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The Composition Applicative Law is as follows:

pure (.) <*> u <*> v <*> w = u <*> (v <*> w)

Here's my attempt at proving the Composition law for the ((->) r) type:

RHS:

u <*> (v <*> w)
u <*> ( \y -> v y (w y) )
\x -> u x ( (\y -> v y (w y)) x )
\x -> u x ( v x (w x)) -- (A)

LHS:

pure (.) <*> u <*> v <*> w
const (.) <*> u <*> v <*> w
(\f -> const (.) f (u f)) <*> v <*> w
(\f -> (.) (u f)) <*> v <*> w
(\g -> (\f -> (.) (u f)) g (v g)) <*> w
\x -> (\g -> (\f -> (.) (u f)) g (v g)) x (w x)
-- Expanding labmda by applying to x
\x -> ((\f -> (.) (u f)) x (v x)) (w x)
\x -> (( (.) (u x)) (v x)) (w x)

\x -> ((u x) . (v x)) (w x) -- (B)

I don't think (A) & (B) are equivalent, so where did I make a mistake? I would appreciate any help or suggestions.

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  • This question is related to stackoverflow.com/questions/33829415/…. However, I couldn't post the code in this question directly as a comment, so I decided to add a new follow-up question instead
    – Umair
    Dec 30, 2015 at 23:18
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    Substitute in the definition (f . g) x = f (g x) for the composition in the last line of the LHS... and you're done! Dec 30, 2015 at 23:25
  • Le sigh. Missed something really simple. Could you post your comment as an answer so that I can accept it?
    – Umair
    Dec 30, 2015 at 23:27
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    For a friendlier presentation of the Applicative laws, see this blog post by Edward Yang. Also, you might consider jumping ahead and proving the monad laws instead.
    – dfeuer
    Dec 31, 2015 at 2:27

1 Answer 1

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You're almost there. You just need to use the definition of (.), which is

(f . g) x = f (g x)

After substituting that definition in the last line of your LHS calculation, you should have two obviously equal lambdas.

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