# Code Golf (sort of): a Functional Puzzle

Here's a puzzle: define some higher-order function `f` such that, using only `f` and parentheses, you can define the three higher-order functions `const`, `id` and `bothOn`.

Those three functions could be defined in a straightforward way and in the Haskell programming language as follows:

``````-- takes two arguments, ignores the second and returning the first"
const a _ = a

-- takes one argument returns it:
id a = a

-- takes three arguments: the first is applied to the third and the result of applying
-- the second to the third:
bothOn f g x = f x (g x)
``````

You're limited to your choice of programming language here of course (lisp or haskell would be fine choices even if you don't know either).

And those of you who know what I'm up to (you know who you are) should only submit answers they thought up themselves ;-)

EDIT: Forgot to mention, the answer with the definition for `f` with fewest characters wins. Also show how you defined the three functions in terms of `f`.

EDIT: Well look at me with egg on my face. It was only after posting this question and trying to implement some known solutions to this problem in haskell that I realized that a statically-typed language isn't particularly well-suited to the untyped lambda calculus.

The infinite type errors... I could not make them stop. But I would be really interested if any haskell type system gurus out there can make a working implementation.

So for those who are still wondering, I was trying to trick you into defining a single-combinator base: essentially, in my understanding, a single function that is sufficient to be a turing complete system.

The three functions you were asked to define with your function were taken from the SKI Combinator calculus, which is a combinator base consisting of only three combinators. So by defining a single combinator (function) which is capable of defining S and K (I can be derived from S and K) you can easily prove that you have a 1-combinator base.

Here is a paper that goes over the derivation of one of the several known single-base combinators. And here is an interesting pair of esoteric languages Iota and Jot which is built on a single combinator and consists of only two symbols.

I'm thinking they should ask me to write the problem for the ICFP contest next year...

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What do you define as "combined" for `bothOn`? Composed? –  Amber Jun 23 '10 at 0:09
Haha, this is far more challenging in Haskell than Lisp. Have fun getting anything to type check! –  C. A. McCann Jun 23 '10 at 0:54
Right. In Lisp you can just write the equivalent of an arity-overloaded function and define `(id a)` as `(f a)`, `(const a b)` as `(f a b)` and `(bothOn a b c)` as `(f a b c)`. In fact, Clojure has actual arity-overloaded functions: `(defn f ([a] a) ([a b] a) ([a b c] ((a c) (b c))))`. This could be my entry (upon removal of some spaces), but I'd much rather solve the typed version. :-) –  Michał Marczyk Jun 23 '10 at 1:08
@Michał Marczyk: I meant even without arity overloading--given the specification for the function, it can't possibly have a valid type without some sort of sneaky trick (I won't go into details, as that might spoil the puzzle). –  C. A. McCann Jun 23 '10 at 2:10
I'm not sure why this was closed. The problem was quite reasonable, well scoped (at least within Haskell), very interesting, and I for one would very much like to see an actual answer. –  Edward Kmett Jun 23 '10 at 4:39

... Iota?

## Python (72 chars)

``````    i=lambda x:x(lambda a:lambda b:lambda c:a(c)(b(c)))(lambda a:lambda b:a)
#  |         |         |         |         |         |         |         |
#  |    |    |    |    |    |    |    |    |    |    |    |    |    |    |
#  0    5   10   15   20   25   30   35   40   45   50   55   60   65   70

idFunc     = i(i)
constFunc  = i(i(i(i)))
bothOnFunc = i(i(i(i(i))))

assert idFunc('foo') == 'foo'
assert constFunc('foo')('bar') == 'foo'
assert bothOnFunc(lambda a:lambda b:a+b)(lambda p:p*p)(4) == 20
``````
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You win the non-prize as the only answer that didn't cheat or fail type-checking :) congratulations! –  jberryman Jun 23 '10 at 21:53

The spec does not require that these functions be as general as they can be, so here's my cheap take. (Use the `-XNoImplicitPrelude` command line option if you insist.)

``````f _ _ x=x
id=f()f
const=f()
bothOn=f
``````

``````> id () == ()
True
> const () () == ()
True
> bothOn const id () == ()
True
``````
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Well, aren't you clever... –  jberryman Jun 23 '10 at 22:02

