I'm changing my TensorFlow code from the old queue interface to the new Dataset API. With the old interface I could specify the num_threads argument to the tf.train.shuffle_batch queue. However, the only way to control the amount of threads in the Dataset API seems to be in the map function using the num_parallel_calls argument. However, I'm using the flat_map function instead, which doesn't have such an argument.

Question: Is there a way to control the number of threads/processes for the flat_map function? Or is there are way to use map in combination with flat_map and still specify the number of parallel calls?

Note that it is of crucial importance to run multiple threads in parallel, as I intend to run heavy pre-processing on the CPU before data enters the queue.

There are two (here and here) related posts on GitHub, but I don't think they answer this question.

Here is a minimal code example of my use-case for illustration:

with tf.Graph().as_default():
    data = tf.ones(shape=(10, 512), dtype=tf.float32, name="data")
    input_tensors = (data,)

    def pre_processing_func(data_):
        # normally I would do data-augmentation here
        results = (tf.expand_dims(data_, axis=0),)
        return tf.data.Dataset.from_tensor_slices(results)

    dataset_source = tf.data.Dataset.from_tensor_slices(input_tensors)
    dataset = dataset_source.flat_map(pre_processing_func)
    # do something with 'dataset'
  • 1
    Kind of a clunky workaround, but how about using map() with your preprocessing function, then prefetch() to buffer items and finally flat_map() with a lambda x : x function that takes care of flattening? – GPhilo Nov 21 '17 at 11:05
  • @GPhilo That idea seems to work indeed, not sure if there is any overhead anywhere. Do you want to give this as an answer, i.e.: pre_processing_func no longer returning a dataset and using a regular map on it, followed by a dataset.flat_map(lambda x: tf.data.Dataset.from_tensor_slices(x)) – CNugteren Nov 21 '17 at 12:52
  • Good to hear that it helped. I'll write a small full-code example as an answer. – GPhilo Nov 21 '17 at 12:54
  • I have a question though, is it your intended use-case to have one Dataset instance for each sample? It looks extremely confusing to me, as typically you'd have only one Dataset instance that produces batches. – GPhilo Nov 21 '17 at 13:04
  • No, one Dataset in total. In the example posted here I would have 10 input vectors with 512 elements each. Then, in pre_processing_func I would apply data-augmentation, generating a random amount of vectors of 512 for each input. In the example there is no randomness, but always returns 1 sample for 1 input, simulated by the tf.expand_dims. – CNugteren Nov 21 '17 at 13:08

To the best of my knowledge, at the moment flat_map does not offer parallelism options. Given that the bulk of the computation is done in pre_processing_func, what you might use as a workaround is a parallel map call followed by some buffering, and then using a flat_map call with an identity lambda function that takes care of flattening the output.

In code:


def pre_processing_func(data_):
    # data-augmentation here
    # generate new samples starting from the sample `data_`
    artificial_samples = generate_from_sample(data_)
    return atificial_samples

dataset_source = (tf.data.Dataset.from_tensor_slices(input_tensors).
                  map(pre_processing_func, num_parallel_calls=NUM_THREADS).
                  flat_map(lambda *x : tf.data.Dataset.from_tensor_slices(x)).
                  shuffle(BUFFER_SIZE)) # my addition, probably necessary though

Note (to myself and whoever will try to understand the pipeline):

Since pre_processing_func generates an arbitrary number of new samples starting from the initial sample (organised in matrices of shape (?, 512)), the flat_map call is necessary to turn all the generated matrices into Datasets containing single samples (hence the tf.data.Dataset.from_tensor_slices(x) in the lambda) and then flatten all these datasets into one big Dataset containing individual samples.

It's probably a good idea to .shuffle() that dataset, or generated samples will be packed together.

  • Minor suggestion: make the lambda accept *x instead of x to make it generic for the case of multiple inputs (e.g. data and labels). Aside from this, one problem I have with your suggestion is that the prefetch is before the flat_map. Is that really needed? Because now the buffer-size is not the actual buffer-size, but the amount of inputs (which might result in a variable number of items in the buffer finally). Is there a way around this? – CNugteren Nov 21 '17 at 13:29
  • I updated the lambda as suggested (or at least I hope, I'm not super confident wit generic arguments). About the prefetch, it is necessary if you want to have the threads running in parallel. I don't have specifics on the implementation of map, but from what I understood, unless you put a buffer after it, the threads will hang until the value they produce is consumed. Indeed, the prefetch counts "items", which at that stage is not samples, but the matrices with the artificial samples. You can trigger that value as needed (1000 is probably way too high). – GPhilo Nov 21 '17 at 13:43
  • The actual samples buffer, however, is the one in shuffle (which, if you don't want to have shuffling, can be replaced by another prefetch()). – GPhilo Nov 21 '17 at 13:44
  • As I said, for me this buffer size is meaningless, since one input could produce anywhere in the range of 1 to 1000 inputs. But anyway I've put the prefetch after the flat_map and it seems to run in parallel, I tested with a small sample. And also according to your reasoning, the output of map would be directly consumed by flat_map, which would directly go into the prefetch buffer afterwards, right? I think the question is solved, thanks. – CNugteren Nov 21 '17 at 14:59
  • That buffer size should not be interpreted as the number of samples stored in the buffer. That's the number of results from map that can be stored before stalling the threads. And no, the threads in map stall until their output is consumed, before starting with a new sample. They get directly consumed only if flat_map is fast enough to process 5 outputs before one map thread produces a new output. Since this is very likely the case, you get a speedup. In the end, the difference is minimal and if i works for you, no need to complicate things ;) – GPhilo Nov 21 '17 at 15:09

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