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
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),
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,
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)
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
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.