# Copyright 2017 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"""Convert the Oxford pet dataset to TFRecord for object_detection. See: O. M. Parkhi, A. Vedaldi, A. Zisserman, C. V. Jawahar Cats and Dogs IEEE Conference on Computer Vision and Pattern Recognition, 2012 http://www.robots.ox.ac.uk/~vgg/data/pets/ Example usage: python object_detection/dataset_tools/create_pet_tf_record.py \ --data_dir=/home/user/pet \ --output_dir=/home/user/pet/output """ import hashlib import io import logging import os import random import re import contextlib2 from lxml import etree import numpy as np import PIL.Image import tensorflow as tf from object_detection.dataset_tools import tf_record_creation_util from object_detection.utils import dataset_util from object_detection.utils import label_map_util flags = tf.app.flags flags.DEFINE_string('data_dir', '', 'Root directory to raw pet dataset.') flags.DEFINE_string('output_dir', '', 'Path to directory to output TFRecords.') flags.DEFINE_string('label_map_path', 'data/pet_label_map.pbtxt', 'Path to label map proto') flags.DEFINE_boolean('faces_only', True, 'If True, generates bounding boxes ' 'for pet faces. Otherwise generates bounding boxes (as ' 'well as segmentations for full pet bodies). Note that ' 'in the latter case, the resulting files are much larger.') flags.DEFINE_string('mask_type', 'png', 'How to represent instance ' 'segmentation masks. Options are "png" or "numerical".') flags.DEFINE_integer('num_shards', 10, 'Number of TFRecord shards') FLAGS = flags.FLAGS def get_class_name_from_filename(file_name): """Gets the class name from a file. Args: file_name: The file name to get the class name from. ie. "american_pit_bull_terrier_105.jpg" Returns: A string of the class name. """ match = re.match(r'([A-Za-z_]+)(_[0-9]+\.jpg)', file_name, re.I) return match.groups()[0] def dict_to_tf_example(data, mask_path, label_map_dict, image_subdirectory, ignore_difficult_instances=False, faces_only=True, mask_type='png'): """Convert XML derived dict to tf.Example proto. Notice that this function normalizes the bounding box coordinates provided by the raw data. Args: data: dict holding PASCAL XML fields for a single image (obtained by running dataset_util.recursive_parse_xml_to_dict) mask_path: String path to PNG encoded mask. label_map_dict: A map from string label names to integers ids. image_subdirectory: String specifying subdirectory within the Pascal dataset directory holding the actual image data. ignore_difficult_instances: Whether to skip difficult instances in the dataset (default: False). faces_only: If True, generates bounding boxes for pet faces. Otherwise generates bounding boxes (as well as segmentations for full pet bodies). mask_type: 'numerical' or 'png'. 'png' is recommended because it leads to smaller file sizes. Returns: example: The converted tf.Example. Raises: ValueError: if the image pointed to by data['filename'] is not a valid JPEG """ img_path = os.path.join(image_subdirectory, data['filename']) with tf.gfile.GFile(img_path, 'rb') as fid: encoded_jpg = fid.read() encoded_jpg_io = io.BytesIO(encoded_jpg) image = PIL.Image.open(encoded_jpg_io) if image.format != 'JPEG': raise ValueError('Image format not JPEG') key = hashlib.sha256(encoded_jpg).hexdigest() with tf.gfile.GFile(mask_path, 'rb') as fid: encoded_mask_png = fid.read() encoded_png_io = io.BytesIO(encoded_mask_png) mask = PIL.Image.open(encoded_png_io) if mask.format != 'PNG': raise ValueError('Mask format not PNG') mask_np = np.asarray(mask) nonbackground_indices_x = np.any(mask_np != 2, axis=0) nonbackground_indices_y = np.any(mask_np != 2, axis=1) nonzero_x_indices = np.where(nonbackground_indices_x) nonzero_y_indices = np.where(nonbackground_indices_y) width = int(data['size']['width']) height = int(data['size']['height']) xmins = [] ymins = [] xmaxs = [] ymaxs = [] classes = [] classes_text = [] truncated = [] poses = [] difficult_obj = [] masks = [] if 'object' in data: for obj in data['object']: difficult = bool(int(obj['difficult'])) if ignore_difficult_instances and difficult: continue difficult_obj.append(int(difficult)) if faces_only: xmin = float(obj['bndbox']['xmin']) xmax = float(obj['bndbox']['xmax']) ymin = float(obj['bndbox']['ymin']) ymax = float(obj['bndbox']['ymax']) else: xmin = float(np.min(nonzero_x_indices)) xmax = float(np.max(nonzero_x_indices)) ymin = float(np.min(nonzero_y_indices)) ymax = float(np.max(nonzero_y_indices)) xmins.append(xmin / width) ymins.append(ymin / height) xmaxs.append(xmax / width) ymaxs.append(ymax / height) class_name = get_class_name_from_filename(data['filename']) classes_text.append(class_name.encode('utf8')) classes.append(label_map_dict[class_name]) truncated.append(int(obj['truncated'])) poses.append(obj['pose'].encode('utf8')) if not faces_only: mask_remapped = (mask_np != 2).astype(np.uint8) masks.append(mask_remapped) feature_dict = { 'image/height': dataset_util.int64_feature(height), 