# Is Haskell's mapM not lazy?

UPDATE: Okay this question becomes potentially very straightforward.

``````q <- mapM return [1..]
``````

Why does this never return?

Does mapM not lazily deal with infinite lists?

The code below hangs. However, if I replace line A by line B, it doesn't hang anymore. Alternatively, if I preceed line A by a "splitRandom \$", it also doesn't hang.

Q1 is: Is mapM not lazy? Otherwise, why does replacing line A with line B "fix this" code?

Q2 is: Why does preceeding line A with splitRandom "solve" the problem?

``````import Control.Monad.Random
import Control.Applicative

f :: (RandomGen g) => Rand g (Double, [Double])
f = do
b <- splitRandom \$ sequence \$ repeat \$ getRandom
c <- mapM return b -- A
-- let c = map id b -- B
a <- getRandom
return (a, c)

splitRandom :: (RandomGen g) => Rand g a -> Rand g a
splitRandom code = evalRand code <\$> getSplit

t0 = do
(a, b) <- evalRand f <\$> newStdGen
print  a
print (take 3 b)
``````

The code generates an infinite list of random numbers lazily. Then it generates a single random number. By using splitRandom, I can evaluate this latter random number first before the infinite list. This can be demonstrated if I return b instead of c in the function.

However, if I apply the mapM to the list, the program now hangs. To prevent this hanging, I have to apply splitRandom again before the mapM. I was under the impression that mapM can lazily

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Well, there's lazy, and then there's lazy. `mapM` is indeed lazy in that it doesn't do more work than it has to. However, look at the type signature:

``````mapM :: (Monad m) => (a -> m b) -> [a] -> m [b]
``````

Think about what this means: You give it a function `a -> m b` and a bunch of `a`s. A regular `map` can turn those into a bunch of `m b`s, but not an `m [b]`. The only way to combine the `b`s into a single `[b]` without the monad getting in the way is to use `>>=` to sequence the `m b`s together to construct the list.

In fact, `mapM` is precisely equivalent to `sequence . map`.

In general, for any monadic expression, if the value is used at all, the entire chain of `>>=`s leading to the expression must be forced, so applying `sequence` to an infinite list can't ever finish.

If you want to work with an unbounded monadic sequence, you'll either need explicit flow control--e.g., a loop termination condition baked into the chain of binds somehow, which simple recursive functions like `mapM` and `sequence` don't provide--or a step-by-step sequence, something like this:

``````data Stream m a = Nil | Stream a (m (Stream m a))
``````

...so that you only force as many monad layers as necessary.

Edit:: Regarding `splitRandom`, what's going on there is that you're passing it a `Rand` computation, evaluating that with the seed `splitRandom` gets, then `return`ing the result. Without the `splitRandom`, the seed used by the single `getRandom` has to come from the final result of sequencing the infinite list, hence it hangs. With the extra `splitRandom`, the seed used only needs to thread though the two `splitRandom` calls, so it works. The final list of random numbers works because you've left the `Rand` monad at that point and nothing depends on its final state.

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But this doesn't explain why preceeding the line with splitRandom solves the problem. Also, note that splitRandom actually splits the random seed into two and uses one of them to generate the infinite list, so there shouldn't be a dependency there. –  qrest Jul 17 '10 at 4:53
@qrest: Added an extra note--does that help? –  C. A. McCann Jul 17 '10 at 6:25
@camccann: No it's doesn't. Here's my reasoning. I need to consume one seed to generate the infinite list. Hence, I split the seed and used it in "splitRandom \$ sequence \$ repeat \$ getRandom". NOTE: This is a monadic expression and it did not evaluate fully! Note also I purposefully got a random number for "a" AFTER the infinite list, proving that the seeds are not dependent. And the Rand monad does not use the seed unless a random number is generated so no seed dependency should exist. So is "return" the one actually forcing the evaluation? –  qrest Jul 17 '10 at 16:09
"In general, for any monadic expression, if the value is used at all, the entire chain of >>=s leading to the expression must be forced, so applying sequence to an infinite list can't ever finish." I don't think this is true in general for all monads. I just showed an example in an answer below with the identity monad, where all the values put into the monad are still there, and can be used lazily. –  newacct Jan 6 '13 at 1:21
@newacct I agree, that part of the answer is wrong. Some monads are lazy enough that applying `sequence` to an infinite list does finish. –  John L Jan 6 '13 at 2:44

Here's an attempt at a proof that `mapM return [1..]` doesn't terminate. Let's assume for the moment that we're in the `Identity` monad (the argument will apply to any other monad just as well):

``````mapM return [1..] -- initial expression
sequence (map return [1 ..]) -- unfold mapM
let k m m' = m >>= \x ->
m' >>= \xs ->
return (x : xs)
in foldr k (return []) (map return [1..]) -- unfold sequence
``````

