# Why does this polyvariadic function require type annotation?

Here’s a simple polyvariadic function, modelled after `Text.Printf.printf`:

``````{-# LANGUAGE FlexibleInstances #-}

sumOf :: SumType r => r
sumOf = sum' []

class SumType t where
sum' :: [Integer] -> t

instance SumType (IO a) where
sum' args = print (sum args) >> return undefined

instance (SumArg a, SumType r) => SumType (a -> r) where
sum' args = \a -> sum' (toSumArg a : args)

class SumArg a where
toSumArg :: a -> Integer

instance SumArg Integer where
toSumArg = id
``````

It works fine in ghci without any type annotations:

``````ghci> sumOf 1 2 3
6
``````

However, when I remove the `SumArg a` constraint…

``````instance SumType r => SumType (Integer -> r) where
sum' args = \a -> sum' (toSumArg a : args)
``````

…it fails:

``````ghci> sumOf 1 2 3

<interactive>:903:7:
No instance for (Num a0) arising from the literal `3'
The type variable `a0' is ambiguous
Possible fix: add a type signature that fixes these type variable(s)
Note: there are several potential instances:
instance Num Double -- Defined in `GHC.Float'
instance Num Float -- Defined in `GHC.Float'
instance Integral a => Num (GHC.Real.Ratio a)
...plus 14 others
In the third argument of `sumOf', namely `3'
In the expression: sumOf 1 2 3
In an equation for `it': it = sumOf 1 2 3
``````

How come?

(To be honest, I’m more confused about the fact that the first version doesn’t need type annotations on its arguments.)

-
The first version doesn't need type annotations because of extended defaulting. – Daniel Wagner Oct 2 '13 at 5:29

That is because `1` has type `Num n => n`. So when looking for a matching instance for `sumOf 1` it won't match `Integer -> r`. But `a -> r` always matches, so it finds a match in the first case, and in the end, `a` defaults to `Integer`. So I would expect that this works, where `a ~ Integer` forces `a` to become `Integer`:
``````instance (a ~ Integer, SumType r) => SumType (a -> r) where