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).