I was wondering if Haskell keeps track of weather a function is a function composition, i.e would it be possible for me to define a function that does something similar to this?:
compositionSplit f.g = (f,g)
I was wondering if Haskell keeps track of weather a function is a function composition, i.e would it be possible for me to define a function that does something similar to this?:
compositionSplit f.g = (f,g)
No, it wouldn't be possible.
For example,
f1 = (+ 1) . (+ 1) :: Int -> Int
is the same function as
f2 = subtract 1 . (+ 3) :: Int -> Int
and referential transparency demands that equals can be substituted for equals, so if compositionSplit
were possible, it would
f1
and f2
, since that is the same function, yetcompositionSplit f1 = ((+ 1), (+1))
and compositionSplit f2 = (subtract 1, (+ 3))
would be required by the specification of compositionSplit
.f1
and f2
are the same function, they can't be distinguished by any function.
– Daniel Fischer
May 29 '13 at 23:53
x = y
then also f x = f y
. Observe that f1
and f2
are equal, therefore compositionSplit f1
should be equal to compositionSplit f2
, but it isn't!
– Vitus
May 29 '13 at 23:53
(\x.x+2)
and (\x.x+1+1)
are only extensionally equal functions. In a language with intensional equality we could distinguish between the two. (just carry around the source code, and simplification/compilation steps, together with the compiled function object in memory -- "provenance").
– Will Ness
May 30 '13 at 8:13
(.)
and id
to be a monoid, i.e. f.(g.h)
= (f.g).h
and id.f
= f
. You can't have referential transparency, this monoid and a decomposition operator. If you don't have this, you're not doing pure functional programming. It's not impossible, it's just not f.p..
– AndrewC
May 30 '13 at 17:18
It could. In strictly interpretational non-compiled implementation, you could represent functions as
data Function = F Source | Compo Function Function
and then you'd just define
compositionSplit (Compo f g) = Just (f,g)
compositionSplit _ = Nothing
Such implementation would treat function equality (w.r.t. referential transparency) as intensional, not extensional equality. As the language itself doesn't say anything about equality of functions AFAIK, this shouldn't affect anything (except maybe performance).
In compiled implementations this could be achieved too, e.g. by maintaining provenance for every object in memory.
AndrewC gives a winning counter-argument: for the two values a=f.(g.h)
and b=(f.g).h
, if we want to consider them as equal values - which we normally do, in Haskell - fst.unJust.deCompo
will produce two different results, breaking referential transparency. So it can't be part of pure FP paradigm. It'd have to return something which we could legitimately consider as being equal values too, in the two cases, and we wouldn't be able to take it apart, without breaking the purity. Maybe such a thing could exist in some impure monad, but that's not what OP asked for, sadly. :) So this answer is in error.