I'm using tensorflow with Titan-X GPUs and I've noticed that, when I run the CIFAR10 example, the Volatile GPU-utilization is pretty constant around 30%, whereas when I train my own model, the Volatile GPU-utilization is far from steady, it is almost always 0% and spikes at 80/90% before going back to 0%, over and over again.

I thought that this behavior was due to the way I was feeding the data to the network (I was fetching the data after each step, which took some time). But after implementing a queue to feed the data and avoid this latency between steps, the problem persisted (see below for the queuing system).

Any idea?

batch = 128 # size of the batch
x = tf.placeholder("float32", [None, n_steps, n_input])
y = tf.placeholder("float32", [None, n_classes])

# with a capacity of 100 batches, the bottleneck should not be the data feeding
queue = tf.RandomShuffleQueue(capacity=100*batch,
                  dtypes=[tf.float32, tf.float32],
                  shapes=[[n_steps, n_input], [n_classes]])
enqueue_op = queue.enqueue_many([x, y])
X_batch, Y_batch = queue.dequeue_many(batch)

sess = tf.Session()

def load_and_enqueue(data):
    while True:
        X, Y = data.get_next_batch(batch)
        sess.run(enqueue_op, feed_dict={x: X, y: Y})

train_thread = threading.Thread(target=load_and_enqueue, args=(data))
train_thread.daemon = True

for _ in xrange(max_iter):
  • How long does data.get_next_batch relative to other operations? It seems to be the only only running on CPU, and it may be slowing down the pipeline. Jul 12 '16 at 10:41
  • For a batch of size 128 get_next_batch takes approximately 14x more time than sess.run(train_op) to run. However, before beginning the training, I feed the queue with 100 * batch examples, so at least in the beginning I should have some good GPU utilization, no?
    – BiBi
    Jul 13 '16 at 15:50
  • If the training is an order of magnitude faster than the feeding, it is possible that the dequeuing operation is waiting most of the time, meaning the GPU-run part (train_op) waits for the CPU-run thread (for load_and_enqueue). I am not clear yet what the interplay with the min_after_dequeue, though. How about running all on CPU (i.e. no thread), and see if the usage is smoother? Jul 13 '16 at 21:24
  • So the problem seems understood now. A solution is probably to pre-process the data, so that feeding is as fast or faster than training. Note that complex models can be way slower... Jul 14 '16 at 12:58
  • Yes it is, thank you. I deleted my comments and will post a proper answer to my question. Thanks again for helping me figure it out.
    – BiBi
    Jul 14 '16 at 12:59

After doing some experiments, I found the answer so I post it since it could be useful to someone else.

First, get_next_batch is approximately 15x slower than train_op (thanks to Eric Platon for pointing this out).

However, I thought that the queue was being fed up to capacity and that only after the training was supposed to begin. Hence, I thought that even if get_next_batch was way slower, the queue should hide this latency, in the beginning at least, since it holds capacity examples and it would need to fetch new data only after it reaches min_after_dequeue which is lower than capacity and that it would result in a somehow steady GPU utilization.

But actually, the training begins as soon as the queue reaches min_after_dequeue examples. Thus, the queue is being dequeued as soon as the queue reaches min_after_dequeue examples to run the train_op, and since the time to feed the queue is 15x slower than the execution time of train_op, the number of elements in the queue drops below min_after_dequeue right after the first iteration of the train_op and the train_op has to wait for the queue to reach again min_after_dequeue examples.

When I force the train_op to wait until the queue is fed up to capacity (with capacity = 100*batch) instead of starting automatically when it reaches min_after_dequeue (with min_after_dequeue=80*batch), the GPU utilization is steady for like 10 seconds before going back to 0%, which is understandable since the queue reaches min_after_dequeue example in less than 10 seconds.

  • So what was the solution. I am facing the same problem. Knowing that I am running my code using tf.keras. and my buffer size is 1000 + 4 * batch size.
    – W. Sam
    Sep 23 '19 at 19:01

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