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I want to write a Haskell function which acts like flip but is far more general and can make any parameter of a function be the last parameter. For convenience, we use pull to represent it.

It is easy to write the following code:

Prelude> :t flip          --we just call this function a swap
flip :: (a -> b -> c) -> b -> a -> c
Prelude> :t (flip.)       --we just call this function a swap
(flip.) :: (a -> a1 -> b -> c) -> a -> b -> a1 -> c
Prelude> :t ((flip.).)    --we just call this function a swap
((flip.).) :: (a -> a1 -> a2 -> b -> c) -> a -> a1 -> b -> a2 -> c
Prelude> :t (((flip.).).) --we just call this function a swap
(((flip.).).)
  :: (a -> a1 -> a2 -> a3 -> b -> c) -> a -> a1 -> a2 -> b -> a3 -> c

And we find that with more (.) applied to flip, it can swap arbitrary adjacent pair of parameters. And with the above results we can write:

Prelude> :t flip
flip :: (a -> b -> c) -> b -> a -> c
Prelude> :t (flip.) . flip
(flip.) . flip :: (a1 -> a -> b -> c) -> a -> b -> a1 -> c
Prelude> :t ((flip.).) . (flip.) . flip
((flip.).) . (flip.) . flip
  :: (a2 -> a -> a1 -> b -> c) -> a -> a1 -> b -> a2 -> c
Prelude> :t (((flip.).).) . ((flip.).) . (flip.) . flip
(((flip.).).) . ((flip.).) . (flip.) . flip
  :: (a3 -> a -> a1 -> a2 -> b -> c) -> a -> a1 -> a2 -> b -> a3 -> c

We can find that with more swaps composed, it can pull an arbitrary parameter to the last place. So we can get rid of lambda expressions in many cases. But the above express is very bloated.

My main idea is to make a function pull to generalize the above functions. The pull acts roughly like bellow.

let f = undefined               --For convenience, we let f be undefined.

:t pull 0 (f::a->b->z)          --the type variable z is not a function type.
>pull 0 (f::a->b->z) :: b->a->z --pull is just like flip for 0 and a function of this type.
:t pull 0 (f::a->b->c->z)       --the type variable z is not a function type.
>pull 0 (f::a->b->c->z) :: b->c->a->z

:t pull 1 (f::a->b->c->z)       --the type variable z is not a function type.
>pull 1 (f::a->b->c->z) :: a->c->b->z
:t pull 1 (f::a->b->c->d->z)    --the type variable z is not a function type.
>pull 1 (f::a->b->c->d->z) :: a->c->d->b->z

:t pull 2 (f::a->b->c->d->z)    --the type variable z is not a function type.
>pull 2 (f::a->b->c->d->z) :: a->b->d->c->z
:t pull 2 (f::a->b->c->d->e->z) --the type variable z is not a function type.
>pull 2 (f::a->b->c->d->e->z) :: a->b->d->e->c->z

I tried many ways to do this. The naivest one is:

swap :: Word -> a -> a
swap 0 = flip
swap n = dot $ swap (n-1)

and ghc complained like bellow and I understand why:

-- Prelude> :reload
-- [1 of 1] Compiling Main             ( ModifyArbitrayParameterOfAFunction.hs, interpreted )
--
-- ModifyArbitrayParameterOfAFunction.hs:4:21:
--     Occurs check: cannot construct the infinite type: c0 = a1 -> c0
--     Expected type: (a1 -> c0) -> c0
--       Actual type: (a1 -> c0) -> a1 -> c0
--     In the return type of a call of `modify'
--     Probable cause: `modify' is applied to too few arguments
--     In the first argument of `(.)', namely `(modify (n - 1) modi)'
--     In the expression: (modify (n - 1) modi) . f1
--
-- ModifyArbitrayParameterOfAFunction.hs:4:42:
--     Occurs check: cannot construct the infinite type: c0 = a1 -> c0
--     Expected type: a1 -> a1 -> c0
--       Actual type: a1 -> c0
--     In the second argument of `(.)', namely `f1'
--     In the expression: (modify (n - 1) modi) . f1
--     In an equation for `modify':
--         modify n modi f1 = (modify (n - 1) modi) . f1
-- Failed, modules loaded: none.

