op is an associative operation,
acc is a neutral element of
l is finite, then they are equivalent.
Indeed, the result of
(l1 `op` (l2 `op` ... (ln `op` acc)))
while that of
(((acc `op` l1) `op` l2) `op` ... ln)
To prove that they are equal, it suffices to simplify
acc away, and reassociate.
acc is not a neutral element, but
acc still satisfies the weaker condition
forall x, acc `op` x = x `op` acc
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.
op has a neutral element
acc, if we assume
foldr op acc [a,b,c] = foldl op acc [a,b,c] -- (*)
a `op` (b `op` c) = (a `op` b) `op` c
(*) holds for all
op has to be associative. Associativity is then necessary and sufficient (when a neutral element exists).
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).