I'm trying to implement a neural network architecture in Haskell, and use it on MNIST.

I'm using the `hmatrix`

package for linear algebra.
My training framework is built using the `pipes`

package.

My code compiles and doesn't crash. But the problem is, certain combinations of layer size (say, 1000), minibatch size, and learning rate give rise to `NaN`

values in the computations. After some inspection, I see that extremely small values (order of `1e-100`

) eventually appear in the activations. But, even when that doesn't happen, the training still doesn't work. There's no improvement over its loss or accuracy.

I checked and rechecked my code, and I'm at a loss as to what the root of the problem could be.

Here's the backpropagation training, which computes the deltas for each layer:

```
backward lf n (out,tar) das = do
let δout = tr (derivate lf (tar, out)) -- dE/dy
deltas = scanr (\(l, a') δ ->
let w = weights l
in (tr a') * (w <> δ)) δout (zip (tail $ toList n) das)
return (deltas)
```

`lf`

is the loss function, `n`

is the network (`weight`

matrix and `bias`

vector for each layer), `out`

and `tar`

are the actual output of the network and the `target`

(desired) output, and `das`

are the activation derivatives of each layer.

In batch mode, `out`

, `tar`

are matrices (rows are output vectors), and `das`

is a list of the matrices.

Here's the actual gradient computation:

```
grad lf (n, (i,t)) = do
-- Forward propagation: compute layers outputs and activation derivatives
let (as, as') = unzip $ runLayers n i
(out) = last as
(ds) <- backward lf n (out, t) (init as') -- Compute deltas with backpropagation
let r = fromIntegral $ rows i -- Size of minibatch
let gs = zipWith (\δ a -> tr (δ <> a)) ds (i:init as) -- Gradients for weights
return $ GradBatch ((recip r .*) <$> gs, (recip r .*) <$> squeeze <$> ds)
```

Here, `lf`

and `n`

are the same as above, `i`

is the input, and `t`

is the target output (both in batch form, as matrices).

`squeeze`

transforms a matrix into a vector by summing over each row. That is, `ds`

is a list of matrices of deltas, where each column corresponds to the deltas for a row of the minibatch. So, the gradients for the biases are the average of the deltas over all the minibatch. The same thing for `gs`

, which corresponds to the gradients for the weights.

Here's the actual update code:

```
move lr (n, (i,t)) (GradBatch (gs, ds)) = do
-- Update function
let update = (\(FC w b af) g δ -> FC (w + (lr).*g) (b + (lr).*δ) af)
n' = Network.fromList $ zipWith3 update (Network.toList n) gs ds
return (n', (i,t))
```

`lr`

is the learning rate. `FC`

is the layer constructor, and `af`

is the activation function for that layer.

The gradient descent algorithm makes sure to pass in a negative value for the learning rate. The actual code for the gradient descent is simply a loop around a composition of `grad`

and `move`

, with a parameterized stop condition.

Finally, here's the code for a mean square error loss function:

```
mse :: (Floating a) => LossFunction a a
mse = let f (y,y') = let gamma = y'-y in gamma**2 / 2
f' (y,y') = (y'-y)
in Evaluator f f'
```

`Evaluator`

just bundles a loss function and its derivative (for calculating the delta of the output layer).

The rest of the code is up on GitHub: NeuralNetwork.

So, if anyone has an insight into the problem, or even just a sanity check that I'm correctly implementing the algorithm, I'd be grateful.

`ce = x_j - log(sum_i(exp(x)))`

calculation from here so you don't take the log of the exponential (which often generates NaNs) – mdaoust Jan 15 '20 at 12:5718more comments