# How to apply higher order function to an effectful function in Haskell?

I have too functions:

``````higherOrderPure :: (a -> b) -> c
effectful :: Monad m => (a -> m b)
``````

I'd like to apply the first function to the second:

``````higherOrderPure `someOp` effectful :: Monad m => m c
``````

where

``````someOp :: Monad m => ((a -> b) -> c) -> (a -> m b) -> m c
``````

Example:

``````curve :: (Double -> Double) -> Dia Any
curve f = fromVertices \$ map p2 [(x, f x) | x <- [1..100]]

func :: Double -> Either String Double
func _ = Left "Parse error" -- in other cases this func can be a useful arithmetic computation as a Right value

someOp :: ((Double -> Double) -> Dia Any) -> (Double -> Either String Double) -> Either String (Dia Any)
someOp = ???

curve `someOp` func :: Either String (Dia Any)
``````
-
What is `map p2 (x, f x)` supposed to be doing? `map p2` implies that `p2` is a function, so `(x, f x)` must be a list, but it is clearly a tuple. I also doubt that the `Dia` type is just an alias for lists, since `curve f = [...]`, meaning `curve` returns a list. Can you update your question with a working example? It also might help to include the type signatures of `p2` and `fromVertices`. –  bheklilr Jun 10 at 13:20
Sorry, typo, after p2 a [ was missing –  PDani Jun 10 at 13:21
That makes it much easier to understand what's going on, thanks! –  bheklilr Jun 10 at 13:22
Which library are you using to do this? I'd like to browse its documentation to figure out if this problem is solvable in the way you want –  bheklilr Jun 10 at 13:36
projects.haskell.org/diagrams, but that's kind of irrelevant, the question is more like theoretical, the example is only for better understanding. –  PDani Jun 10 at 13:47

The type

``````Monad m => ((a -> b) -> c) -> (a -> m b) -> m c
``````

is not inhabited, i.e., there is no term `t` having that type (unless you exploit divergence, e.g. infinite recursion, `error`, `undefined`, etc.).

This means, unfortunately, that it is impossible to implement the operator `someOp`.

# Proof

To prove that it is impossible to construct such a `t`, we proceed by contradiction. Assume `t` exists with type

``````t :: Monad m => ((a -> b) -> c) -> (a -> m b) -> m c
``````

Now, specialize `c` to `(a -> b)`. We obtain

``````t :: Monad m => ((a -> b) -> a -> b) -> (a -> m b) -> m (a -> b)
``````

Hence

``````t id :: Monad m => (a -> m b) -> m (a -> b)
``````

Then, specialize the monad `m` to the continuation monad `(* -> r) -> r`

``````t id :: (a -> (b -> r) -> r) -> ((a -> b) -> r) -> r
``````

Further specialize `r` to `a`

``````t id :: (a -> (b -> a) -> a) -> ((a -> b) -> a) -> a
``````

So, we obtain

``````t id const :: ((a -> b) -> a) -> a
``````

Finally, by the Curry-Howard isomorphism, we deduce that the following is an intuitionistic tautology:

``````((A -> B) -> A) -> A
``````

But the above is the well-known Peirce's law, which is not provable in intuitionistic logic. Hence we obtain a contradiction.

# Conclusion

The above proves that `t` can not be implemented in a general way, i.e., working in any monad. In a specific monad this may still be possible.

-
`peirce k = k unsafeCoerce` :) –  András Kovács Jun 10 at 16:45
peirce = undefined someOp = undefined FunctionToSolveWorldProblems = undefined –  PyRulez Jun 10 at 17:36
Is it even possible to have a function of type `(a -> b) -> c`? You can have specialized versions of this type, but never this type itself, I would think: how can I write a function which, given a function between any two types you like, returns a value of any other third type you like? –  amalloy Jun 10 at 19:19
@amalloy Indeed, but `Monad m => ((a -> b) -> c) -> (a -> m b) -> m c` allows for specialisation. For the argument to be uninhabited, we would have to prevent specialisation by using a higher-rank type, e.g. `(forall a. b. c. (a -> b) -> c) -> etc`. –  duplode Jun 10 at 19:36
@amalloy The polymorphic type `(a -> b) -> c` is not inhabited. If it were, the logical proposition `(A -> B) -> C` would be an intuitionistic tautology, but it is not even a classical tautology. That is, if `A=B=True` and `C=False` then `(A -> B) -> C` is false. This proves that it is not possible to construct a term of said polymorphic type. Specific instances (e.g. `a=b=c=Int`) are inhabited, though. –  chi Jun 10 at 19:48

I think you can achieve what you want by writing a monadic version of `curve`:

``````curveM :: Monad m => (Double -> m Double) -> m (QDiagram B R2 Any)
curveM f = do
let xs = [1..100]
ys <- mapM f xs
let pts = map p2 \$ zip xs ys
return \$ fromVertices pts
``````

This can easily be written shorter, but it has the type you want. This is analogous to `map -> mapM` and `zipWith -> zipWithM`. The monadic versions of the functions have to be separated out into different implementations.

To test:

``````func1, func2 :: Double -> Either String Double
func1 x = if x < 1000 then Right x else Left "Too large"
func2 x = if x < 10   then Right x else Left "Too large"

> curveM func1
Right (_ :: QDiagram B R2 Any)
> curveM func2
Left "Too large"
``````
-