Is there a built-in KL divergence loss function in TensorFlow?

I have two tensors, `prob_a` and `prob_b` with shape `[None, 1000]`, and I want to compute the KL divergence from `prob_a` to `prob_b`. Is there a built-in function for this in TensorFlow? I tried using `tf.contrib.distributions.kl(prob_a, prob_b)`, but it gives:

NotImplementedError: No KL(dist_a || dist_b) registered for dist_a type Tensor and dist_b type Tensor

If there is no built-in function, what would be a good workaround?

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.

• Your arrays `a` and `b` seems to sum to 1 on the last axis, not on the first Commented Aug 6, 2019 at 19:43
• Yes, it would have been better to say "along axis 1", or even better, the last axis. I meant axis 1 when I wrote "along the first axis", as there is also axis 0. I'll edit the answer. Thanks! Commented Aug 7, 2019 at 12:16
• `AttributeError: module 'tensorflow' has no attribute 'distributions'` Commented Apr 8, 2020 at 14:46

For there is softmax_cross_entropy_with_logits, there is no need to optimize on KL.

``````KL(prob_a, prob_b)
= Sum(prob_a * log(prob_a/prob_b))
= Sum(prob_a * log(prob_a) - prob_a * log(prob_b))
= - Sum(prob_a * log(prob_b)) + Sum(prob_a * log(prob_a))
= - Sum(prob_a * log(prob_b)) + const
= H(prob_a, prob_b) + const
``````

If prob_a is not const. You can rewrite it to the sub of two entropies.

``````KL(prob_a, prob_b)
= Sum(prob_a * log(prob_a/prob_b))
= Sum(prob_a * log(prob_a) - prob_a * log(prob_b))
= - Sum(prob_a * log(prob_b)) + Sum(prob_a * log(prob_a))
= H(prob_a, prob_b) - H(prob_a, prob_a)
``````
• There are cases where target probability `prob_a` changes during the optimisation. Then it becomes not constant. Commented Feb 21, 2019 at 10:04

I'm not sure why it's not implemented, but perhaps there is a workaround. The KL divergence is defined as:

`KL(prob_a, prob_b) = Sum(prob_a * log(prob_a/prob_b))`

The cross entropy H, on the other hand, is defined as:

`H(prob_a, prob_b) = -Sum(prob_a * log(prob_b))`

So, if you create a variable `y = prob_a/prob_b`, you could obtain the KL divergence by calling negative `H(proba_a, y)`. In Tensorflow notation, something like:

`KL = tf.reduce_mean(-tf.nn.softmax_cross_entropy_with_logits(prob_a, y))`

• KL divergence must be 0 when `prob_a` = `prob_b`. But last line doesn't give 0. Commented Jan 26, 2017 at 0:33
• Yes, it does. When `prob_a = prob_b`, we get `y = 1`. Then, `H(prob_a, y)` is zero from `log(y)`. Are you saying you checked it using Tensorflow's `softmax_cross_entropy_with_logits(prob_a, y)` and the result was not zero? Commented Jan 27, 2017 at 7:26
• Exactly. TensorFlow's implementation might be slightly different than the actual formula. Commented Jan 27, 2017 at 11:17
• Worth pointing out that softmax_cross_entropy_with_logits(prob_a,y) does not actually implement H(prob_a,y), it implements H(softmax(a),y). So using softmax_cross_entropy_with_logits will only work if you try to calculate the KL divergence on the activations of a softmax function (prob_a) and have access to the unscaled logits (a) Commented Aug 20, 2019 at 13:17

`tf.contrib.distributions.kl` takes instances of a `tf.distribution` not a `Tensor`.

Example:

``````  ds = tf.contrib.distributions
p = ds.Normal(loc=0., scale=1.)
q = ds.Normal(loc=1., scale=2.)
kl = ds.kl_divergence(p, q)
# ==> 0.44314718
``````

``````prob_a = tf.nn.softmax(a)
cr_aa = tf.nn.softmax_cross_entropy_with_logits(prob_a, a)
cr_ab = tf.nn.softmax_cross_entropy_with_logits(prob_a, b)
kl_ab = tf.reduce_sum(cr_ab - cr_aa)
``````
• Not going to work! From the documentation: "WARNING: This op expects unscaled logits, since it performs a softmax on logits internally for efficiency. Do not call this op with the output of softmax, as it will produce incorrect results" (emphasis mine) Commented Mar 22, 2018 at 6:39
• Assuming that you have access to logits a and b. This is not calling it on prob_a and prob_b. It is calling it on a and b.
– Sara
Commented Nov 15, 2018 at 22:36

I think this might work:

``````tf.reduce_sum(p * tf.log(p/q))
``````

where p is my actual probability distribution and q is my approximate probability distribution.

I used the function from this code (from this Medium post) to calculate the KL-divergence of any given tensor from a normal Gaussian distribution, where `sd` is the standard deviation and `mn` is the tensor.

``````latent_loss = -0.5 * tf.reduce_sum(1.0 + 2.0 * sd - tf.square(mn) - tf.exp(2.0 * sd), 1)
``````