division | |
from __future__ import print_function | |
import argparse | |
import collections | |
from datetime import datetime | |
import hashlib | |
import os.path | |
import random | |
import re | |
import sys | |
import tarfile | |
import numpy as np | |
from six.moves import urllib | |
import tensorflow as tf | |
from tensorflow.python.framework import graph_util | |
from tensorflow.python.framework import tensor_shape | |
from tensorflow.python.platform import gfile | |
from tensorflow.python.util import compat | |
FLAGS = None | |
# These are all parameters that are tied to the particular model architecture | |
# we're using for Inception v3. These include things like tensor names and their | |
# sizes. If you want to adapt this script to work with another model, you will | |
# need to update these to reflect the values in the network you're using. | |
MAX_NUM_IMAGES_PER_CLASS = 2 ** 27 - 1 # ~134M | |
def create_image_lists(image_dir, testing_percentage, validation_percentage): | |
"""Builds a list of training images from the file system. | |
Analyzes the sub folders in the image directory, splits them into stable | |
training, testing, and validation sets, and returns a data structure | |
describing the lists of images for each label and their paths. | |
Args: | |
image_dir: String path to a folder containing subfolders of images. | |
testing_percentage: Integer percentage of the images to reserve for tests. | |
validation_percentage: Integer percentage of images reserved for validation. | |
Returns: | |
A dictionary containing an entry for each label subfolder, with images split | |
into training, testing, and validation sets within each label. | |
""" | |
if not gfile.Exists(image_dir): | |
tf.logging.error("Image directory '" + image_dir + "' not found.") | |
return None | |
result = collections.OrderedDict() | |
sub_dirs = [ | |
os.path.join(image_dir,item) | |
for item in gfile.ListDirectory(image_dir)] | |
sub_dirs = sorted(item for item in sub_dirs | |
if gfile.IsDirectory(item)) | |
for sub_dir in sub_dirs: | |
extensions = ['jpg', 'jpeg', 'JPG', 'JPEG'] | |
file_list = [] | |
dir_name = os.path.basename(sub_dir) | |
if dir_name == image_dir: | |
continue | |
tf.logging.info("Looking for images in '" + dir_name + "'") | |
for extension in extensions: | |
file_glob = os.path.join(image_dir, dir_name, '*.' + extension) | |
file_list.extend(gfile.Glob(file_glob)) | |
if not file_list: | |
tf.logging.warning('No files found') | |
continue | |
if len(file_list) < 20: | |
tf.logging.warning( | |
'WARNING: Folder has less than 20 images, which may cause issues.') | |
elif len(file_list) > MAX_NUM_IMAGES_PER_CLASS: | |
tf.logging.warning( | |
'WARNING: Folder {} has more than {} images. Some images will ' | |
'never be selected.'.format(dir_name, MAX_NUM_IMAGES_PER_CLASS)) | |
label_name = re.sub(r'[^a-z0-9]+', ' ', dir_name.lower()) | |
training_images = [] | |
testing_images = [] | |
validation_images = [] | |
for file_name in file_list: | |
base_name = os.path.basename(file_name) | |
# We want to ignore anything after '_nohash_' in the file name when | |
# deciding which set to put an image in, the data set creator has a way of | |
# grouping photos that are close variations of each other. For example | |
# this is used in the plant disease data set to group multiple pictures of | |
# the same leaf. | |
hash_name = re.sub(r'_nohash_.*$', '', file_name) | |
# This looks a bit magical, but we need to decide whether this file should | |
# go into the training, testing, or validation sets, and we want to keep | |
# existing files in the same set even if more files are subsequently | |
# added. | |
# To do that, we need a stable way of deciding based on just the file name | |
# itself, so we do a hash of that and then use that to generate a | |
# probability value that we use to assign it. | |
hash_name_hashed = hashlib.sha1(compat.as_bytes(hash_name)).hexdigest() | |
percentage_hash = ((int(hash_name_hashed, 16) % | |
(MAX_NUM_IMAGES_PER_CLASS + 1)) * | |
(100.0 / MAX_NUM_IMAGES_PER_CLASS)) | |
if percentage_hash < validation_percentage: | |
validation_images.append(base_name) | |
elif percentage_hash < (testing_percentage + validation_percentage): | |
testing_images.append(base_name) | |
else: | |
training_images.append(base_name) | |
result[label_name] = { | |
'dir': dir_name, | |
'training': training_images, | |
'testing': testing_images, | |
'validation': validation_images, | |
} | |
return result | |
def get_image_path(image_lists, label_name, index, image_dir, category): | |
""""Returns a path to an image for a label at the given index. | |
Args: | |
image_lists: Dictionary of training images for each label. | |
label_name: Label string we want to get an image for. | |
index: Int offset of the image we want. This will be moduloed by the | |
available number of images for the label, so it can be arbitrarily large. | |
image_dir: Root folder string of the subfolders containing the training | |
images. | |
category: Name string of set to pull images from - training, testing, or | |
validation. | |
Returns: | |
File system path string to an image that meets the requested parameters. | |
""" | |
if label_name not in image_lists: | |
tf.logging.fatal('Label does not exist %s.', label_name) | |
label_lists = image_lists[label_name] | |
if category not in label_lists: | |
tf.logging.fatal('Category does not exist %s.', category) | |
category_list = label_lists[category] | |
if not category_list: | |
tf.logging.fatal('Label %s has no images in the category %s.', | |
label_name, category) | |
mod_index = index % len(category_list) | |
base_name = category_list[mod_index] | |
sub_dir = label_lists['dir'] | |
full_path = os.path.join(image_dir, sub_dir, base_name) | |
return full_path | |
def get_bottleneck_path(image_lists, label_name, index, bottleneck_dir, | |
category, architecture): | |
""""Returns a path to a bottleneck file for a label at the given index. | |
Args: | |