'image/width': dataset_util.int64_feature(width), 'image/filename': dataset_util.bytes_feature( data['filename'].encode('utf8')), 'image/source_id': dataset_util.bytes_feature( data['filename'].encode('utf8')), 'image/key/sha256': dataset_util.bytes_feature(key.encode('utf8')), 'image/encoded': dataset_util.bytes_feature(encoded_jpg), 'image/format': dataset_util.bytes_feature('jpeg'.encode('utf8')), 'image/object/bbox/xmin': dataset_util.float_list_feature(xmins), 'image/object/bbox/xmax': dataset_util.float_list_feature(xmaxs), 'image/object/bbox/ymin': dataset_util.float_list_feature(ymins), 'image/object/bbox/ymax': dataset_util.float_list_feature(ymaxs), 'image/object/class/text': dataset_util.bytes_list_feature(classes_text), 'image/object/class/label': dataset_util.int64_list_feature(classes), 'image/object/difficult': dataset_util.int64_list_feature(difficult_obj), 'image/object/truncated': dataset_util.int64_list_feature(truncated), 'image/object/view': dataset_util.bytes_list_feature(poses), } if not faces_only: if mask_type == 'numerical': mask_stack = np.stack(masks).astype(np.float32) masks_flattened = np.reshape(mask_stack, [-1]) feature_dict['image/object/mask'] = ( dataset_util.float_list_feature(masks_flattened.tolist())) elif mask_type == 'png': encoded_mask_png_list = [] for mask in masks: img = PIL.Image.fromarray(mask) output = io.BytesIO() img.save(output, format='PNG') encoded_mask_png_list.append(output.getvalue()) feature_dict['image/object/mask'] = ( dataset_util.bytes_list_feature(encoded_mask_png_list)) example = tf.train.Example(features=tf.train.Features(feature=feature_dict)) return example def create_tf_record(output_filename, num_shards, label_map_dict, annotations_dir, image_dir, examples, faces_only=True, mask_type='png'): """Creates a TFRecord file from examples. Args: output_filename: Path to where output file is saved. num_shards: Number of shards for output file. label_map_dict: The label map dictionary. annotations_dir: Directory where annotation files are stored. image_dir: Directory where image files are stored. examples: Examples to parse and save to tf record. faces_only: If True, generates bounding boxes for pet faces. Otherwise generates bounding boxes (as well as segmentations for full pet bodies). mask_type: 'numerical' or 'png'. 'png' is recommended because it leads to smaller file sizes. """ with contextlib2.ExitStack() as tf_record_close_stack: output_tfrecords = tf_record_creation_util.open_sharded_output_tfrecords( tf_record_close_stack, output_filename, num_shards) for idx, example in enumerate(examples): if idx % 100 == 0: logging.info('On image %d of %d', idx, len(examples)) xml_path = os.path.join(annotations_dir, 'xmls', example + '.xml') mask_path = os.path.join(annotations_dir, 'trimaps', example + '.png') if not os.path.exists(xml_path): logging.warning('Could not find %s, ignoring example.', xml_path) continue with tf.gfile.GFile(xml_path, 'r') as fid: xml_str = fid.read() xml = etree.fromstring(xml_str) data = dataset_util.recursive_parse_xml_to_dict(xml)['annotation'] try: tf_example = dict_to_tf_example( data, mask_path, label_map_dict, image_dir, faces_only=faces_only, mask_type=mask_type) if tf_example: shard_idx = idx % num_shards output_tfrecords[shard_idx].write(tf_example.SerializeToString()) except ValueError: logging.warning('Invalid example: %s, ignoring.', xml_path) # TODO(derekjchow): Add test for pet/PASCAL main files. def main(_): data_dir = FLAGS.data_dir label_map_dict = label_map_util.get_label_map_dict(FLAGS.label_map_path) logging.info('Reading from Pet dataset.') image_dir = os.path.join(data_dir, 'images') annotations_dir = os.path.join(data_dir, 'annotations') examples_path = os.path.join(annotations_dir, 'trainval.txt') examples_list = dataset_util.read_examples_list(examples_path) # Test images are not included in the downloaded data set, so we shall perform # our own split. random.seed(42) random.shuffle(examples_list) num_examples = len(examples_list) num_train = int(0.7 * num_examples) train_examples = examples_list[:num_train] val_examples = examples_list[num_train:] logging.info('%d training and %d validation examples.', len(train_examples), len(val_examples)) train_output_path = os.path.join(FLAGS.output_dir, 'pet_faces_train.record') val_output_path = os.path.join(FLAGS.output_dir, 'pet_faces_val.record') if not FLAGS.faces_only: train_output_path = os.path.join(FLAGS.output_dir, 'pets_fullbody_with_masks_train.record') val_output_path = os.path.join(FLAGS.output_dir, 'pets_fullbody_with_masks_val.record') create_tf_record( train_output_path, FLAGS.num_shards, label_map_dict, annotations_dir, image_dir, train_examples, faces_only=FLAGS.faces_only, mask_type=FLAGS.mask_type) create_tf_record( val_output_path, FLAGS.num_shards, label_map_dict, annotations_dir, image_dir, val_examples, faces_only=FLAGS.faces_only, mask_type=FLAGS.mask_type) if __name__ == '__main__': tf.app.run()