Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I was playing around with functors, and I noticed something interesting:

Trivially, id can be instantiated at the type (a -> b) -> a -> b.

With the list functor we have fmap :: (a -> b) -> [a] -> [b], which is the same as map.

In the case of the ((->) r) functor (from Control.Monad.Instances), fmap is function composition, so we can instantiate fmap fmap fmap :: (a -> b) -> [[a]] -> [[b]], which is equivalent to (map . map).

Interestingly, fmap eight times gives us (map . map . map)!

So we have

0: id = id
1: fmap = map
3: fmap fmap fmap = (map . map)
8: fmap fmap fmap fmap fmap fmap fmap fmap = (map . map . map)

Does this pattern continue? Why/why not? Is there a formula for how many fmaps I need to map a function over an n-times nested list?

I tried writing a test script to search for a solution to the n = 4 case, but GHC starts eating too much memory at around 40 fmaps.

share|improve this question
2  
It degenerates pretty quickly into a cycle or something like it, but I've forgotten the exact formula. (Incidentally, lambdabot actually defines (.) as fmap.) –  ehird Jan 5 '12 at 3:01
    
@ehird: I think you're right. It seems like fmap n = 4k times (for n at least 8) gives (map . map . map). I'm still curious about why this happens, though. Especially because the instances change. At n = 8 it's (.) (.) (.) (.) (.) map map map, while for n = 12 it's (.) (.) (.) (.) (.) (.) (.) (.) map (.) map map. –  hammar Jan 5 '12 at 3:20
add comment

1 Answer 1

I can't explain why, but here's the proof of the cycle:

Assume k >= 2 and fmap^(4k) :: (a -> b) -> F1 F2 F3 a -> F1 F2 F3 b, where Fx stands for an unknown/arbitrary Functor. fmap^n stands for fmap applied to n-1 fmaps, not n-fold iteration. The induction's start can be verified by hand or querying ghci.

fmap^(4k+1) = fmap^(4k) fmap
fmap :: (x -> y) -> F4 x -> F4 y

unification with a -> b yields a = x -> y, b = F4 x -> F4 y, so

fmap^(4k+1) :: F1 F2 F3 (x -> y) -> F1 F2 F3 (F4 x -> F4 y)

Now, for fmap^(4k+2) we must unify F1 F2 F3 (x -> y) with (a -> b) -> F5 a -> F5 b.
Thus F1 = (->) (a -> b) and F2 F3 (x -> y) must be unified with F5 a -> F5 b.
Hence F2 = (->) (F5 a) and F3 (x -> y) = F5 b, i.e. F5 = F3 and b = x -> y. The result is

fmap^(4k+2) :: F1 F2 F3 (F4 x -> F4 y)
             = (a -> (x -> y)) -> F3 a -> F3 (F4 x -> F4 y)

For fmap^(4k+3), we must unify a -> (x -> y) with (m -> n) -> F6 m -> F6 n), giving a = m -> n,
x = F6 m and y = F6 n, so

fmap^(4k+3) :: F3 a -> F3 (F4 x -> F4 y)
             = F3 (m -> n) -> F3 (F4 F6 m -> F4 F6 n)

Finally, we must unify F3 (m -> n) with (a -> b) -> F7 a -> F7 b, so F3 = (->) (a -> b), m = F7 a and n = F7 b, therefore

fmap^(4k+4) :: F3 (F4 F6 m -> F4 F6 n)
             = (a -> b) -> (F4 F6 F7 a -> F4 F6 F7 b)

and the cycle is complete. Of course the result follows from querying ghci, but maybe the derivation sheds some light on how it works.

share|improve this answer
6  
+1, nice derivation! –  ehird Jan 5 '12 at 5:28
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.