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Many functions can be reduced to point free form - but is this true for all of them?

E.g. I don't see how it could be done for:

apply2 f x = f x x 
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Find and install GOA a.k.a. "GHC On Acid", then from within GHC type :pl \f x -> f x x (pl stands for "point-less", which is a less reverent term for point-free). –  n.m. Nov 1 '12 at 20:10
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related: stackoverflow.com/questions/9169046/… Your apply2 is what's known as W combinator, _W = join -- _W f x = f x x = CSI = SS(KI) = SS(SK). C is flip; I is id; S is (<*>), K is const. Check it out. –  Will Ness Nov 2 '12 at 15:23
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Control.Applicative> (<*> id) (,) 4 ==> (4,4). –  Will Ness Nov 2 '12 at 15:45
    
The Theory of Concatenative Combinators offers an alternate combinatorial basis, in which your function might be expressed as [dup] dip i or dup dig2 i, depending on order of arguments. In either case, dup duplicates the value and i applies the function to it. –  Jon Purdy Oct 31 '13 at 7:00
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3 Answers

up vote 9 down vote accepted

Logical combinators (i.e. the S, K, I combinators) are essentially point-free forms of functions, and the lambda-calculus is equivalent to combinatory logic, so I think this suggests that the answer is yes.

The combinator for your apply2 function is (if I am reading things correctly):

((S((S(KS))K))(K((S((SK)K))((SK)K))))

also known as the "Lark", from Raymond Smullyan's Combinatory Birds page.

(edit-in:) Turns out1 the above is equivalent to \f x -> f (x x). According to the comments by "@gereeter" here below it is indeed known as the "Lark", whereas the function \f x -> f x x requested in the question is the "Warbler" from the aforementioned book (a.k.a. the "W" combinator), W f x = S(S(K(S(KS)K))S)(KK)SI f x = S(S(KB)S)(KK)SI f x = CSI f x = SfIx = f x x.


1 here:

((S((S(KS))K))(K((S((SK)K))((SK)K)))) f x =
  S( S(KS) K) (K( S( SK K) ( SK K)))  f x =   -- SKK    == I
  S (S(KS) K) (K( S  I       I    ))  f x =   -- S(KS)K == B
  S B         (K( S  I       I    ))  f x =
  Bf (K(SII)f) x = Bf (SII) x = f (SII x) = f (x x)
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For a start, not all functions are curried; tuples are magic-encoded! You can express them without the syntax, but there aren't functions to do this for large tuples. Also, Haskell is not purely the lambda calculus! –  AndrewC Nov 1 '12 at 20:25
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@AndrewC While it's true that data is a bit outside the realm of the lambda calculus, it's not that far out: there are various encodings of data as functions that can simulate sums, products, and recursive types. –  Daniel Wagner Nov 1 '12 at 21:21
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@DanielWagner Obviously. However, the encoding of the tuples is built in and not available other than via the given syntax. Hence I'd happily withdraw my criticism if this answer said "...suggests the answer is yes, for curried functions" or similar restriction of scope. –  AndrewC Nov 2 '12 at 0:55
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That's why I qualified my answer because I wasn't sure if I was interpreting the lambda expressions correctly. –  user5402 Nov 2 '12 at 16:24
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@Ingo BW this appears in the link "(a.k.a. the "W" combinator)" in the answer. It gives SS(SK) also. All seem to be typeable, using <*> for S. –  Will Ness Oct 31 '13 at 9:22
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S-K basis

As already mentioned, with a proper fixed set of combinators, any lambda term can be converted into a form that uses only those combinators and function application - no lambda abstraction (hence no variables). The most well known set of combinators is S and K. Se Combinatory Logic/Completeness of the S-K basis for the description of the procedure. The combinators are defined as

K x y    = x
S x y z  = (x z) (y z)

Sometimes the identity combinator I is included, but it's redundant as I = S K K.

A single combinator basis

Interestingly you can do that even with a single combinator. The Iota language uses

U f = (f S) K

and it can be shown that

I = (UU)
K = (U(U(UU)))
S = (U(U(U(UU))))

So we can convert any lambda term into a binary tree with no other information than it's shape (all the leaves contain U and and the nodes represent function application).

A more efficient basis S, K, I, B, C

However, if we want to be a bit efficient and get a reasonably sized conversion, it's helpful to use I and to introduce two more redundant combinators, which are called B and C:

C f x y  = f y x
B f g x  = f (g x)

Here C reverses the order of arguments of f and B is function composition.

This addtion reduces the length of the output significantly.

These combinators in Haskell

Actually Haskell already contains all those standard combinators in some form. In particular:

I = id
K = const
  = pure :: a -> (r -> a)
S = (<*>) :: (r -> a -> b) -> (r -> a) -> (r -> b)
B = (.)
  = (<$>) :: (a -> b) -> (r -> a) -> (r -> b)
C = flip
  = \k x -> k <*> pure x

where pure, <*> and <$> are functions from the Applicative functors type class which we here specialize for the reader monad (->) r.

So in your case, we could write

apply2 = (<*>) `flip` id

Why the reader monad?

In the process of abstraction elimination we try to convert a term of the form λx -> M :: r -> a (where r is the type of x and a is the type of M) into a form without x. We do this by recursively processing M and we subsequently convert each its sub-term of type b (possibly containing x) into a function of type r -> b (not containing x), and then we combine these sub-terms together. And that's just what the reader monad is designed for: To combine functions of type r -> something together.