image_lists: Dictionary of training images for each label. | |
label_name: Label string we want to get an image for. | |
index: Integer offset of the image we want. This will be moduloed by the | |
available number of images for the label, so it can be arbitrarily large. | |
bottleneck_dir: Folder string holding cached files of bottleneck values. | |
category: Name string of set to pull images from - training, testing, or | |
validation. | |
architecture: The name of the model architecture. | |
Returns: | |
File system path string to an image that meets the requested parameters. | |
""" | |
return get_image_path(image_lists, label_name, index, bottleneck_dir, | |
category) + '_' + architecture + '.txt' | |
def create_model_graph(model_info): | |
""""Creates a graph from saved GraphDef file and returns a Graph object. | |
Args: | |
model_info: Dictionary containing information about the model architecture. | |
Returns: | |
Graph holding the trained Inception network, and various tensors we'll be | |
manipulating. | |
""" | |
with tf.Graph().as_default() as graph: | |
model_path = os.path.join(FLAGS.model_dir, model_info['model_file_name']) | |
with gfile.FastGFile(model_path, 'rb') as f: | |
graph_def = tf.GraphDef() | |
graph_def.ParseFromString(f.read()) | |
bottleneck_tensor, resized_input_tensor = (tf.import_graph_def( | |
graph_def, | |
name='', | |
return_elements=[ | |
model_info['bottleneck_tensor_name'], | |
model_info['resized_input_tensor_name'], | |
])) | |
return graph, bottleneck_tensor, resized_input_tensor | |
def run_bottleneck_on_image(sess, image_data, image_data_tensor, | |
decoded_image_tensor, resized_input_tensor, | |
bottleneck_tensor): | |
"""Runs inference on an image to extract the 'bottleneck' summary layer. | |
Args: | |
sess: Current active TensorFlow Session. | |
image_data: String of raw JPEG data. | |
image_data_tensor: Input data layer in the graph. | |
decoded_image_tensor: Output of initial image resizing and preprocessing. | |
resized_input_tensor: The input node of the recognition graph. | |
bottleneck_tensor: Layer before the final softmax. | |
Returns: | |
Numpy array of bottleneck values. | |
""" | |
# First decode the JPEG image, resize it, and rescale the pixel values. | |
resized_input_values = sess.run(decoded_image_tensor, | |
{image_data_tensor: image_data}) | |
# Then run it through the recognition network. | |
bottleneck_values = sess.run(bottleneck_tensor, | |
{resized_input_tensor: resized_input_values}) | |
bottleneck_values = np.squeeze(bottleneck_values) | |
return bottleneck_values | |
def maybe_download_and_extract(data_url): | |
"""Download and extract model tar file. | |
If the pretrained model we're using doesn't already exist, this function | |
downloads it from the TensorFlow.org website and unpacks it into a directory. | |
Args: | |
data_url: Web location of the tar file containing the pretrained model. | |
""" | |
dest_directory = FLAGS.model_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, _progress) | |
print() | |
statinfo = os.stat(filepath) | |
tf.logging.info('Successfully downloaded', filename, statinfo.st_size, | |
'bytes.') | |
tarfile.open(filepath, 'r:gz').extractall(dest_directory) | |
def ensure_dir_exists(dir_name): | |
"""Makes sure the folder exists on disk. | |
Args: | |
dir_name: Path string to the folder we want to create. | |
""" | |
if not os.path.exists(dir_name): | |
os.makedirs(dir_name) | |
bottleneck_path_2_bottleneck_values = {} | |
def create_bottleneck_file(bottleneck_path, image_lists, label_name, index, | |
image_dir, category, sess, jpeg_data_tensor, | |
decoded_image_tensor, resized_input_tensor, | |
bottleneck_tensor): | |
"""Create a single bottleneck file.""" | |
tf.logging.info('Creating bottleneck at ' + bottleneck_path) | |
image_path = get_image_path(image_lists, label_name, index, | |
image_dir, category) | |
if not gfile.Exists(image_path): | |
tf.logging.fatal('File does not exist %s', image_path) | |
image_data = gfile.FastGFile(image_path, 'rb').read() | |
try: | |
bottleneck_values = run_bottleneck_on_image( | |
sess, image_data, jpeg_data_tensor, decoded_image_tensor, | |
resized_input_tensor, bottleneck_tensor) | |
except Exception as e: | |
raise RuntimeError('Error during processing file %s (%s)' % (image_path, | |
str(e))) | |
bottleneck_string = ','.join(str(x) for x in bottleneck_values) | |
with open(bottleneck_path, 'w') as bottleneck_file: | |
bottleneck_file.write(bottleneck_string) | |
def get_or_create_bottleneck(sess, image_lists, label_name, index, image_dir, | |
category, bottleneck_dir, jpeg_data_tensor, | |
decoded_image_tensor, resized_input_tensor, | |
bottleneck_tensor, architecture): | |
"""Retrieves or calculates bottleneck values for an image. | |
If a cached version of the bottleneck data exists on-disk, return that, | |
otherwise calculate the data and save it to disk for future use. | |
Args: | |
sess: The current active TensorFlow Session. | |
image_lists: Dictionary of training images for each label. | |
label_name: Label string we want to get an image for. | |
index: Integer offset of the image we want. This will be modulo-ed by the | |
available number of images for the label, so it can be arbitrarily large. | |
image_dir: Root folder string of the subfolders containing the training | |
images. | |
category: Name string of which set to pull images from - training, testing, | |
or validation. | |
bottleneck_dir: Folder string holding cached files of bottleneck values. | |
jpeg_data_tensor: The tensor to feed loaded jpeg data into. | |
decoded_image_tensor: The output of decoding and resizing the image. | |
resized_input_tensor: The input node of the recognition graph. | |
bottleneck_tensor: The output tensor for the bottleneck values. | |
architecture: The name of the model architecture. | |
Returns: | |
Numpy array of values produced by the bottleneck layer for the image. | |
""" | |
label_lists = image_lists[label_name] | |
sub_dir = label_lists['dir'] | |
