在使用slim之类的tensorflow自带框架的时候一般默认的数据格式就是TFRecords,在训练的时候使用TFRecords中数据的流程如下:使用input pipeline读取tfrecords文件/其他支持的格式,然后随机乱序,生成文件序列,读取并解码数据,输入模型训练。
如果有一串jpg图片地址和相应的标签:images和labels
1. 生成TFrecords
存入TFRecords文件需要数据先存入名为example的protocol buffer,然后将其serialize成为string才能写入。example中包含features,用于描述数据类型:bytes,float,int64。
import tensorflow as tf
import cv2
def _int64_feature(value):
return tf.train.Feature(int64_list=tf.train.Int64List(value=[value]))
def _bytes_feature(value):
return tf.train.Feature(bytes_list=tf.train.BytesList(value=value))
train_filename = 'train.tfrecords'
with tf.python_io.TFRecordWriter(train_filename) as tfrecord_writer:
for i in range(len(images)):
# read in image data by tf
img_data = tf.gfile.FastGFile(images[i], 'rb').read() # image data type is string
label = labels[i]
# get width and height of image
image_shape = cv2.imread(images[i]).shape
width = image_shape[1]
height = image_shape[0]
# create features
feature = {'train/image': _bytes_feature(img_data),
'train/label': _int64_feature(label), # label: integer from 0-N
'train/height': _int64_feature(height),
'train/width': _int64_feature(width)}
# create example protocol buffer
example = tf.train.Example(features=tf.train.Features(feature=feature))
# serialize protocol buffer to string
tfrecord_writer.write(example.SerializeToString())
tfrecord_writer.close()2. 读取TFRecords文件
首先用tf.train.string_input_producer读取tfrecords文件的list建立FIFO序列,可以申明num_epoches和shuffle参数表示需要读取数据的次数以及时候将tfrecords文件读入顺序打乱,然后定义TFRecordReader读取上面的序列返回下一个record,用tf.parse_single_example对读取到TFRecords文件进行解码,根据保存的serialize example和feature字典返回feature所对应的值。此时获得的值都是string,需要进一步解码为所需的数据类型。把图像数据的string reshape成原始图像后可以进行preprocessing操作。此外,还可以通过tf.train.batch或者tf.train.shuffle_batch将图像生成batch序列。
由于tf.train函数会在graph中增加tf.train.QueueRunner类,而这些类有一系列的enqueue选项使一个队列在一个线程里运行。为了填充队列就需要用tf.train.start_queue_runners来为所有graph中的queue runner启动线程,而为了管理这些线程就需要一个tf.train.Coordinator来在合适的时候终止这些线程。
import tensorflow as tf
import matplotlib.pyplot as plt
data_path = 'train.tfrecords'
with tf.Session() as sess:
# feature key and its data type for data restored in tfrecords file
feature = {'train/image': tf.FixedLenFeature([], tf.string),
'train/label': tf.FixedLenFeature([], tf.int64),
'train/height': tf.FixedLenFeature([], tf.int64),
'train/width': tf.FixedLenFeature([], tf.int64)}
# define a queue base on input filenames
filename_queue = tf.train.string_input_producer([data_path], num_epoches=1)
# define a tfrecords file reader
reader = tf.TFRecordReader()
# read in serialized example data
_, serialized_example = reader.read(filename_queue)
# decode example by feature
features = tf.parse_single_example(serialized_example, features=feature)
image = tf.image.decode_jpeg(features['train/image'])
image = tf.image.convert_image_dtype(image, dtype=tf.float32) # convert dtype from unit8 to float32 for later resize
label = tf.cast(features['train/label'], tf.int64)
height = tf.cast(features['train/height'], tf.int32)
width = tf.cast(features['train/width'], tf.int32)
# restore image to [height, width, 3]
image = tf.reshape(image, [height, width, 3])
# resize
image = tf.image.resize_images(image, [224, 224])
# create bathch
images, labels = tf.train.shuffle_batch([image, label], batch_size=10, capacity=30, num_threads=1, min_after_dequeue=10) # capacity是队列的最大容量,num_threads是dequeue后最小的队列大小,num_threads是进行队列操作的线程数。
# initialize global & local variables
init_op = tf.group(tf.global_variables_initializer(), tf.local_variables_initializer())
sess.run(init_op)
# create a coordinate and run queue runner objects
coord = tf.train.Coordinator()
threads = tf.train.start_queue_runners(coord=coord)
for batch_index in range(3):
batch_images, batch_labels = sess.run([images, labels])
for i in range(10):
plt.imshow(batch_images[i, ...])
plt.show()
print "Current image label is: ", batch_lables[i]
# close threads
coord.request_stop()
coord.join(threads)
sess.close()