I am working with Keras 2.0.0 and I'd like to train a deep model with a huge amount of parameters on a GPU. Using too large images, I'm running out of memory (OOM). Using too low images, the model's accuracy will be worse than possible. Therefore I'd like to find the biggest possible input size of images that fit to my GPU. Is there any functionality calculating the memory (e.g. comparable to model.summary()) given the model and input data?

I appreciate your help.

  • 3
    You can look at how they compute the memory usage [here] (cs231n.github.io/convolutional-networks/#case), you could also try to reduce the batch size instead of the resolution. Commented Mar 31, 2017 at 9:55
  • 1
    Thanks for your answer. Actually, I was reading the given link before posting my question. But I wanted to avoid manual computing :D Also I don't want to reduce batch size as I want to have a good representation of my whole data set in a statistical sense. Commented Mar 31, 2017 at 10:09
  • 4
    try-fail will be the fastest to answer your question. Keras isn't the computation library, it's only a wrapper around the backend you chose. The memory management is handled differently for different backends. The memory consumption will not only depend on the number of parameters, LSTM will use a lot of memory even if the number of parameters is low... You should just try and see the actual memory consumption :)
    – Nassim Ben
    Commented Mar 31, 2017 at 11:11
  • I was afraid of that. But I will do so...thanks! (Nassim, you like answering my questions, don't you? :D) Commented Mar 31, 2017 at 11:53
  • love it :-) have fun
    – Nassim Ben
    Commented Mar 31, 2017 at 11:58

5 Answers 5


I created a complete function based on the answer of Fabrício Pereira.

def get_model_memory_usage(batch_size, model):
    import numpy as np
        from keras import backend as K
        from tensorflow.keras import backend as K

    shapes_mem_count = 0
    internal_model_mem_count = 0
    for l in model.layers:
        layer_type = l.__class__.__name__
        if layer_type == 'Model':
            internal_model_mem_count += get_model_memory_usage(batch_size, l)
        single_layer_mem = 1
        out_shape = l.output_shape
        if type(out_shape) is list:
            out_shape = out_shape[0]
        for s in out_shape:
            if s is None:
            single_layer_mem *= s
        shapes_mem_count += single_layer_mem

    trainable_count = np.sum([K.count_params(p) for p in model.trainable_weights])
    non_trainable_count = np.sum([K.count_params(p) for p in model.non_trainable_weights])

    number_size = 4.0
    if K.floatx() == 'float16':
        number_size = 2.0
    if K.floatx() == 'float64':
        number_size = 8.0

    total_memory = number_size * (batch_size * shapes_mem_count + trainable_count + non_trainable_count)
    gbytes = np.round(total_memory / (1024.0 ** 3), 3) + internal_model_mem_count
    return gbytes

UPDATE 2019.10.06: Added support for models which contain other models as layers.

UPDATE 2020.07.17: Function now works correctly in TensorFlow v2.

  • the calculation makes sense, but for some reason, it seems to output memory usage far beyond what my GPU has, while Keras is happily training on it. E.g: get_model_memory_usage(batch_size, model) => 28GB, while my GTX 1060 has 6GB :)
    – Alon Burg
    Commented Oct 16, 2017 at 7:36
  • 1
    i wonder if it could be related to the loss function? which might require some memory ...
    – Alon Burg
    Commented Oct 16, 2017 at 8:18
  • 3
    Probably Theano or TensorFlow don't store all intermediate shapes in memory except 2 shapes which involved in calculation of current layer. So to find memory required by shapes we need to get 2 maximum consecutive shapes volume.
    – ZFTurbo
    Commented Oct 16, 2017 at 17:18
  • 9
    There's also memory needed for result of every layer and also gradients. So this is incorrect. Commented Nov 6, 2017 at 14:10
  • 3
    Shouldn't it be : total_memory = 4.0*( batch_size*shapes_mem_count + trainable_count + non_trainable_count ) weights are shared amongst all the batches. No matter the batch size, the weights will take up same amount of memory. Don't need to multiply weights by batchsize.
    – mkuse
    Commented Nov 30, 2018 at 5:12

Here is my variant of @ZFTurbo's answer. It offers better handling for nested Keras models, different TensorFlow dtypes, and removes the dependency on NumPy. I've written and tested this on TensorFlow 2.3.0, and it may not work on earlier versions.

def keras_model_memory_usage_in_bytes(model, *, batch_size: int):
    Return the estimated memory usage of a given Keras model in bytes.
    This includes the model weights and layers, but excludes the dataset.

