Assuming that your input tensors `prob_a`

and `prob_b`

are probability tensors that sum to 1 along the last axis, you could do it like this:

```
def kl(x, y):
X = tf.distributions.Categorical(probs=x)
Y = tf.distributions.Categorical(probs=y)
return tf.distributions.kl_divergence(X, Y)
result = kl(prob_a, prob_b)
```

A simple example:

```
import numpy as np
import tensorflow as tf
a = np.array([[0.25, 0.1, 0.65], [0.8, 0.15, 0.05]])
b = np.array([[0.7, 0.2, 0.1], [0.15, 0.8, 0.05]])
sess = tf.Session()
print(kl(a, b).eval(session=sess)) # [0.88995184 1.08808468]
```

You would get the same result with

```
np.sum(a * np.log(a / b), axis=1)
```

However, this implementation is a bit buggy (checked in Tensorflow 1.8.0).

If you have zero probabilities in `a`

, e.g. if you try `[0.8, 0.2, 0.0]`

instead of `[0.8, 0.15, 0.05]`

, you will get `nan`

even though by Kullback-Leibler definition `0 * log(0 / b)`

should contribute as zero.

To mitigate this, one should add some small numerical constant. It is also prudent to use `tf.distributions.kl_divergence(X, Y, allow_nan_stats=False)`

to cause a runtime error in such situations.

Also, if there are some zeros in `b`

, you will get `inf`

values which won't be caught by the `allow_nan_stats=False`

option so those have to be handled as well.