KL Divergence for two probability distributions in PyTorch

I have two probability distributions. How should I find the KL-divergence between them in PyTorch? The regular cross entropy only accepts integer labels.

Yes, PyTorch has a method named `kl_div` under `torch.nn.functional` to directly compute KL-devergence between tensors. Suppose you have tensor `a` and `b` of same shape. You can use the following code:

``````import torch.nn.functional as F
out = F.kl_div(a, b)
``````

For more details, see the above method documentation.

• Yeah, I had seen that function, but it was returning a negative value. I figured out what the problem was: I had to use `log` of input, and the actual value of target. Now, it works fine. Apr 18, 2018 at 23:31
• you can also write the kl-equation using pytorch's tensor method. It is easy. Apr 19, 2018 at 0:55

function `kl_div` is not the same as wiki's explanation.

I use the following:

``````# this is the same example in wiki
P = torch.Tensor([0.36, 0.48, 0.16])
Q = torch.Tensor([0.333, 0.333, 0.333])

(P * (P / Q).log()).sum()
# tensor(0.0863), 10.2 µs ± 508

F.kl_div(Q.log(), P, None, None, 'sum')
# tensor(0.0863), 14.1 µs ± 408 ns
``````

compare to `kl_div`, even faster

• It gives the same answer, therefore there's no evidence it's not the same. Speed is a separate issue entirely. Aug 7, 2019 at 13:23
• In my test, the first way to compute kl div is faster :D Aug 24, 2019 at 9:22
• @AleksandrDubinsky Its not the same as input is `Q.log()` which is pretty non-intuitive when taken out of context of machine learning. Oct 12, 2020 at 6:46
• @BlackJack21 Thanks for explaining what the OP meant. While slightly non-intuitive, keeping probabilities in log space is often useful for reasons of numerical precision. What's non-intuitive is that one input is in log space while the other is not. ¯_(ツ)_/¯ Oct 12, 2020 at 13:50
• @AleksandrDubinsky I agree with you, this design is confusing. Oct 15, 2020 at 4:41

If you have two probability distribution in form of pytorch `distribution` object. Then you are better off using the function `torch.distributions.kl.kl_divergence(p, q)`. For documentation follow the link

• It gave me NotImplementedError: Feb 7, 2020 at 8:46
• Check for pytorch version. I think it should be >1.0 Feb 8, 2020 at 12:48
• `torch.distributions.kl.kl_divergence` seems to need distributions to be registered with pytorch.org/docs/stable/… Jun 13, 2021 at 17:43
• Registration is the correct method. Mar 12, 2022 at 5:40

If you are using the normal distribution, then the following code will directly compare the two distributions themselves:

``````p = torch.distributions.normal.Normal(p_mu, p_std)
q = torch.distributions.normal.Normal(q_mu, q_std)

loss = torch.distributions.kl_divergence(p, q)
``````

p and q are two tensor objects.

This code will work and won't give any NotImplementedError.

If working with Torch distributions

``````mu = torch.Tensor([0] * 100)
sd = torch.Tensor([1] * 100)

p = torch.distributions.Normal(mu,sd)
q = torch.distributions.Normal(mu,sd)

out = torch.distributions.kl_divergence(p, q).mean()
out.tolist() == 0
True
``````
• This does not seem to be supported for all distributions defined. Mar 12, 2022 at 5:00