The right fold can start producing immediately if the combining function is lazy in its second argument. A simplistic example:
foldr1 (++) ["one", "two", "three", ...]
~> "one" ++ foldr1 (++) ["two", "three", ...]
and the first part of the result is immediately accessible without further evaluating the second argument of
(++). That needs only be evaluated when the first part is consumed. Often, the first part can then already be garbage-collected.
In the example with
f = flip const as the combining function, we have a different situation, that is strict(1) in its second argument, but doesn't need to evaluate it at all. And it ignores its first. That is also good for right folds. Here it goes
foldr1 f [x1, x2, x3, ... ]
~> f x1 (foldr1 f [x2, x3, ... ])
and now the outermost
f can immediately evaluated
~> foldr1 f [x2, x3, ... ]
~> f x2 (foldr1 f [x3, ... ])
~> foldr1 f [x3, ... ]
and at each step, the outermost
f can always be immediately evaluated (completely), and one list element thrown away.
If the list is given by a generator that can create it in constant space when sequentially consumed,
last = foldr1 (flip const)
can run in constant space.
With the left fold, things are different. Since that is tail-recursive
foldl1 f (x:y:zs) = foldl f x (y:zs) = foldl f (f x y) zs
it cannot return anything before the fold has reached the end of the list. In particular, a left fold can never terminate on an infinite list.
Now, looking at our case
f = flip const, we find
foldl1 f [x1, x2, x3, x4, ...]
~> foldl f x1 [x2, x3, x4, ... ]
~> foldl f (f x1 x2) [x3, x4, ... ]
~> foldl f (f (f x1 x2) x3) [x4, ... ]
Of course it would be possible to immediately evaluate
f x1 x2 to
x2, and then
f x2 x3 = x3, but that is only possible for this special
foldl is a general higher order function, it cannot evaluate the intermediate results before they are needed, since it is possible that the intermediate results never are needed - and in fact, they are never needed here, at the end of the list, one gets an expression
f (f (f (f ...y3) y2) y1) y0
and then the outermost
f can be evaluated without looking at the huge thunk of nested
fs that builds the first argument.
foldl1) cannot know that it would have been far more efficient to evaluate the intermediate results immediately.
The strict left folds,
foldl1' do that, they evaluate the intermediate results to weak head normal form (to the outermost value constructor or lambda), and
last = foldl1' (flip const)
would also be very efficient.
But, since the intermediate results are evaluated further than with
foldr, they would be a little less efficient, and, importantly, if any list element is
foldl1' version would return
foldl1' f [x1, ⊥, x3, x4]
~> foldl' f x1 [⊥, x3, x4]
~> case f x1 ⊥ of
pattern -- that causes ⊥
foldr1 version has no problem with that, since it doesn't inspect the list elements or intermediate results at all.
f is strict in its second argument means that
f x ⊥ = ⊥
f simply returns its second argument, that is evidently the case.