Notice that you can chain any number of `<*>`

, to get a function of the form

```
f (a0 -> .. -> an) -> (f a0 -> .. -> f an)
```

If we have the type `a0 -> .. -> an`

and `f a0 -> .. -> f an`

, we can compute `f`

from this. We can encode this relation, and the most general type, as follows

```
class Lift a f b | a b -> f where
lift' :: f a -> b
```

As you may expect, the "recursive case" instance will simply apply `<*>`

once, then recurse:

```
instance (a ~ a', f' ~ f, Lift as f rs, Applicative f)
=> Lift (a -> as) f (f' a' -> rs) where
lift' f a = lift' $ f <*> a
```

The base case is when there is no more function. Since you can't actually assert "`a`

is not a function type", this relies on overlapping instances:

```
instance (f a ~ b) => Lift a f b where
lift' = id
```

Because of GHCs instance selection rules, the recursive case will always be selected, if possible.

Then the function you want is `lift' . pure`

:

```
lift :: (Lift a f b, Applicative f) => a -> b
lift x = lift' (pure x)
```

This is where the functional dependency on `Lift`

becomes very important. Since `f`

is mentioned only in the context, this function would be ill-typed unless we can determine what `f`

is knowing only `a`

and `b`

(which do appear in the right hand side of `=>`

).

This requires several extensions:

```
{-# LANGUAGE
OverlappingInstances
, MultiParamTypeClasses
, UndecidableInstances
, FunctionalDependencies
, ScopedTypeVariables
, TypeFamilies
, FlexibleInstances
#-}
```

and, as usual with variadic functions in Haskell, normally the only way to select an instance is to give an explicit type signature.

```
lift (\x y z -> x * y + z) readLn readLn readLn :: IO Int
```

The way I have written it, GHC will happily accept `lift`

which is polymorphic in the arguments to `f`

(but not `f`

itself).

```
lift (+) [1..5] [3..5] :: (Enum a, Num a) => [a]
```

Sometimes the context is sufficient to infer the correct type. Note that the argument type is again polymorphic.

```
main = lift (\x y z -> x * y + z) readLn readLn readLn >>= print
```

As of GHC >= 7.10, `OverlappingInstances`

has been deprecated and the compiler will issue a warning. It will likely be removed in some later version. This can be fixed by removing `OverlappingInstances`

from the `{-# LANGUAGE .. #-}`

pragma and changing the 2nd instance to

```
instance {-# OVERLAPS #-} (f a ~ b) => Lift a f b where
```

to? I see`<*>`

in the code, but I don't see any mention of`Applicative`

in the type signatures... Either way, I suspect the`Lift a`

instance is going to be a problem, since it overlaps with every other possible instance (including`Lift (a -> r)`

).`lift (pure (+)) (Just 1) (Just 2)`

- here,`(pure (+))`

has a different type than`Just 1`

, but the structure provided is hardcoded for a single type`Integer`

... I also need a way to encode an instance for "any type that is not a function", as sort of a termination condition for the type unrolling.