A completely disappointing, but technically correct version ;)

``````{-# LANGUAGE FlexibleInstances, OverlappingInstances, UndecidableInstances #-}
class F a where
f :: a
instance F (a -> a) where
f a = a
instance F (a -> a -> a) where
f a _ = a
instance F ((a -> b -> c) -> (a -> b) -> a -> c) where
f f0 g x = f0 x (g x)

const :: a -> a -> a
const = f

id :: a -> a
id = f

bothOn :: (a -> b -> c) -> (a -> b) -> a -> c
bothOn = f
``````

A more satisfying version would be to build one out of the iota combinator

``````import Control.Applicative
k x y = x
s x y z = x z (y z)
iota x = x s k
-- iota x = x (<*>) pure
``````

but unfortunately I don't think you can get interesting programs built out of it or type restricted versions of it to typecheck.

If we flip it around a bit you can make some headway though:

``````f :: (((e -> a) -> (e -> a -> b) -> e -> b) -> (c -> f -> c) -> d) -> d
f x = flip (<*>) `x` pure

const :: a -> b -> a
const = f f

flippedBothOn :: (a -> b) -> (a -> b -> c) -> a -> c
flippedBothOn = f (f f)
``````
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I played around with an expanded version of the challenge which allowed arbitrary newtypes with wrapping and unwrapping as well, but didn't get very far... –  sclv Jun 23 '10 at 17:34
Thanks for the attempt. I completely failed to do any tests, or realize before posting that answering this problem in haskell would be difficult or impossible. I still would love to see if it could be done though –  jberryman Jun 23 '10 at 22:01

Does this qualify?

## JavaScript, 74 84 characters

``````function f(){x=arguments,l=x.length;[a,b,c]=x;return l==3&&a(c)(b(c))||a}
``````

``````function f() {
var x = arguments, length = x.length;
[first, second, third] = x;

return (length == 3 && first(third)(second(third))) || first;
}
``````

Uses destructuring assignment from JavaScript 1.7 to break apart arguments into a,b,c.

## JavaScript, 102 characters

Here's another version that defines all the three functions first. Although code-golf is usually more concerned with output than the internal workings of the code, but here goes a little bit bigger but more technically correct version that relies on the arity to determine which function to call:

``````function f()[x=arguments,function(a)a,function(a,_)a,function(g,h,x)g(x)(h(x))][x.length].apply('',x)
``````

``````function f() {
var id_ = function(a) a;
var const_ = function(a, _) a;
var bothOn_ = function(g, h, x) g(x)(h(x));

var functions = [id_, const_, bothOn_];
var functionIndex = arguments.length - 1;

return functions[functionIndex].apply(null, arguments);
}
``````
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I didn't realize `[a,b,c] = x` was valid syntax, thanks for that. –  Casey Chu Jun 23 '10 at 2:04
I have totally missed the point of the question :) will edit and add a new solution later –  Anurag Jun 23 '10 at 4:18

# Python (43 chars)

(cheating) (based on the JS solution)

``````    f=lambda a,b=0,*c:c and a(c[0],b(c[0]))or a
#  |         |         |         |         |
#  |    |    |    |    |    |    |    |    |
#  0    5   10   15   20   25   30   35   40

idFunc = f
constFunc = f
bothOnFunc = f

assert idFunc('foo') == 'foo'
assert constFunc('foo', 'bar') == 'foo'
assert bothOnFunc(lambda a,b: a+b,  lambda p: p*p,  4) == 20
``````
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## Mathematica 34 chars

``````f[x_,y_:0]=x;f[x_,y_,z_]=x[z,y[z]]

const = id = bothOn = f

{id[x]==x, const[x]==x, bothOn[x,y,z]==x[z,y[z]]}
{True,True,True}

In[52]:= bothOn[Plus,Sqrt,4]
Out[52]= 6
``````
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