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Input Pipeline Optimisation for TFRecords

Assignment-15

TFRecords introduce lazy loading (on demand) loading of the data from dataset. While variety of data can be loaded as TFRecords, the commonest form is the data loaded as .tfrecords format.

The text loading operations can be considered roughly the following operations:

  1. Extract
  2. Transform
  3. Load

Extract

Extract operation typically, encompasses reading from the file system to segregating data as classified columns. In this case, we will read the data as image and class to which the image belongs to.

Normal Loading of TFRecords

The following code is used to load the dataset from a collection of file paths in the .tfrecords format.

	dataset = tf.data.TFRecordDataset(path)

Interleaved Parallel Loading

Here, multiple files are interleaved and can be parallel read by multiple threads. However, the gains may not be substantial for local disk reads and multi-head reads may not be optimised for all the local disks. The effect is much pronounced in SAN or network reads.

    files = tf.data.Dataset.list_files(path)
    dataset = files.interleave(tf.data.TFRecordDataset,    									                           cycle_length=nfile, 
					           num_parallel_calls=tf.data.experimental.AUTOTUNE)

Record Extraction

Data is stored as Examples which are essentially records to be loaded for inference. The records can be extracted individually or can be extracted in batches as well. Batch extraction introduces potential to vectorize the code and thus pass the computation to multiple parallel threads for execution.

As can be seen below the tf.parse_example method is used instead of tf.parse_single_example which expects the example data is presented as a batch.

def parse_fn(example):
    example_fmt = {
        'image': tf.io.FixedLenFeature((), tf.string, ""),
        'label': tf.io.FixedLenFeature((), tf.int64, -1)
    }
    parsed = tf.parse_example(example, example_fmt)
    images = tf.map_fn(tf.io.decode_image, parsed['image'], dtype=tf.uint8)
    images = tf.reshape(images, [-1, 32, 32, 3])
    return (images, parsed['label'])

Transform

In the previous step data is presented as basic levels of details with the image extracted and presented. However, image augmentation and normalisation are not carried out. The same is carried out as part of transformation steps at the CPU and machine RAM.

The dataset.map method is responsible for all the transformation activities. While, the transform function is used to manipulate the image, no transformation is applied on category membership part.

    func = lambda x: (tf.map_fn(transform, x[0], dtype=tf.float32), x[1])    
    dataset = dataset.map(map_func=lambda a: func(parse_fn(a)), 
                          num_parallel_calls=tf.data.experimental.AUTOTUNE)

Image Manipulation Operations

The TFRecord requires these methods are always executed in the Graph mode even if the code provided is simple Python code that can be run in the eager execution mode. Hence, the code shown below all are written in TensorFlow functions with Tensors as input and output.

Training

The following image augmentation methods are carried out on the image. As the methods applied are on individual images tf.map_fn is used to vectorize the code as shown above.

normalize = lambda x: (tf.cast(x, tf.float32) - train_mean) / train_std
random_crop = lambda x,n: tf.random_crop(x, [n, n, 3])
random_flip_left_right = lambda x: tf.image.random_flip_left_right(x)
pad = lambda x, n: tf.pad(x, [[n, n], [n, n], [0, 0]], mode='reflect')
random_rotate = lambda x, n: tf.contrib.image.rotate(x, (np.random.rand()-0.5)*math.pi/180*n)
def cutout(x, si, sj):
    ci = tf.random.uniform((1,), 0, x.shape[0] - si - 1, dtype=tf.int32)[0]
    cj = tf.random.uniform((1,), 0, x.shape[1] - sj - 1, dtype=tf.int32)[0]
    idx = [tf.range(ci, si), tf.range(cj, sj)]
    val = tf.zeros((si, sj, 3))
    tf.tensor_scatter_update(x, idx, val)
    return x
image_augment = lambda x: cutout(normalize(random_rotate(random_crop(random_flip_left_right(pad(x, 4)), 32), 10)), 8, 8)

train_tfr = make_dataset(train_fn, image_augment, 10)

Test

Only image normalisation is carried out for the test data.

test_tfr = make_dataset(test_fn, normalize, 1)

Load

The load part of the pipeline is the exchange of data between memory and GPU during model training and execution. The input pipeline operation does not significantly affect those. However, the load strategy can be programmed in the TFRecord. The commands like batch, repeat, ___iter___ which is used as part of actual iteration designs the loading operation.

Profiling

Profile data can be collected as part of the code by instantiating a Profile object in the eager execution mode.

from tensorflow.python.eager.profiler import Profiler
with Profiler('logs'):
    # The training code goes here

The profile data can be viewed using Tensorboard using the command as shown below:

$ tensorboard --logdir logs/ --port 6009

And can be viewed in the browser by loading the URL: http://localhost:6009

Memory Footprint Caveat

Profiling operations can be highly memory intensive and can take up to 23GB of memory as the profiler tends to write to disk at the end of the training operations, due to usage of the profile object. Intermittent writes can reduce this footprint drastically. Colab timeouts can be common in such cases. top outputs are shown below.

No Profile

With Profile

Results

While accuracy remained almost the same around 92 to 93%, the training time with and without pipeline were 1046s vs 709s. This kind of makes it imperative to observe and analyse the variations that are described below.

No Pipeline

As can be seen in the below image below, the CPU and GPU are waiting on data between each epoch. An operation called IteratorGetNextSynctake about 25s. Hence, both CPU and GPU threads for compuation are starved for data.

As shown below the IteratorGetNextSync.

Reading of data from disk:

Distinct read blocks for test as well as training sets.

With Pipeline

The IteratorGetNextSync is just 0.2s down from 25s. As it can be seen, the data is uniformly read from the files. However, the performance gains are only 1-2s per epoch as the data is available all on the disc. The GPU is more evenly loaded. However, the load cycles can be improved. On zooming the data one can observe massive gaps between operations showing ideal CPU and GPU.

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