First some `imports`

,

```
import Control.Applicative
import Data.Traversable as T
import Data.Foldable as F
import Data.Monoid
```

Say I have a functor holding a pair of values,

```
data Fret a = Fret a a deriving (Show)
instance Functor Fret where fmap f (Fret a b) = Fret (f a) (f b)
instance Applicative Fret where
pure a = Fret a a
Fret aa ab <*> Fret ba bb = Fret (aa ba) (ab bb)
instance Monoid a => Monoid (Fret a) where
mempty = Fret mempty mempty
a `mappend` b = mappend <$> a <*> b
```

I have a large list of these,

```
frets = replicate 10000000 (Fret 1 2)
```

over which I want to compute a, e.g., an average,

```
data Average a = Average !Int !a deriving (Read, Show)
instance Num a => Monoid (Average a) where
mempty = Average 0 0
Average n a `mappend` Average m b = Average (n+m) (a+b)
runAverage :: Fractional a => Average a -> a
runAverage (Average n a) = a / fromIntegral n
average = Average 1
```

Here are a few potential implementations of this,

```
average1 = runAverage <$> foldMap (fmap average) frets
average2 = pure (runAverage . mconcat) <*> T.sequenceA (map (pure (Average 1) <*>) frets)
```

Unfortunately, all of these result in a stack overflow.

Thinking that the problem might be excessive laziness in `Foldable.foldMap`

, I tried implementing a stricter variant,

```
foldMap' :: (F.Foldable f, Monoid m) => (a -> m) -> f a -> m
foldMap' f = F.foldl' (\m a->mappend m $! f a) mempty
average3 = runAverage <$> foldMap' (fmap average) frets
```

Unfortunately, this too overflows.

How can one accomplish this without compromise the clean structure of the approach?

## Update

If I make the fields of `Fret`

strict, things appear to work as expected. Checking to see if this works in the larger application.