sub_dir_path = os.path.join(bottleneck_dir, sub_dir) | |
ensure_dir_exists(sub_dir_path) | |
bottleneck_path = get_bottleneck_path(image_lists, label_name, index, | |
bottleneck_dir, category, architecture) | |
if not os.path.exists(bottleneck_path): | |
create_bottleneck_file(bottleneck_path, image_lists, label_name, index, | |
image_dir, category, sess, jpeg_data_tensor, | |
decoded_image_tensor, resized_input_tensor, | |
bottleneck_tensor) | |
with open(bottleneck_path, 'r') as bottleneck_file: | |
bottleneck_string = bottleneck_file.read() | |
did_hit_error = False | |
try: | |
bottleneck_values = [float(x) for x in bottleneck_string.split(',')] | |
except ValueError: | |
tf.logging.warning('Invalid float found, recreating bottleneck') | |
did_hit_error = True | |
if did_hit_error: | |
create_bottleneck_file(bottleneck_path, image_lists, label_name, index, | |
image_dir, category, sess, jpeg_data_tensor, | |
decoded_image_tensor, resized_input_tensor, | |
bottleneck_tensor) | |
with open(bottleneck_path, 'r') as bottleneck_file: | |
bottleneck_string = bottleneck_file.read() | |
# Allow exceptions to propagate here, since they shouldn't happen after a | |
# fresh creation | |
bottleneck_values = [float(x) for x in bottleneck_string.split(',')] | |
return bottleneck_values | |
def cache_bottlenecks(sess, image_lists, image_dir, bottleneck_dir, | |
jpeg_data_tensor, decoded_image_tensor, | |
resized_input_tensor, bottleneck_tensor, architecture): | |
"""Ensures all the training, testing, and validation bottlenecks are cached. | |
Because we're likely to read the same image multiple times (if there are no | |
distortions applied during training) it can speed things up a lot if we | |
calculate the bottleneck layer values once for each image during | |
preprocessing, and then just read those cached values repeatedly during | |
training. Here we go through all the images we've found, calculate those | |
values, and save them off. | |
Args: | |
sess: The current active TensorFlow Session. | |
image_lists: Dictionary of training images for each label. | |
image_dir: Root folder string of the subfolders containing the training | |
images. | |
bottleneck_dir: Folder string holding cached files of bottleneck values. | |
jpeg_data_tensor: Input tensor for jpeg data from file. | |
decoded_image_tensor: The output of decoding and resizing the image. | |
resized_input_tensor: The input node of the recognition graph. | |
bottleneck_tensor: The penultimate output layer of the graph. | |
architecture: The name of the model architecture. | |
Returns: | |
Nothing. | |
""" | |
how_many_bottlenecks = 0 | |
ensure_dir_exists(bottleneck_dir) | |
for label_name, label_lists in image_lists.items(): | |
for category in ['training', 'testing', 'validation']: | |
category_list = label_lists[category] | |
for index, unused_base_name in enumerate(category_list): | |
get_or_create_bottleneck( | |
sess, image_lists, label_name, index, image_dir, category, | |
bottleneck_dir, jpeg_data_tensor, decoded_image_tensor, | |
resized_input_tensor, bottleneck_tensor, architecture) | |
how_many_bottlenecks += 1 | |
if how_many_bottlenecks % 100 == 0: | |
tf.logging.info( | |
str(how_many_bottlenecks) + ' bottleneck files created.') | |
def get_random_cached_bottlenecks(sess, image_lists, how_many, category, | |
bottleneck_dir, image_dir, jpeg_data_tensor, | |
decoded_image_tensor, resized_input_tensor, | |
bottleneck_tensor, architecture): | |
"""Retrieves bottleneck values for cached images. | |
If no distortions are being applied, this function can retrieve the cached | |
bottleneck values directly from disk for images. It picks a random set of | |
images from the specified category. | |
Args: | |
sess: Current TensorFlow Session. | |
image_lists: Dictionary of training images for each label. | |
how_many: If positive, a random sample of this size will be chosen. | |
If negative, all bottlenecks will be retrieved. | |
category: Name string of which set to pull from - training, testing, or | |
validation. | |
bottleneck_dir: Folder string holding cached files of bottleneck values. | |
image_dir: Root folder string of the subfolders containing the training | |
images. | |
jpeg_data_tensor: The layer to feed jpeg image data into. | |
decoded_image_tensor: The output of decoding and resizing the image. | |
resized_input_tensor: The input node of the recognition graph. | |
bottleneck_tensor: The bottleneck output layer of the CNN graph. | |
architecture: The name of the model architecture. | |
Returns: | |
List of bottleneck arrays, their corresponding ground truths, and the | |
relevant filenames. | |
""" | |
class_count = len(image_lists.keys()) | |
bottlenecks = [] | |
ground_truths = [] | |
filenames = [] | |
if how_many >= 0: | |
# Retrieve a random sample of bottlenecks. | |
for unused_i in range(how_many): | |
label_index = random.randrange(class_count) | |
label_name = list(image_lists.keys())[label_index] | |
image_index = random.randrange(MAX_NUM_IMAGES_PER_CLASS + 1) | |
image_name = get_image_path(image_lists, label_name, image_index, | |
image_dir, category) | |
bottleneck = get_or_create_bottleneck( | |
sess, image_lists, label_name, image_index, image_dir, category, | |
bottleneck_dir, jpeg_data_tensor, decoded_image_tensor, | |
resized_input_tensor, bottleneck_tensor, architecture) | |
ground_truth = np.zeros(class_count, dtype=np.float32) | |
ground_truth[label_index] = 1.0 | |
bottlenecks.append(bottleneck) | |
ground_truths.append(ground_truth) | |
filenames.append(image_name) | |
else: | |
# Retrieve all bottlenecks. | |
for label_index, label_name in enumerate(image_lists.keys()): | |
for image_index, image_name in enumerate( | |
image_lists[label_name][category]): | |
image_name = get_image_path(image_lists, label_name, image_index, | |
image_dir, category) | |
bottleneck = get_or_create_bottleneck( | |
sess, image_lists, label_name, image_index, image_dir, category, | |
bottleneck_dir, jpeg_data_tensor, decoded_image_tensor, | |
