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

Solution:

```
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(
shape=[input_length],
minval=0,
maxval=None,
dtype=tf.float32,
seed=None,
name=None
)
# 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.