Maybe my goal is just a wishful thinking, but considering Haskell's type system is even able to write lambda expressions, I dare to say there must be a way to do this.

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1  
I suppose it's possible, but definitely would require some mild olegery. –  Artyom Jun 17 '13 at 12:07
2  
Not possible in the way you have mentioned. Simply because the parameter value to pull (which is available) at runtime can't decide the type of pull (which is required at compile time) –  Ankur Jun 17 '13 at 12:17
    
But, I think pull can choose a proper type base on the parameter function, only if there is a way to identify the parameter function is a unary function, function of two variables or function of several variables –  TorosFanny Jun 17 '13 at 14:30
    
Maybe you could use Daniel Fridlender and Mia Indrika's pattern for n-ary functions - brics.dk/RS/98/38. Myself I'd just make an arity family of functions like the Prelude already has for zip, zip2, etc. –  stephen tetley Jun 17 '13 at 16:55

2 Answers 2

up vote 1 down vote accepted

As mentioned in the comments, you can't have a function to which you'd pass the arity of the function you want to flip. Parameters are computed at runtime, while you need the value at compile time so that you can determine the correct type.

Neither you can make it without passing it the arity somehow. For example a -> b -> c -> d could be viewed as a function of three arguments returning d, or as a function if two arguments returning c -> d.

Probably the easiest solution would be to define the functions explicitly, like flip2, flip3 etc. I know this isn't what you're looking for, but it's the most practical solution.

Another option would be to use Template Haskell. Then, the situation is different, because Template Haskell executes (I'd say "meta-") code at compile time. With TH you can create a function that takes a natural number and produces a TH expression that can be compiled into another module. The meta-function could be defined as

{-# LANGUAGE TemplateHaskell #-}
module GenFlipTH where

import Language.Haskell.TH

pull :: Int -> Q Exp
pull 0              = varE 'flip
pull n | n < 0      = fail "Negative arity"
       | otherwise  = [| fmap $(pull (n - 1)) . flip |]
-- Here we use the fact that `(->) r` is a functor.

and used in another module to generate the appropriate expression like

{-# LANGUAGE TemplateHaskell #-}
import GenFlipTH

flip3 :: (a -> b3 -> b2 -> b1 -> b -> c) -> (b3 -> b2 -> b1 -> b -> a -> c)
flip3 = $( pull 3 )

This is probably closes to your requirements I can get - you determine the function by a number and get compile-time guarantees that it's created and used correctly.

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By the way, can we define a class which is the complement of an existing class. If that's possible I can tell whether a variable is a function or not or even the function's number of parameters. –  TorosFanny Jun 26 '13 at 2:27
    
@TorosFanny What do you mean by the complement of a class? I believe you can't tell the number of parameters automatically. Like, does a -> b -> c -> d have one, two or three parameters? –  Petr Pudlák Jun 26 '13 at 6:49
    
Currently, I could only tell the number of parameters automatically for functions whoes "final result" is of types I defined specially as zero. see:stackoverflow.com/questions/17318107/… –  TorosFanny Jun 26 '13 at 10:52
    
@TorosFanny I'd say not using TH. In TH you have access to the term that defines a function, but not to its type. –  Petr Pudlák Jun 26 '13 at 12:02

You can't do this as a normal function, because the type of the function will vary based on inputs. You can do it with the ad-hoc polymorphism introduced by typeclasses and functional dependencies. However, even then you will need a host of extensions to allow something like Oleg's IsFunction (see: http://okmij.org/ftp/Haskell/isFunction.lhs). That's the missing piece that lets you identify if you've reached the base case of the typeclass recursion.

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