The key point is that you do not need to sample from the NN-produced distribution. All you need is to optimize the likelihood of the target value under the NN distribution.

There is an example in the official PyTorch example on VAE (https://github.com/pytorch/examples/tree/master/vae), though for multidimensional Bernoulli distribution.

Since PyTorch 0.4, you can use torch.distributions: instantiate distribution `distro`

with outputs of your NN and then optimize `-distro.log_prob(target)`

.

EDIT: As requested in a comment, a complete example of using the `torch.distributions`

module.

First, we create a heteroscedastic dataset:

```
import numpy as np
import torch
X = np.random.uniform(size=300)
Y = X + 0.25*X*np.random.normal(size=X.shape[0])
```

We build a trivial model, which is perfectly able to match the generative process of our data:

```
class Model(torch.nn.Module):
def __init__(self):
super().__init__()
self.mean_coeff = torch.nn.Parameter(torch.Tensor([0]))
self.var_coeff = torch.nn.Parameter(torch.Tensor([1]))
def forward(self, x):
return torch.distributions.Normal(self.mean_coeff * x, self.var_coeff * x)
mdl = Model()
optim = torch.optim.SGD(mdl.parameters(), lr=1e-3)
```

Initialization of the model makes it always produce a standard normal, which is a poor fit for our data, so we train (note it is a very stupid batch training, but demonstrates that you can output a set of distributions for your batch at once):

```
for _ in range(2000): # epochs
dist = mdl(torch.from_numpy(X).float())
obj = -dist.log_prob(torch.from_numpy(Y).float()).mean()
optim.zero_grad()
obj.backward()
optim.step()
```

Eventually, the learned parameters should match the values we used to construct the Y.

```
print(mdl.mean_coeff, mdl.var_coeff)
# tensor(1.0150) tensor(0.2597)
```