# How to do automatic differentiation on complex datatypes?

Given a very simple Matrix definition based on Vector:

``````import Numeric.AD
import qualified Data.Vector as V

newtype Mat a = Mat { unMat :: V.Vector a }

scale' f = Mat . V.map (*f) . unMat
add' a b = Mat \$ V.zipWith (+) (unMat a) (unMat b)
sub' a b = Mat \$ V.zipWith (-) (unMat a) (unMat b)
mul' a b = Mat \$ V.zipWith (*) (unMat a) (unMat b)
pow' a e = Mat \$ V.map (^e) (unMat a)

sumElems' :: Num a => Mat a -> a
sumElems' = V.sum . unMat
``````

(for demonstration purposes ... I am using hmatrix but thought the problem was there somehow)

And an error function (`eq3`):

``````eq1' :: Num a => [a] -> [Mat a] -> Mat a
eq1' as φs = foldl1 add' \$ zipWith scale' as φs

eq3' :: Num a => Mat a -> [a] -> [Mat a] -> a
eq3' img as φs = negate \$ sumElems' (errImg `pow'` (2::Int))
where errImg = img `sub'` (eq1' as φs)
``````

Why the compiler not able to deduce the right types in this?

``````diffTest :: forall a . (Fractional a, Ord a) => Mat a -> [Mat a] -> [a] -> [[a]]
diffTest m φs as0 = gradientDescent go as0
where go xs = eq3' m xs φs
``````

The exact error message is this:

``````src/Stuff.hs:59:37:
Could not deduce (a ~ Numeric.AD.Internal.Reverse.Reverse s a)
from the context (Fractional a, Ord a)
bound by the type signature for
diffTest :: (Fractional a, Ord a) =>
Mat a -> [Mat a] -> [a] -> [[a]]
at src/Stuff.hs:58:13-69
or from (reflection-1.5.1.2:Data.Reflection.Reifies
s Numeric.AD.Internal.Reverse.Tape)
bound by a type expected by the context:
reflection-1.5.1.2:Data.Reflection.Reifies
s Numeric.AD.Internal.Reverse.Tape =>
[Numeric.AD.Internal.Reverse.Reverse s a]
-> Numeric.AD.Internal.Reverse.Reverse s a
at src/Stuff.hs:59:21-42
‘a’ is a rigid type variable bound by
the type signature for
diffTest :: (Fractional a, Ord a) =>
Mat a -> [Mat a] -> [a] -> [[a]]
at src//Stuff.hs:58:13
Expected type: [Numeric.AD.Internal.Reverse.Reverse s a]
-> Numeric.AD.Internal.Reverse.Reverse s a
Actual type: [a] -> a
Relevant bindings include
go :: [a] -> a (bound at src/Stuff.hs:60:9)
as0 :: [a] (bound at src/Stuff.hs:59:15)
φs :: [Mat a] (bound at src/Stuff.hs:59:12)
m :: Mat a (bound at src/Stuff.hs:59:10)
diffTest :: Mat a -> [Mat a] -> [a] -> [[a]]
(bound at src/Stuff.hs:59:1)
In the first argument of ‘gradientDescent’, namely ‘go’
In the expression: gradientDescent go as0
``````
• I am not sure if I have actually asked this question yesterday already. I thought I did ... but it doesn't appear in my newest questions ... – fho Apr 1 '15 at 12:42

## 1 Answer

The `gradientDescent` function from `ad` has the type

``````gradientDescent :: (Traversable f, Fractional a, Ord a) =>
(forall s. Reifies s Tape => f (Reverse s a) -> Reverse s a) ->
f a -> [f a]
``````

Its first argument requires a function of the type `f r -> r` where `r` is `forall s. (Reverse s a)`. `go` has the type `[a] -> a` where `a` is the type bound in the signature of `diffTest`. These `a`s are the same, but `Reverse s a` isn't the same as `a`.

The `Reverse` type has instances for a number of type classes that could allow us to convert an `a` into a `Reverse s a` or back. The most obvious is `Fractional a => Fractional (Reverse s a)` which would allow us to convert `a`s into `Reverse s a`s with `realToFrac`.

To do so, we'll need to be able to map a function `a -> b` over a `Mat a` to obtain a `Mat b`. The easiest way to do this will be to derive a `Functor` instance for `Mat`.

``````{-# LANGUAGE DeriveFunctor #-}

newtype Mat a = Mat { unMat :: V.Vector a }
deriving Functor
``````

We can convert the `m` and `fs` into any `Fractional a' => Mat a'` with `fmap realToFrac`.

``````diffTest m fs as0 = gradientDescent go as0
where go xs = eq3' (fmap realToFrac m) xs (fmap (fmap realToFrac) fs)
``````

But there's a better way hiding in the ad package. The `Reverse s a` is universally qualified over all `s` but the `a` is the same `a` as the one bound in the type signature for `diffTest`. We really only need a function `a -> (forall s. Reverse s a)`. This function is `auto` from the `Mode` class, for which `Reverse s a` has an instance. `auto` has the slightly wierd type `Mode t => Scalar t -> t` but `type Scalar (Reverse s a) = a`. Specialized for `Reverse` `auto` has the type

``````auto :: (Reifies s Tape, Num a) => a -> Reverse s a
``````

This allows us to convert our `Mat a`s into `Mat (Reverse s a)`s without messing around with conversions to and from `Rational`.

``````{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeFamilies #-}

diffTest :: forall a . (Fractional a, Ord a) => Mat a -> [Mat a] -> [a] -> [[a]]
diffTest m fs as0 = gradientDescent go as0
where
go :: forall t. (Scalar t ~ a, Mode t) => [t] -> t
go xs = eq3' (fmap auto m) xs (fmap (fmap auto) fs)
``````
• Great writeup. I just wanted to complain that this should be obvious from the `ad` documentation ... just to find it right there on github. Now I feel stupid :) – fho Apr 1 '15 at 16:40
• what does the `~` do in the signature of `go` ? – ocramz Aug 6 '15 at 17:06
• `~` is type equality. It says the `Scalar` of `t` must be the same type as the `a`s held in the original `Mat a`s. – Cirdec Aug 6 '15 at 17:47