resized_input_tensor, bottleneck_tensor, architecture) | |
ground_truth = np.zeros(class_count, dtype=np.float32) | |
ground_truth[label_index] = 1.0 | |
bottlenecks.append(bottleneck) | |
ground_truths.append(ground_truth) | |
filenames.append(image_name) | |
return bottlenecks, ground_truths, filenames | |
def get_random_distorted_bottlenecks( | |
sess, image_lists, how_many, category, image_dir, input_jpeg_tensor, | |
distorted_image, resized_input_tensor, bottleneck_tensor): | |
"""Retrieves bottleneck values for training images, after distortions. | |
If we're training with distortions like crops, scales, or flips, we have to | |
recalculate the full model for every image, and so we can't use cached | |
bottleneck values. Instead we find random images for the requested category, | |
run them through the distortion graph, and then the full graph to get the | |
bottleneck results for each. | |
Args: | |
sess: Current TensorFlow Session. | |
image_lists: Dictionary of training images for each label. | |
how_many: The integer number of bottleneck values to return. | |
category: Name string of which set of images to fetch - training, testing, | |
or validation. | |
image_dir: Root folder string of the subfolders containing the training | |
images. | |
input_jpeg_tensor: The input layer we feed the image data to. | |
distorted_image: The output node of the distortion graph. | |
resized_input_tensor: The input node of the recognition graph. | |
bottleneck_tensor: The bottleneck output layer of the CNN graph. | |
Returns: | |
List of bottleneck arrays and their corresponding ground truths. | |
""" | |
class_count = len(image_lists.keys()) | |
bottlenecks = [] | |
ground_truths = [] | |
for unused_i in range(how_many): | |
label_index = random.randrange(class_count) | |
label_name = list(image_lists.keys())[label_index] | |
image_index = random.randrange(MAX_NUM_IMAGES_PER_CLASS + 1) | |
image_path = get_image_path(image_lists, label_name, image_index, image_dir, | |
category) | |
if not gfile.Exists(image_path): | |
tf.logging.fatal('File does not exist %s', image_path) | |
jpeg_data = gfile.FastGFile(image_path, 'rb').read() | |
# Note that we materialize the distorted_image_data as a numpy array before | |
# sending running inference on the image. This involves 2 memory copies and | |
# might be optimized in other implementations. | |
distorted_image_data = sess.run(distorted_image, | |
{input_jpeg_tensor: jpeg_data}) | |
bottleneck_values = sess.run(bottleneck_tensor, | |
{resized_input_tensor: distorted_image_data}) | |
bottleneck_values = np.squeeze(bottleneck_values) | |
ground_truth = np.zeros(class_count, dtype=np.float32) | |
ground_truth[label_index] = 1.0 | |
bottlenecks.append(bottleneck_values) | |
ground_truths.append(ground_truth) | |
return bottlenecks, ground_truths | |
def should_distort_images(flip_left_right, random_crop, random_scale, | |
random_brightness): | |
"""Whether any distortions are enabled, from the input flags. | |
Args: | |
flip_left_right: Boolean whether to randomly mirror images horizontally. | |
random_crop: Integer percentage setting the total margin used around the | |
crop box. | |
random_scale: Integer percentage of how much to vary the scale by. | |
random_brightness: Integer range to randomly multiply the pixel values by. | |
Returns: | |
Boolean value indicating whether any distortions should be applied. | |
""" | |
return (flip_left_right or (random_crop != 0) or (random_scale != 0) or | |
(random_brightness != 0)) | |
def add_input_distortions(flip_left_right, random_crop, random_scale, | |
random_brightness, input_width, input_height, | |
input_depth, input_mean, input_std): | |
"""Creates the operations to apply the specified distortions. | |
During training it can help to improve the results if we run the images | |
through simple distortions like crops, scales, and flips. These reflect the | |
kind of variations we expect in the real world, and so can help train the | |
model to cope with natural data more effectively. Here we take the supplied | |
parameters and construct a network of operations to apply them to an image. | |
Cropping | |
~~~~~~~~ | |
Cropping is done by placing a bounding box at a random position in the full | |
image. The cropping parameter controls the size of that box relative to the | |
input image. If it's zero, then the box is the same size as the input and no | |
cropping is performed. If the value is 50%, then the crop box will be half the | |
width and height of the input. In a diagram it looks like this: | |
< width > | |
+---------------------+ | |
| | | |
| width - crop% | | |
| < > | | |
| +------+ | | |
| | | | | |
| | | | | |
| | | | | |
| +------+ | | |
| | | |
| | | |
+---------------------+ | |
Scaling | |
~~~~~~~ | |
Scaling is a lot like cropping, except that the bounding box is always | |
centered and its size varies randomly within the given range. For example if | |
the scale percentage is zero, then the bounding box is the same size as the | |
input and no scaling is applied. If it's 50%, then the bounding box will be in | |
a random range between half the width and height and full size. | |
Args: | |
flip_left_right: Boolean whether to randomly mirror images horizontally. | |
random_crop: Integer percentage setting the total margin used around the | |
crop box. | |
random_scale: Integer percentage of how much to vary the scale by. | |
random_brightness: Integer range to randomly multiply the pixel values by. | |
graph. | |
input_width: Horizontal size of expected input image to model. | |
input_height: Vertical size of expected input image to model. | |
input_depth: How many channels the expected input image should have. | |
input_mean: Pixel value that should be zero in the image for the graph. | |
input_std: How much to divide the pixel values by before recognition. | |
Returns: | |
The jpeg input layer and the distorted result tensor. | |
""" | |
jpeg_data = tf.placeholder(tf.string, name='DistortJPGInput') | |
