Is there an equivalent function to numpy random choice in Tensorflow. In numpy we can get an item randomly from the given list with its weights.

 np.random.choice([1,2,3,5], 1, p=[0.1, 0, 0.3, 0.6, 0])

This code will select an item from the given list with p weights.

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No, but you can achieve the same result using tf.multinomial:

elems = tf.convert_to_tensor([1,2,3,5])
samples = tf.multinomial(tf.log([[1, 0, 0.3, 0.6]]), 1) # note log-prob
elems[tf.cast(samples[0][0], tf.int32)].eval()
Out: 1
elems[tf.cast(samples[0][0], tf.int32)].eval()
Out: 5

The [0][0] part is here, as multinomial expects a row of unnormalized log-probabilities for each element of the batch and also has another dimension for the number of samples.

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  • 1
    How can this be extended to the case of (i) dynamic tensors whose shape can only be inferred during execution and (ii) equal probability of selection for each element in this tensor ? – HuckleberryFinn Mar 8 '18 at 16:13
  • I'd try something like: tf.multinomial(tf.ones_like(dynamic_tensor), num_samples=1). – sygi Mar 17 '18 at 12:22

My team and I had the same problem with the requirement of keeping all operations as tensorflow ops and implementing a 'without replacement' version.


def tf_random_choice_no_replacement_v1(one_dim_input, num_indices_to_drop=3):

    input_length = tf.shape(one_dim_input)[0]

    # create uniform distribution over the sequence
    # for tf.__version__<1.11 use tf.random_uniform - no underscore in function name
    uniform_distribution = tf.random.uniform(

    # grab the indices of the greatest num_words_to_drop values from the distibution
    _, indices_to_keep = tf.nn.top_k(uniform_distribution, input_length - num_indices_to_drop)
    sorted_indices_to_keep = tf.contrib.framework.sort(indices_to_keep)

    # gather indices from the input array using the filtered actual array
    result = tf.gather(one_dim_input, sorted_indices_to_keep)
    return result

The idea behind this code is to produce a random uniform distribution with a dimensionality that is equal to the dimension of the vector over which you'd like to perform the choice selection. Since the distribution will produce a sequence of numbers that will be unique and able to be ranked, you can take the indices of the top k positions, and use those as your choices. Since the position of the top k will be as random as the uniform distribution, it equates to performing a random choice without replacement.

This can perform the choice operation on any 1-d sequence in tensorflow.

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  • OP's question does not assume uniform distribution. Probabilities of each choice are specified. – Brenden Petersen Oct 21 at 18:09

If instead of sampling random elements from a 1-dimensional Tensor, you want to randomly sample rows from an n-dimensional Tensor, you can combine tf.multinomial and tf.gather.

def _random_choice(inputs, n_samples):
    With replacement.
      inputs (Tensor): Shape [n_states, n_features]
      n_samples (int): The number of random samples to take.
      sampled_inputs (Tensor): Shape [n_samples, n_features]
    # (1, n_states) since multinomial requires 2D logits.
    uniform_log_prob = tf.expand_dims(tf.zeros(tf.shape(inputs)[0]), 0)

    ind = tf.multinomial(uniform_log_prob, n_samples)
    ind = tf.squeeze(ind, 0, name="random_choice_ind")  # (n_samples,)

    return tf.gather(inputs, ind, name="random_choice")
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In tensorflow 2.0 tf.compat.v1.multinomial is deprecated instead use tf.random.categorical

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Very late to the party but I will add another solution since the existing tf.multinomial approach takes up a lot of temporary memory and so can't be used for large inputs. Here is the method I use (for TF 2.0):

# Sampling k members of 1D tensor a using weights w
cum_dist = tf.math.cumsum(w)
cum_dist /= cum_dist[-1]  # to account for floating point errors
unif_samp = tf.random.uniform((k,), 0, 1)
idxs = tf.searchsorted(cum_dist, unif_samp)
samp = tf.gather(a, idxs)  # samp contains the k weighted samples
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  • Any chance to use this for a tensor of shape [batch,timesteps,probabilities]? Where each timestep has a small amount of probabilities assigned to it for a Mixed Density Network e.g. [0.2,0.1,0.7]. The requirement is one pick per row from another tensor of the same shape resulting in [batch,timesteps,1] – JP K. Oct 12 at 7:23

There is no need to do random choice in tf. you can just directly do it using np.random.choice(data, p=probs), tf can accept that.

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