# How do I break out of a pure loop in Haskell without hand-written recursion?

I want to write a function that goes through a list updating an accumulator until that accumulator reaches a certain condition or I get to the end of the list. For example, a product function that stops as soon as its accumulator reaches zero.

I know how to code it by writing the recursion by hand:

``````{-# LANGUAGE BangPatterns #-}

prod :: [Integer] -> Integer
prod xs =
go 1 xs
where
go 0   _       = 0
go !acc []     = acc
go !acc (x:xs) = go (acc * x) xs
``````

but is there a way to code this using folds and other higher order functions?

One thing that comes to mind is defining

``````mult 0 _ = 0
mult x y = x * y
``````

and then using foldl'. However, this doesn't break out early so its a bit wasteful of performance.

We can't use foldr since it goes through the list in the wrong order and its way of "breaking out early" is by looking at the elements of the list instead of looking at the accumulator (this would have mattered if the accumulator had a different type than the list elements).

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You could use `Monoids` and `mconcat` –  viorior Jan 20 '14 at 16:08
@viorior: That doesn't work in the general case where the accumulator and list elements have different types. –  hugomg Jan 20 '14 at 16:17
You can use `foldr` for this example, because `foldr` is non-strict, as is your `mult` operator, so `foldr1 mult \$ [1,2] ++ [0..]` gives you `0` very quickly. Perhaps you'd be better off with an example involving addition where you stop as soon as the accumulator's zero, so you can't tell from the data that it will be: you want to ask for `mult _ 0 = 0` not the other way round if you want it to short circuit on the accumulator, as `foldr :: (a -> b -> b) -> b -> [a] -> b` - the second argument is the accumulator. –  enough rep to comment Jan 20 '14 at 17:43
@DavidYoung: In my real problem the only way is to look at the accumulator because the function is not commutative and assoociative like `*` is. I guess I shouldnt have chosen "product" as an example. –  hugomg Jan 20 '14 at 21:59
BTW you don't need the bang pattern `!acc` because you pattern match on it against `0`. This will force it, on its own. –  Will Ness Jan 21 '14 at 12:47

One simple way is to do the computation in a monad that allows to escape early, such as `Either` or `Maybe`:

``````{-# LANGUAGE BangPatterns #-}
import Data.Functor ((<\$))
import Data.Maybe (fromMaybe)

prod :: [Integer] -> Integer
prod = fromMaybe 0 . prodM

-- The type could be generalized to any MonadPlus Integer
prodM :: [Integer] -> Maybe Integer
prodM = foldM (\ !acc x -> (acc * x) <\$ guard (acc /= 0)) 1
``````

At each step of the computation we check if the accumulator is nonzero. And if it's zero, `guard` invokes `mplus`, which exits the computation immediately. For example the following exits immediately:

``````> prod ([1..5] ++ [0..])
0
``````
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It seems that `scanl` is the simplest list combinator that gives you what you want. For example this won't evaluate the `1` to `10` of the second list.

``````Prelude> let takeUntil _ [] = []; takeUntil p (x:xs) = if p x then [x] else (x: takeUntil p xs)
Prelude> (last . takeUntil (==0) . scanl (*) 1) ([1..10] ++ [0..10])
0
``````

`takeUntil` doesn't seem to exist in the standard library. It's like `takeWhile` but also gives you the first failing element.

If you want to do this properly you should take care with that partial `last`. If you want a powerful general solution I guess `mapAccumL` is the way to go.

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Exactly! `scanl` gives us the left-to-right flow, and `foldr` - an early breakout: `takeUntil p = foldr (\x r-> head([[x]|p x]++[r])) []`. -- `last` is not partial here, since `scanl` always produces a non-empty list. :) –  Will Ness Jan 21 '14 at 12:36
and of course where `scanl` fits the bill, so will `iterate`, and `unfoldr`. `unfoldr` will even stop on its own. –  Will Ness Jan 21 '14 at 12:55
`last . takeUntil p` could be rewritten as `head . takeWhile (not.p)` with the same effect. –  enough rep to comment Jan 21 '14 at 13:18
@WillNess: Indeed the partiality of `last` isn't hit here, but one should ideally write this in a way that doesn't use `last` and where the totality is obvious by construction. –  Tom Ellis Jan 21 '14 at 14:56
@chunksOf50 you meant `dropWhile (not.p) >>> head`... but that's not correct either (what if `p` never holds?). –  Will Ness Jan 21 '14 at 15:04