decoded_image = tf.image.decode_jpeg(jpeg_data, channels=input_depth) | |
decoded_image_as_float = tf.cast(decoded_image, dtype=tf.float32) | |
decoded_image_4d = tf.expand_dims(decoded_image_as_float, 0) | |
margin_scale = 1.0 + (random_crop / 100.0) | |
resize_scale = 1.0 + (random_scale / 100.0) | |
margin_scale_value = tf.constant(margin_scale) | |
resize_scale_value = tf.random_uniform(tensor_shape.scalar(), | |
minval=1.0, | |
maxval=resize_scale) | |
scale_value = tf.multiply(margin_scale_value, resize_scale_value) | |
precrop_width = tf.multiply(scale_value, input_width) | |
precrop_height = tf.multiply(scale_value, input_height) | |
precrop_shape = tf.stack([precrop_height, precrop_width]) | |
precrop_shape_as_int = tf.cast(precrop_shape, dtype=tf.int32) | |
precropped_image = tf.image.resize_bilinear(decoded_image_4d, | |
precrop_shape_as_int) | |
precropped_image_3d = tf.squeeze(precropped_image, squeeze_dims=[0]) | |
cropped_image = tf.random_crop(precropped_image_3d, | |
[input_height, input_width, input_depth]) | |
if flip_left_right: | |
flipped_image = tf.image.random_flip_left_right(cropped_image) | |
else: | |
flipped_image = cropped_image | |
brightness_min = 1.0 - (random_brightness / 100.0) | |
brightness_max = 1.0 + (random_brightness / 100.0) | |
brightness_value = tf.random_uniform(tensor_shape.scalar(), | |
minval=brightness_min, | |
maxval=brightness_max) | |
brightened_image = tf.multiply(flipped_image, brightness_value) | |
offset_image = tf.subtract(brightened_image, input_mean) | |
mul_image = tf.multiply(offset_image, 1.0 / input_std) | |
distort_result = tf.expand_dims(mul_image, 0, name='DistortResult') | |
return jpeg_data, distort_result | |
def variable_summaries(var): | |
"""Attach a lot of summaries to a Tensor (for TensorBoard visualization).""" | |
with tf.name_scope('summaries'): | |
mean = tf.reduce_mean(var) | |
tf.summary.scalar('mean', mean) | |
with tf.name_scope('stddev'): | |
stddev = tf.sqrt(tf.reduce_mean(tf.square(var - mean))) | |
tf.summary.scalar('stddev', stddev) | |
tf.summary.scalar('max', tf.reduce_max(var)) | |
tf.summary.scalar('min', tf.reduce_min(var)) | |
tf.summary.histogram('histogram', var) | |
def add_final_training_ops(class_count, final_tensor_name, bottleneck_tensor, | |
bottleneck_tensor_size): | |
"""Adds a new softmax and fully-connected layer for training. | |
We need to retrain the top layer to identify our new classes, so this function | |
adds the right operations to the graph, along with some variables to hold the | |
weights, and then sets up all the gradients for the backward pass. | |
The set up for the softmax and fully-connected layers is based on: | |
https://www.tensorflow.org/versions/master/tutorials/mnist/beginners/index.html | |
Args: | |
class_count: Integer of how many categories of things we're trying to | |
recognize. | |
final_tensor_name: Name string for the new final node that produces results. | |
bottleneck_tensor: The output of the main CNN graph. | |
bottleneck_tensor_size: How many entries in the bottleneck vector. | |
Returns: | |
The tensors for the training and cross entropy results, and tensors for the | |
bottleneck input and ground truth input. | |
""" | |
with tf.name_scope('input'): | |
bottleneck_input = tf.placeholder_with_default( | |
bottleneck_tensor, | |
shape=[None, bottleneck_tensor_size], | |
name='BottleneckInputPlaceholder') | |
ground_truth_input = tf.placeholder(tf.float32, | |
[None, class_count], | |
name='GroundTruthInput') | |
# Organizing the following ops as `final_training_ops` so they're easier | |
# to see in TensorBoard | |
layer_name = 'final_training_ops' | |
with tf.name_scope(layer_name): | |
with tf.name_scope('weights'): | |
initial_value = tf.truncated_normal( | |
[bottleneck_tensor_size, class_count], stddev=0.001) | |
layer_weights = tf.Variable(initial_value, name='final_weights') | |
variable_summaries(layer_weights) | |
with tf.name_scope('biases'): | |
layer_biases = tf.Variable(tf.zeros([class_count]), name='final_biases') | |
variable_summaries(layer_biases) | |
with tf.name_scope('Wx_plus_b'): | |
logits = tf.matmul(bottleneck_input, layer_weights) + layer_biases | |
tf.summary.histogram('pre_activations', logits) | |
final_tensor = tf.nn.softmax(logits, name=final_tensor_name) | |
tf.summary.histogram('activations', final_tensor) | |
with tf.name_scope('cross_entropy'): | |
cross_entropy = tf.nn.softmax_cross_entropy_with_logits( | |
labels=ground_truth_input, logits=logits) | |
with tf.name_scope('total'): | |
cross_entropy_mean = tf.reduce_mean(cross_entropy) | |
tf.summary.scalar('cross_entropy', cross_entropy_mean) | |
with tf.name_scope('train'): | |
optimizer = tf.train.GradientDescentOptimizer(FLAGS.learning_rate) | |
train_step = optimizer.minimize(cross_entropy_mean) | |
return (train_step, cross_entropy_mean, bottleneck_input, ground_truth_input, | |
final_tensor) | |
def add_evaluation_step(result_tensor, ground_truth_tensor): | |
"""Inserts the operations we need to evaluate the accuracy of our results. | |
Args: | |
result_tensor: The new final node that produces results. | |
ground_truth_tensor: The node we feed ground truth data | |
into. | |
Returns: | |
Tuple of (evaluation step, prediction). | |
""" | |
with tf.name_scope('accuracy'): | |
with tf.name_scope('correct_prediction'): | |
prediction = tf.argmax(result_tensor, 1) | |
correct_prediction = tf.equal( | |
prediction, tf.argmax(ground_truth_tensor, 1)) | |
with tf.name_scope('accuracy'): | |
evaluation_step = tf.reduce_mean(tf.cast(correct_prediction, tf.float32)) | |
tf.summary.scalar('accuracy', evaluation_step) | |
return evaluation_step, prediction | |
def save_graph_to_file(sess, graph, graph_file_name): | |
output_graph_def = graph_util.convert_variables_to_constants( | |
sess, graph.as_graph_def(), [FLAGS.final_tensor_name]) | |
with gfile.FastGFile(graph_file_name, 'wb') as f: | |
f.write(output_graph_def.SerializeToString()) | |
return | |
def prepare_file_system(): | |