For more details see The Monad Reader, Issue 17: The Reader Monad and Abstraction Elimination.

How about data structures?

For constructing data structures we simply use their constructors, there is no problem here.

For deconstructing them, we need some way to get rid of pattern matching. This is something a compiler has to do when compiling a functional program. Such a procedure is described in The Implementation of Functional Programming Languages Chapter 5: Efficient compilation of pattern matching. The idea is that for each data type we have one case function that describes how to deconstruct (fold) the data type. For example, for lists it foldr, for Either its either, and let's say for 4-tuples it'd be

caseTuple4 :: (a -> b -> c -> d -> r) -> (a,b,c,d) -> r
caseTuple4 f (a,b,c,d) = f a b c d

etc. So for each data type we add its constructors, its deconstructing case function, and compile patterns into this function.

As an example, let's express

map :: (a -> b) -> [a] -> [b]
map f []        = []   
map f (x : xs)  = f x : map f xs

this can be expressed using foldr:

map f = foldr (\x xs -> f x : xs) []

and then converted using the combinators we discussed earlier:

map = (foldr . ((.) (:))) `flip` []

You can verify that it indeed does what we want.

See also System F data structures which describes how data structures can be encoded directly as functions if we enable higher rank types.

Conclusion

Yes, we can construct a fixed set of combinators and then convert any function into point-free style that uses only these combinators and function application.

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To my mind, the only real issue here is if data deconstructors are considered part of the set of "functions", i.e. is a data deconstructor a valid choice for "any function" as intended by the question? The answer follows pretty quickly from that. –  John L Nov 3 '12 at 2:01
    
@JohnL btw, fst = uncurry const and snd = uncurry (const id). But there isn't such stuff for fst3 and fstN - because there isn't uncurry3 or uncurryN. But why shouldn't there be? (I still contend that it is what it means to introduce a primitive type to a language: provide primitive means of selection from it. Or else it is unusable.) I like this answer! :) –  Will Ness Nov 3 '12 at 7:04
    
@WillNess that only works because uncurry itself uses fst and snd, both of which are point-ful (at least in ghc). The problem is that data introduces a new type, and a new primitive means of extracting data from it, but that data extraction mechanism is not the case function as described above. So we have to write the case function ourselves, in a pointful form. I suppose you could say I'm disagreeing on a technicality, however as Haskell currently requires that we construct the "fixed set of combinators" manually in a pointful form, we cannot write every function pointfree. –  John L Nov 5 '12 at 3:54
    
@JohnL that's just coincidental. It could have been defined the other way around just as well. Moreover, you make my point for me - apparently fst and snd are pointful but are widely used in pointfree rewrites nevertheless! Of course you're absolutely right if we limit our base to what comes pre-built in the "Real" Haskell; I already agreed on that somewhere else on this page (and I used your example of data in that argument). :) I see it as just a matter of convention - or personal choice. And for me, choosing otherwise (as e.g. in this answer) makes perfect sense too. –  Will Ness Nov 5 '12 at 8:00
    
Just an idea, I've never used generics but perhaps could this be a way how to fold arbitrary data structures without having a separate folding function for each data type? –  Petr Pudlák Nov 5 '12 at 19:49
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There are a lot of functions that look like they might not be, but are expressible in a point free style, but to get one that isn't, you could quickly define one that works with extremely large tuples where there aren't any standard functions.

I think this sort of thing is less likely to be expressible point-free, not because of the complexity, but because there aren't many functions of tuples this size:

weird (a,b,c,d,e,f,g,h,i,j) = (a<*>b,c++d,e^f+a,g ()-h 4+e,j <*> take f i)

Your example:

apply2 :: (b -> b -> a) -> (b -> a)
apply2 = join

It's join in the reader monad ((->) b)

join :: Monad m => m (m a) -> m a

so in this case

join :: ((->) b) ((->) b a) -> ((->) b) a
join :: ((->) b) (b -> a) -> (b -> a)
join :: (b -> (b -> a)) -> (b -> a)
join :: (b -> b -> a) -> (b -> a)

Many more functions than we expect have point-free versions, but some point-free expressions are a complete mess. Sometimes it's better to be explicit than terse.

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This doesn't address the OP's underlying question, which is can any function be reduced to a point-free form...you've just debunked the example the OP thought might not. –  NominSim Nov 1 '12 at 19:48
    
@NominSim you said that as I was editing to answer the general question. –  AndrewC Nov 1 '12 at 20:14
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Perhaps someone can try running :pl in GOA on your example? A difficult example without (an obvious) point-free rep is not a proof! –  Andy Hayden Nov 1 '12 at 20:25
    
moreObvious (a,b,c,d,e,f,g,h,i,j,k,l,m,n,o) = (d,e,f,a,g,b,n,o,m,f,e,g,a,a,c,n). My point is there aren't functions that deal with tuples that length to go point-free with. –  AndrewC Nov 1 '12 at 20:28
    
I'm not so sure, the point-less function might exist but be incredibly long/more complex... perhaps you can build up to that function from smaller functions. Certainly it's not obvious either way (and needs a proof). –  Andy Hayden Nov 1 '12 at 21:24
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