# How to takeWhile elements in a list wrapped in a monad

Got a little puzzle I was wondering if you could help me clarify.

Let's define a function that returns a list:

``````let f = replicate 3
``````

What we want to do is map this function to an infinite list, concatenate the results, and then take only things that match a predicate.

``````takeWhile (< 3) \$ concatMap f [1..]
``````

Great! That returns `[1,1,1,2,2,2]`, which is what I want.

Now, I want to do something similar, but the function f now wraps its results in a Monad. In my usecase, this is the IO monad, but this works for discussing my problem:

``````let f' x = Just \$ replicate 3 x
``````

To map and concat, I can use:

``````fmap concat \$ mapM f' [1..5]
``````

That returns: `Just [1,1,1,2,2,2,3,3,3,4,4,4,5,5,5]`

If I want to use `takeWhile`, this still works:

``````fmap (takeWhile (< 3) . concat) \$ mapM f' [1..5]
``````

Which returns: Just [1,1,1,2,2,2]. Great!

But, if I make the list over which I map an infinite list this does not do what I expected:

``````fmap (takeWhile (< 3) . concat) \$ mapM f' [1..]
``````

Seems like the `takeWhile` is never happening. Somehow, I'm not getting the lazy computation I was expecting. I’m a bit lost.

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## 3 Answers

You can't mapM an infinite list of Maybes. mapM is map followed by sequence. Here is the definition of sequence:

```sequence ms = foldr k (return []) ms
where
k m m' = do { x <- m; xs <- m'; return (x:xs) }
```

From this we see that sequence evaluates every monadic value in the list. Since it's an infinite list, this operation will not terminate.

EDIT:

luqui and Carl make a good point that this doesn't generalize to any monad. To see why it doesn't work for Maybe we need to look at the implementation of (>>=):

``````(>>=) m k = case m of
Just x  -> k x
Nothing -> Nothing
``````

The important point here is that we do a case on m. This makes the m strict because we have to evaluate it to figure out how to continue execution. Note that we're not casing on x here, so it remains lazy.

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"Evaluating" infinitely many monadic values is not really where the trouble is. For example, you can easily do this in the `Identity` monad. –  luqui Dec 10 '10 at 0:40
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This should do the trick:

``````takeWhileM :: (Monad m) => (a -> Bool) -> [m a] -> m [a]
takeWhileM p [] = return []
takeWhileM p (m:ms) = do
x <- m
if p x
then liftM (x:) (takeWhileM p ms)
else return []
``````

See sepp2k's answer for an explanation of why you are losing laziness. The Identity monad or the nonempty list monad, for example, wouldn't have this problem.

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Note that iteratees provide a more general solution to this problem. –  John L Dec 10 '10 at 15:29
@John, interesting! I didn't make that connection :-) –  luqui Dec 10 '10 at 19:20
@John, I'd love to see a more gentle intro do iteratees. I've been having a hard time wrapping my head around them. –  Daniel Apr 12 '11 at 14:24
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The problem isn't that `fmap` + `takeWhile` doesn't work with infinite lists wrapped in a monad. The problem is that `mapM` can't produce an infinite list (at least not in the Maybe monad).

Think about it: If `f'` returns `Nothing` for any item in the list, `mapM` has to return `Nothing`. However `mapM` can't know whether that will happen until it has called `f'` on all items in the list. So it needs to iterate through the whole list before it knows whether the result is `Nothing` or `Just`. Obviously that's a problem with infinite lists.

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Any suggestions on what I can use instead? –  Daniel Dec 10 '10 at 0:18
More generally, mapM is not (and cannot be) lazy for any monad where (>>=) is strict in its first argument. That includes Maybe, [], IO, and quite a few other things. –  Carl Dec 10 '10 at 0:20
@Daniel: The only real option is to explicitly write the control flow you intend. Yes, it's less convenient. Such is the price of sacrificing laziness. –  Carl Dec 10 '10 at 0:24
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