# Setup the directory we'll write summaries to for TensorBoard | |
if tf.gfile.Exists(FLAGS.summaries_dir): | |
tf.gfile.DeleteRecursively(FLAGS.summaries_dir) | |
tf.gfile.MakeDirs(FLAGS.summaries_dir) | |
if FLAGS.intermediate_store_frequency > 0: | |
ensure_dir_exists(FLAGS.intermediate_output_graphs_dir) | |
return | |
def create_model_info(architecture): | |
"""Given the name of a model architecture, returns information about it. | |
There are different base image recognition pretrained models that can be | |
retrained using transfer learning, and this function translates from the name | |
of a model to the attributes that are needed to download and train with it. | |
Args: | |
architecture: Name of a model architecture. | |
Returns: | |
Dictionary of information about the model, or None if the name isn't | |
recognized | |
Raises: | |
ValueError: If architecture name is unknown. | |
""" | |
architecture = architecture.lower() | |
if architecture == 'inception_v3': | |
# pylint: disable=line-too-long | |
data_url = 'http://download.tensorflow.org/models/image/imagenet/inception-2015-12-05.tgz' | |
# pylint: enable=line-too-long | |
bottleneck_tensor_name = 'pool_3/_reshape:0' | |
bottleneck_tensor_size = 2048 | |
input_width = 299 | |
input_height = 299 | |
input_depth = 3 | |
resized_input_tensor_name = 'Mul:0' | |
model_file_name = 'classify_image_graph_def.pb' | |
input_mean = 128 | |
input_std = 128 | |
elif architecture.startswith('mobilenet_'): | |
parts = architecture.split('_') | |
if len(parts) != 3 and len(parts) != 4: | |
tf.logging.error("Couldn't understand architecture name '%s'", | |
architecture) | |
return None | |
version_string = parts[1] | |
if (version_string != '1.0' and version_string != '0.75' and | |
version_string != '0.50' and version_string != '0.25'): | |
tf.logging.error( | |
""""The Mobilenet version should be '1.0', '0.75', '0.50', or '0.25', | |
but found '%s' for architecture '%s'""", | |
version_string, architecture) | |
return None | |
size_string = parts[2] | |
if (size_string != '224' and size_string != '192' and | |
size_string != '160' and size_string != '128'): | |
tf.logging.error( | |
"""The Mobilenet input size should be '224', '192', '160', or '128', | |
but found '%s' for architecture '%s'""", | |
size_string, architecture) | |
return None | |
if len(parts) == 3: | |
is_quantized = False | |
else: | |
if parts[3] != 'quantized': | |
tf.logging.error( | |
"Couldn't understand architecture suffix '%s' for '%s'", parts[3], | |
architecture) | |
return None | |
is_quantized = True | |
data_url = 'http://download.tensorflow.org/models/mobilenet_v1_' | |
data_url += version_string + '_' + size_string + '_frozen.tgz' | |
bottleneck_tensor_name = 'MobilenetV1/Predictions/Reshape:0' | |
bottleneck_tensor_size = 1001 | |
input_width = int(size_string) | |
input_height = int(size_string) | |
input_depth = 3 | |
resized_input_tensor_name = 'input:0' | |
if is_quantized: | |
model_base_name = 'quantized_graph.pb' | |
else: | |
model_base_name = 'frozen_graph.pb' | |
model_dir_name = 'mobilenet_v1_' + version_string + '_' + size_string | |
model_file_name = os.path.join(model_dir_name, model_base_name) | |
input_mean = 127.5 | |
input_std = 127.5 | |
else: | |
tf.logging.error("Couldn't understand architecture name '%s'", architecture) | |
raise ValueError('Unknown architecture', architecture) | |
return { | |
'data_url': data_url, | |
'bottleneck_tensor_name': bottleneck_tensor_name, | |
'bottleneck_tensor_size': bottleneck_tensor_size, | |
'input_width': input_width, | |
'input_height': input_height, | |
'input_depth': input_depth, | |
'resized_input_tensor_name': resized_input_tensor_name, | |
'model_file_name': model_file_name, | |
'input_mean': input_mean, | |
'input_std': input_std, | |
} | |
def add_jpeg_decoding(input_width, input_height, input_depth, input_mean, | |
input_std): | |
"""Adds operations that perform JPEG decoding and resizing to the graph.. | |
Args: | |
input_width: Desired width of the image fed into the recognizer graph. | |
input_height: Desired width of the image fed into the recognizer graph. | |
input_depth: Desired channels of the image fed into the recognizer graph. | |
input_mean: Pixel value that should be zero in the image for the graph. | |
input_std: How much to divide the pixel values by before recognition. | |
Returns: | |
Tensors for the node to feed JPEG data into, and the output of the | |
preprocessing steps. | |
""" | |
jpeg_data = tf.placeholder(tf.string, name='DecodeJPGInput') | |
decoded_image = tf.image.decode_jpeg(jpeg_data, channels=input_depth) | |
decoded_image_as_float = tf.cast(decoded_image, dtype=tf.float32) | |
decoded_image_4d = tf.expand_dims(decoded_image_as_float, 0) | |
resize_shape = tf.stack([input_height, input_width]) | |
resize_shape_as_int = tf.cast(resize_shape, dtype=tf.int32) | |
resized_image = tf.image.resize_bilinear(decoded_image_4d, | |
resize_shape_as_int) | |
offset_image = tf.subtract(resized_image, input_mean) | |
mul_image = tf.multiply(offset_image, 1.0 / input_std) | |
return jpeg_data, mul_image | |
def main(_): | |
# Needed to make sure the logging output is visible. | |
# See https://github.com/tensorflow/tensorflow/issues/3047 | |
tf.logging.set_verbosity(tf.logging.INFO) | |
# Prepare necessary directories that can be used during training | |
prepare_file_system() | |
# Gather information about the model architecture we'll be using. | |
model_info = create_model_info(FLAGS.architecture) | |
if not model_info: | |
tf.logging.error('Did not recognize architecture flag') | |
return -1 | |
# Set up the pre-trained graph. | |
maybe_download_and_extract(model_info['data_url']) | |
graph, bottleneck_tensor, resized_image_tensor = ( | |
create_model_graph(model_info)) | |
# Look at the folder structure, and create lists of all the images. | |
image_lists = create_image_lists(FLAGS.image_dir, FLAGS.testing_percentage, | |
FLAGS.validation_percentage) | |
class_count = len(image_lists.keys()) | |
