3

I'm trying to build a Haskell function that does basically the same thing as Prelude's product. Unlike that function, however, it should have these two properties:

  1. It should operate in constant space (ignoring the fact that some numeric types like Integer aren't). For example, I want myProduct (replicate 100000000 1) to eventually return 1, unlike Prelude's product which uses up all of my RAM and then gives *** Exception: stack overflow.
  2. It should short-circuit when it encounters a 0. For example, I want myProduct (0:undefined) to return 0, unlike Prelude's product which gives *** Exception: Prelude.undefined.

Here's what I've come up with so far:

myProduct :: (Eq n, Num n) => [n] -> n
myProduct = go 1
  where go acc (x:xs) = if x == 0 then 0 else acc `seq` go (acc * x) xs
        go acc []     = acc

That works exactly how I want it to for lists, but I'd like to generalize it to have type (Foldable t, Eq n, Num n) => t n -> n. Is it possible to do this with any of the folds? If I just use foldr, then it will short-circuit but won't be constant-space, and if I just use foldl', then it will be constant-space but won't short-circuit.

  • Just an aside: product doesn't stack overflow in a compiled program. – Daniel Wagner Mar 14 at 20:19
2

You might be looking for foldM. Instantiate it with m = Either b and you get short circuiting behavior (or Maybe, depends if you have many possible early exit values, or one known in advance).

foldM :: (Foldable t, Monad m) => (b -> a -> m b) -> b -> t a -> m b

I recall discussions whether there should be foldM', but IIRC GHC does the right thing most of the time.

import Control.Monad
import Data.Maybe

myProduct :: (Foldable t, Eq n, Num n) => t n -> n
myProduct = fromMaybe 0 . foldM go 1
  where go acc x = if x == 0 then Nothing else Just $! acc * x
  • Something cool I just noticed: if you take this answer, inline the definition of foldM, and simplify, the result is the same as the final result in Daniel Wagner's answer. – Joseph Sible 2 days ago
3

If you spell your function slightly differently, it's more obvious how to turn it into a foldr. Namely:

myProduct :: (Eq n, Num n) => [n] -> n
myProduct = flip go 1 where
    go (x:xs) = if x == 0 then \acc -> 0 else \acc -> acc `seq` go xs (acc * x)
    go [] = \acc -> acc

Now go has got that foldr flavor, and we can just fill in the holes.

myProduct :: (Foldable t, Eq n, Num n) => t n -> n
myProduct = flip go 1 where
    go = foldr
        (\x f -> if x == 0 then \acc -> 0 else \acc -> acc `seq` f (acc * x))
        (\acc -> acc)

Hopefully you can see where each of those pieces came from in the previous explicit-recursion style and how mechanical the transformation is. Then I'd make a few aesthetic tweaks:

myProduct :: (Foldable t, Eq n, Num n) => t n -> n
myProduct xs = foldr step id xs 1 where
    step 0 f acc = 0
    step x f acc = f $! acc * x

And we're all done! A bit of quick testing in ghci reveals that it still short-circuits on 0 as required and uses constant space.

  • I've seen the pattern of "foldr to build a function that you then immediately call" before, but this is the first time it's been clear exactly how/why it works. Thanks! – Joseph Sible Mar 14 at 21:57

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.