    The model shapes are multipled by the batch size, but the weights are not.

        model: A Keras model.
        batch_size: The batch size you intend to run the model with. If you
            have already specified the batch size in the model itself, then
            pass `1` as the argument here.
        An estimate of the Keras model's memory usage in bytes.

    default_dtype = tf.keras.backend.floatx()
    shapes_mem_count = 0
    internal_model_mem_count = 0
    for layer in model.layers:
        if isinstance(layer, tf.keras.Model):
            internal_model_mem_count += keras_model_memory_usage_in_bytes(
                layer, batch_size=batch_size
        single_layer_mem = tf.as_dtype(layer.dtype or default_dtype).size
        out_shape = layer.output_shape
        if isinstance(out_shape, list):
            out_shape = out_shape[0]
        for s in out_shape:
            if s is None:
            single_layer_mem *= s
        shapes_mem_count += single_layer_mem

    trainable_count = sum(
        [tf.keras.backend.count_params(p) for p in model.trainable_weights]
    non_trainable_count = sum(
        [tf.keras.backend.count_params(p) for p in model.non_trainable_weights]

    total_memory = (
        batch_size * shapes_mem_count
        + internal_model_mem_count
        + trainable_count
        + non_trainable_count
    return total_memory

  • I have a question about internal_model_mem_count, it seems to be always 0? but what does this mean? why compute this? thank you
    – Jing
    Commented Oct 4, 2021 at 15:45
  • 1
    @Jing, it is possible to use a Keras model as an individual layer in a larger model. To account for this, keras_model_memory_usage_in_bytes() recursively calls itself to measure memory usage and tracks nested model memory usage in the internal_model_mem_count variable. Commented Oct 6, 2021 at 9:38
  • Doesn't seem that the calculation is correct - my basic UNET model (disk size of 1 GB) with batch size 1, this yields 101.594.448.001, which is 100 GB. It trains fine on a 16 GB RAM, or 12 GB NVidia.
    – illan
    Commented Sep 27, 2022 at 15:54

Hope this can help you...

  • Here is how determinate a number of shapes of you Keras model (var model), and each shape unit occupies 4 bytes in memory:

    shapes_count = int(numpy.sum([numpy.prod(numpy.array([s if isinstance(s, int) else 1 for s in l.output_shape])) for l in model.layers]))

    memory = shapes_count * 4

  • And here is how determinate a number of params of your Keras model (var model):

    from keras import backend as K

    trainable_count = int(numpy.sum([K.count_params(p) for p in set(model.trainable_weights)]))

    non_trainable_count = int(numpy.sum([K.count_params(p) for p in set(model.non_trainable_weights)]))

  • 3
    Please add more description regarding your answer. Commented Jul 21, 2017 at 17:04
  • If you use batch training, to calculate the memory needed on the GPU, you additionally have to multiply the calculated memory by the batch size. Commented Jul 27, 2017 at 14:58

Given the previous answers do not take into account the memory required for gradients, and/or intermediate outputs, and/or mixed dtypes, and/or nested models, I decided to give it a go as well. Note that the function returns the estimated memory requirement in bits, that the model must be compiled with a fully known input shape (including batch_size), and that the function does not consider the memory required for internal computations (e.g., neural attention). Microsoft has developed a method that is likely more accurate, but has not released the code.

import tensorflow as tf, warnings

# Define function to calculate one layer's memory requirement
def layer_mem(layer: tf.keras.layers.Layer, prev_layer_mem: int) -> int:
    # Check whether calculations can be performed
    if not hasattr(layer, "output_shape") or (None in layer.output_shape):
        msg = f"Check `model.summary(expand_nested=True)` and recompile model to ensure that {layer.name} has a fully defined `output_shape`, including `batch_size`. Using previous layer's memory requirement."
        return prev_layer_mem
    # Collect sizes
    out_size = int(tf.reduce_prod(layer.output_shape)) 
    params = gradients = int(layer.count_params())
    bits = int(layer.dtype[-2:])
    # Calculate memory requirement
    return (params+gradients+out_size)*bits

# Define recursive function to gather all layers' memory requirements
def model_mem(model: tf.keras.Model) -> int:
    # Make limitations known
    warnings.warn("This function does not take into account the memory required for calculations (e.g., outer products)")
    # Initialize
    total_bits = 0
    # Loop over layers in model
    for layer in model.layers:
        # In case of nested model...
        if hasattr(layer, "layers"):
            # ... apply recursion
            total_bits += model_mem(layer)
            # Calculate and add layer's memory requirement
            prev_layer_mem = layer_mem(layer, locals().get("prev_layer_mem", 0))
            total_bits += prev_layer_mem
    return total_bits

I believe that if you use a data generator either custom written or leverage some existing generators from keras, it will resolve your issue. Memory error usually arises when all the loaded data becomes over bearing for the system, instead using a generator will break down the dataset into segments, that way you won't run out of memory and will be train on any system.

  • 1
    This attitude is incorrect. While data generators or small batch sizes can help reduce memory usage, it is already common for research-grade models to consume more memory than consumer-grade GPUs can offer. Commented Oct 18, 2020 at 12:19

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.