if class_count == 0: | |
tf.logging.error('No valid folders of images found at ' + FLAGS.image_dir) | |
return -1 | |
if class_count == 1: | |
tf.logging.error('Only one valid folder of images found at ' + | |
FLAGS.image_dir + | |
' - multiple classes are needed for classification.') | |
return -1 | |
# See if the command-line flags mean we're applying any distortions. | |
do_distort_images = should_distort_images( | |
FLAGS.flip_left_right, FLAGS.random_crop, FLAGS.random_scale, | |
FLAGS.random_brightness) | |
with tf.Session(graph=graph) as sess: | |
# Set up the image decoding sub-graph. | |
jpeg_data_tensor, decoded_image_tensor = add_jpeg_decoding( | |
model_info['input_width'], model_info['input_height'], | |
model_info['input_depth'], model_info['input_mean'], | |
model_info['input_std']) | |
if do_distort_images: | |
# We will be applying distortions, so setup the operations we'll need. | |
(distorted_jpeg_data_tensor, | |
distorted_image_tensor) = add_input_distortions( | |
FLAGS.flip_left_right, FLAGS.random_crop, FLAGS.random_scale, | |
FLAGS.random_brightness, model_info['input_width'], | |
model_info['input_height'], model_info['input_depth'], | |
model_info['input_mean'], model_info['input_std']) | |
else: | |
# We'll make sure we've calculated the 'bottleneck' image summaries and | |
# cached them on disk. | |
cache_bottlenecks(sess, image_lists, FLAGS.image_dir, | |
FLAGS.bottleneck_dir, jpeg_data_tensor, | |
decoded_image_tensor, resized_image_tensor, | |
bottleneck_tensor, FLAGS.architecture) | |
# Add the new layer that we'll be training. | |
(train_step, cross_entropy, bottleneck_input, ground_truth_input, | |
final_tensor) = add_final_training_ops( | |
len(image_lists.keys()), FLAGS.final_tensor_name, bottleneck_tensor, | |
model_info['bottleneck_tensor_size']) | |
# Create the operations we need to evaluate the accuracy of our new layer. | |
evaluation_step, prediction = add_evaluation_step( | |
final_tensor, ground_truth_input) | |
# Merge all the summaries and write them out to the summaries_dir | |
merged = tf.summary.merge_all() | |
train_writer = tf.summary.FileWriter(FLAGS.summaries_dir + '/train', | |
sess.graph) | |
validation_writer = tf.summary.FileWriter( | |
FLAGS.summaries_dir + '/validation') | |
# Set up all our weights to their initial default values. | |
init = tf.global_variables_initializer() | |
sess.run(init) | |
# Run the training for as many cycles as requested on the command line. | |
for i in range(FLAGS.how_many_training_steps): | |
# Get a batch of input bottleneck values, either calculated fresh every | |
# time with distortions applied, or from the cache stored on disk. | |
if do_distort_images: | |
(train_bottlenecks, | |
train_ground_truth) = get_random_distorted_bottlenecks( | |
sess, image_lists, FLAGS.train_batch_size, 'training', | |
FLAGS.image_dir, distorted_jpeg_data_tensor, | |
distorted_image_tensor, resized_image_tensor, bottleneck_tensor) | |
else: | |
(train_bottlenecks, | |
train_ground_truth, _) = get_random_cached_bottlenecks( | |
sess, image_lists, FLAGS.train_batch_size, 'training', | |
FLAGS.bottleneck_dir, FLAGS.image_dir, jpeg_data_tensor, | |
decoded_image_tensor, resized_image_tensor, bottleneck_tensor, | |
FLAGS.architecture) | |
# Feed the bottlenecks and ground truth into the graph, and run a training | |
# step. Capture training summaries for TensorBoard with the `merged` op. | |
train_summary, _ = sess.run( | |
[merged, train_step], | |
feed_dict={bottleneck_input: train_bottlenecks, | |
ground_truth_input: train_ground_truth}) | |
train_writer.add_summary(train_summary, i) | |
# Every so often, print out how well the graph is training. | |
is_last_step = (i + 1 == FLAGS.how_many_training_steps) | |
if (i % FLAGS.eval_step_interval) == 0 or is_last_step: | |
train_accuracy, cross_entropy_value = sess.run( | |
[evaluation_step, cross_entropy], | |
feed_dict={bottleneck_input: train_bottlenecks, | |
ground_truth_input: train_ground_truth}) | |
tf.logging.info('%s: Step %d: Train accuracy = %.1f%%' % | |
(datetime.now(), i, train_accuracy * 100)) | |
tf.logging.info('%s: Step %d: Cross entropy = %f' % | |
(datetime.now(), i, cross_entropy_value)) | |
validation_bottlenecks, validation_ground_truth, _ = ( | |
get_random_cached_bottlenecks( | |
sess, image_lists, FLAGS.validation_batch_size, 'validation', | |
FLAGS.bottleneck_dir, FLAGS.image_dir, jpeg_data_tensor, | |
decoded_image_tensor, resized_image_tensor, bottleneck_tensor, | |
FLAGS.architecture)) | |
# Run a validation step and capture training summaries for TensorBoard | |
# with the `merged` op. | |
validation_summary, validation_accuracy = sess.run( | |
[merged, evaluation_step], | |
feed_dict={bottleneck_input: validation_bottlenecks, | |
ground_truth_input: validation_ground_truth}) | |
validation_writer.add_summary(validation_summary, i) | |
tf.logging.info('%s: Step %d: Validation accuracy = %.1f%% (N=%d)' % | |
(datetime.now(), i, validation_accuracy * 100, | |
len(validation_bottlenecks))) | |
# Store intermediate results | |
intermediate_frequency = FLAGS.intermediate_store_frequency | |
if (intermediate_frequency > 0 and (i % intermediate_frequency == 0) | |
and i > 0): | |
intermediate_file_name = (FLAGS.intermediate_output_graphs_dir + | |
'intermediate_' + str(i) + '.pb') | |
tf.logging.info('Save intermediate result to : ' + | |
intermediate_file_name) | |
save_graph_to_file(sess, graph, intermediate_file_name) | |
# We've completed all our training, so run a final test evaluation on | |
# some new images we haven't used before. | |
test_bottlenecks, test_ground_truth, test_filenames = ( | |
get_random_cached_bottlenecks( | |
sess, image_lists, FLAGS.test_batch_size, 'testing', | |
FLAGS.bottleneck_dir, FLAGS.image_dir, jpeg_data_tensor, | |
decoded_image_tensor, resized_image_tensor, bottleneck_tensor, | |
FLAGS.architecture)) | |
test_accuracy, predictions = sess.run( | |
[evaluation_step, prediction], | |
feed_dict={bottleneck_input: test_bottlenecks, | |
