7

Consider the expressions E1 = foldl op acc l and E2 = foldr op acc l.

What are some natural sufficient conditions for op, acc and/or l that guarantee the equivalence of E1and E2?

A naive example would be that if opis constant then both are equivalent.

I'm pretty sure there must be precise conditions involving commutativity and/or associativity of op, and/or finitude of l, and/or neutrality of acc.

7

If op is an associative operation, acc is a neutral element of op, and l is finite, then they are equivalent.

Indeed, the result of foldr is

(l1 `op` (l2 `op` ... (ln `op` acc)))

while that of foldl is

(((acc `op` l1) `op` l2) `op` ... ln)

To prove that they are equal, it suffices to simplify acc away, and reassociate.


Even if acc is not a neutral element, but acc still satisfies the weaker condition

forall x,  acc `op` x = x `op` acc

then, if op is associative and l is finite, we again get the desired equivalence.

To prove this, we can exploit the fact that acc commutes with everything, and "move" it from the tail position to the head one, exploiting associativity. E.g.

(l1 `op` (l2 `op` acc))
=
(l1 `op` (acc `op` l2))
=
((l1 `op` acc) `op` l2)
=
((acc `op` l1) `op` l2)

In the question it is mentioned the sufficient condition op = const k which is associative but has no neutral element. Still, any acc commutes with everything, so the "constant op" case is a subcase of the above sufficient condition.


Assuming op has a neutral element acc, if we assume

foldr op acc [a,b,c] = foldl op acc [a,b,c]      -- (*)

we derive

a `op` (b `op` c) = (a `op` b) `op` c

Hence, If (*) holds for all a,b,c, then op has to be associative. Associativity is then necessary and sufficient (when a neutral element exists).


If l is infinite, foldl always diverges no matter what op,acc are. If op is strict on its second argument, foldr also diverges (i.e., it returns bottom).

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  • 1
    According to the diagrams in this link the most inner operation always involves acc as a left/right operator respectively, so I think this might be mistaken. – Jsevillamol Nov 26 '17 at 12:21
  • @Jsevillamol Thanks. I was too fast to remove the neutral element requirement. Restored. – chi Nov 26 '17 at 12:26
  • Regarding the case where l is infinitve: if we take` op` which is strict on its second argument to be for example the list constructor : then the result is an infinite list that you can still use lazily. So I think that this argument is not sensitive to different kinds of $\bottom$ values, if that makes sense. – Jsevillamol Nov 26 '17 at 12:39
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    @Jsevillamol Note that the list constructor : is not strict in Haskell, in both arguments. E.g. seq (undefined : undefined) () will happily terminate. Infinite lists are also not considered bottom values. – chi Nov 26 '17 at 12:46
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    @Jsevillamol For instance, foldr (+) 0 [1..] is bottom. Instead, foldr (:) [] [1..] is [1..] which is not bottom. (Above, with "diverges" I mean the result is bottom). With foldl you always get a bottom value with an infinite list. You can only get an infinite value in trivial cases e.g. foldr op [1..] [], or when op itself produces (after finitely many applications) an infinite value. – chi Nov 26 '17 at 13:17

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