ground_truth_input: test_ground_truth}) | |
tf.logging.info('Final test accuracy = %.1f%% (N=%d)' % | |
(test_accuracy * 100, len(test_bottlenecks))) | |
if FLAGS.print_misclassified_test_images: | |
tf.logging.info('=== MISCLASSIFIED TEST IMAGES ===') | |
for i, test_filename in enumerate(test_filenames): | |
if predictions[i] != test_ground_truth[i].argmax(): | |
tf.logging.info('%70s %s' % | |
(test_filename, | |
list(image_lists.keys())[predictions[i]])) | |
# Write out the trained graph and labels with the weights stored as | |
# constants. | |
save_graph_to_file(sess, graph, FLAGS.output_graph) | |
with gfile.FastGFile(FLAGS.output_labels, 'w') as f: | |
f.write('\n'.join(image_lists.keys()) + '\n') | |
if __name__ == '__main__': | |
parser = argparse.ArgumentParser() | |
parser.add_argument( | |
'--image_dir', | |
type=str, | |
default='', | |
help='Path to folders of labeled images.' | |
) | |
parser.add_argument( | |
'--output_graph', | |
type=str, | |
default='/tmp/output_graph.pb', | |
help='Where to save the trained graph.' | |
) | |
parser.add_argument( | |
'--intermediate_output_graphs_dir', | |
type=str, | |
default='/tmp/intermediate_graph/', | |
help='Where to save the intermediate graphs.' | |
) | |
parser.add_argument( | |
'--intermediate_store_frequency', | |
type=int, | |
default=0, | |
help="""\ | |
How many steps to store intermediate graph. If "0" then will not | |
store.\ | |
""" | |
) | |
parser.add_argument( | |
'--output_labels', | |
type=str, | |
default='/tmp/output_labels.txt', | |
help='Where to save the trained graph\'s labels.' | |
) | |
parser.add_argument( | |
'--summaries_dir', | |
type=str, | |
default='/tmp/retrain_logs', | |
help='Where to save summary logs for TensorBoard.' | |
) | |
parser.add_argument( | |
'--how_many_training_steps', | |
type=int, | |
default=4000, | |
help='How many training steps to run before ending.' | |
) | |
parser.add_argument( | |
'--learning_rate', | |
type=float, | |
default=0.01, | |
help='How large a learning rate to use when training.' | |
) | |
parser.add_argument( | |
'--testing_percentage', | |
type=int, | |
default=10, | |
help='What percentage of images to use as a test set.' | |
) | |
parser.add_argument( | |
'--validation_percentage', | |
type=int, | |
default=10, | |
help='What percentage of images to use as a validation set.' | |
) | |
parser.add_argument( | |
'--eval_step_interval', | |
type=int, | |
default=10, | |
help='How often to evaluate the training results.' | |
) | |
parser.add_argument( | |
'--train_batch_size', | |
type=int, | |
default=100, | |
help='How many images to train on at a time.' | |
) | |
parser.add_argument( | |
'--test_batch_size', | |
type=int, | |
default=-1, | |
help="""\ | |
How many images to test on. This test set is only used once, to evaluate | |
the final accuracy of the model after training completes. | |
A value of -1 causes the entire test set to be used, which leads to more | |
stable results across runs.\ | |
""" | |
) | |
parser.add_argument( | |
'--validation_batch_size', | |
type=int, | |
default=100, | |
help="""\ | |
How many images to use in an evaluation batch. This validation set is | |
used much more often than the test set, and is an early indicator of how | |
accurate the model is during training. | |
A value of -1 causes the entire validation set to be used, which leads to | |
more stable results across training iterations, but may be slower on large | |
training sets.\ | |
""" | |
) | |
parser.add_argument( | |
'--print_misclassified_test_images', | |
default=False, | |
help="""\ | |
Whether to print out a list of all misclassified test images.\ | |
""", | |
action='store_true' | |
) | |
parser.add_argument( | |
'--model_dir', | |
type=str, | |
default='/tmp/imagenet', | |
help="""\ | |
Path to classify_image_graph_def.pb, | |
imagenet_synset_to_human_label_map.txt, and | |
imagenet_2012_challenge_label_map_proto.pbtxt.\ | |
""" | |
) | |
parser.add_argument( | |
'--bottleneck_dir', | |
type=str, | |
default='/tmp/bottleneck', | |
help='Path to cache bottleneck layer values as files.' | |
) | |
parser.add_argument( | |
'--final_tensor_name', | |
type=str, | |
default='final_result', | |
help="""\ | |
The name of the output classification layer in the retrained graph.\ | |
""" | |
) | |
parser.add_argument( | |
'--flip_left_right', | |
default=False, | |
help="""\ | |
Whether to randomly flip half of the training images horizontally.\ | |
""", | |
action='store_true' | |
) | |
parser.add_argument( | |
'--random_crop', | |
type=int, | |
default=0, | |
help="""\ | |
A percentage determining how much of a margin to randomly crop off the | |
training images.\ | |
""" | |
) | |
parser.add_argument( | |
'--random_scale', | |
type=int, | |
default=0, | |
help="""\ | |
A percentage determining how much to randomly scale up the size of the | |
training images by.\ | |
""" | |
) | |
parser.add_argument( | |
'--random_brightness', | |
type=int, | |
default=0, | |
help="""\ | |
A percentage determining how much to randomly multiply the training image | |
input pixels up or down by.\ | |
""" | |
) | |
parser.add_argument( | |
'--architecture', | |
type=str, | |
default='inception_v3', | |
help="""\ | |
Which model architecture to use. 'inception_v3' is the most accurate, but | |
also the slowest. For faster or smaller models, chose a MobileNet with the | |
form 'mobilenet_<parameter size>_<input_size>[_quantized]'. For example, | |
'mobilenet_1.0_224' will pick a model that is 17 MB in size and takes 224 | |
pixel input images, while 'mobilenet_0.25_128_quantized' will choose a much | |
less accurate, but smaller and faster network that's 920 KB on disk and | |
takes 128x128 images. See https://research.googleblog.com/2017/06/mobilenets-open-source-models-for.html | |
for more information on Mobilenet.\ | |
""") | |
FLAGS, unparsed = parser.parse_known_args() | |
tf.app.run(main=main, argv=[sys.argv[0]] + unparsed) | |
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