So far so good...

``````-- unfold foldr
let k m m' = m >>= \x ->
m' >>= \xs ->
return (x : xs)
go [] = return []
go (y:ys) = k y (go ys)
in go (map return [1..])

-- unfold map so we have enough of a list to pattern-match go:
go (return 1 : map return [2..])
-- unfold go:
k (return 1) (go (map return [2..])
-- unfold k:
(return 1) >>= \x -> go (map return [2..]) >>= \xs -> return (x:xs)
``````

Recall that `return a = Identity a` in the Identity monad, and `(Identity a) >>= f = f a` in the Identity monad. Continuing:

``````-- unfold >>= :
(\x -> go (map return [2..]) >>= \xs -> return (x:xs)) 1
-- apply 1 to \x -> ... :
go (map return [2..]) >>= \xs -> return (1:xs)
-- unfold >>= :
(\xs -> return (1:xs)) (go (map return [2..]))
``````

Note that at this point we'd love to apply to `\xs`, but we can't yet! We have to instead continue unfolding until we have a value to apply:

``````-- unfold map for go:
(\xs -> return (1:xs)) (go (return 2 : map return [3..]))
-- unfold go:
(\xs -> return (1:xs)) (k (return 2) (go (map return [3..])))
-- unfold k:
(\xs -> return (1:xs)) ((return 2) >>= \x2 ->
(go (map return [3..])) >>= \xs2 ->
return (x2:xs2))
-- unfold >>= :
(\xs -> return (1:xs)) ((\x2 -> (go (map return [3...])) >>= \xs2 ->
return (x2:xs2)) 2)
``````

At this point, we still can't apply to `\xs`, but we can apply to `\x2`. Continuing:

``````-- apply 2 to \x2 :
(\xs -> return (1:xs)) ((go (map return [3...])) >>= \xs2 ->
return (2:xs2))
-- unfold >>= :
(\xs -> return (1:xs)) (\xs2 -> return (2:xs2)) (go (map return [3..]))
``````

Now we've gotten to a point where neither `\xs` nor `\xs2` can be reduced yet! Our only choice is:

``````-- unfold map for go, and so on...
(\xs -> return (1:xs))
(\xs2 -> return (2:xs2))
(go ((return 3) : (map return [4..])))
``````

So you can see that, because of `foldr`, we're building up a series of functions to apply, starting from the end of the list and working our way back up. Because at each step the input list is infinite, this unfolding will never terminate and we will never get an answer.

This makes sense if you look at this example (borrowed from another StackOverflow thread, I can't find which one at the moment). In the following list of monads:

``````mebs = [Just 3, Just 4, Nothing]
``````

we would expect `sequence` to catch the `Nothing` and return a failure for the whole thing:

``````sequence mebs = Nothing
``````

However, for this list:

``````mebs2 = [Just 3, Just 4]
``````

we would expect sequence to give us:

``````sequence mebs = Just [3, 4]
``````

In other words, `sequence` has to see the whole list of monadic computations, string them together, and run them all in order to come up with the right answer. There's no way `sequence` can give an answer without seeing the whole list.

Note: The previous version of this answer asserted that `foldr` computes starting from the back of the list, and wouldn't work at all on infinite lists, but that's incorrect! If the operator you pass to `foldr` is lazy on its second argument and produces output with a lazy data constructor like a list, `foldr` will happily work with an infinite list. See `foldr (\x xs -> (replicate x x) ++ xs) [] [1...]` for an example. But that's not the case with our operator `k`.

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Saying that `foldr` works "from the back of the list" is a bit confusing. Both `foldl` and `foldr` process the list left-to-right. The difference is the bracketing, not the processing direction. –  nh2 Jan 3 '13 at 2:02
I would contend that your description is the one that's more confusing. The Prelude documentation itself says that `foldr` "reduces the list using the binary operator, from right to left" -- the bracketing is the whole point! The initial left-right pass through the list (required anyway to traverse Haskell's list structure) establishes the stack of recursion, but does no computation on the elements of the list. –  Owen S. Jan 5 '13 at 1:45
I disagree: There is no actual "initial left right pass" until the end. If there was, how could `foldr` work on infinite lists? `foldr (:) [] [1..]` runs perfectly fine and it constant memory - this could not be if the list was processed from right to left because there is no right end. –  nh2 Jan 5 '13 at 11:46
Aha, so I wasn't confusing, I was just flat-out wrong! Thanks for the correction. See if the updated answer looks correct to you. –  Owen S. Jan 5 '13 at 21:11

Okay this question becomes potentially very straightforward.

q <- mapM return [1..]

Why does this never return?

It's not necessarily true. It depends on the monad you're in.

For example, with the identity monad, you can use the result lazily and it terminates fine:

``````newtype Identity a = Identity a

Identity x >>= k = k x
return = Identity

-- "foo" is the infinite list of all the positive integers
foo :: [Integer]
Identity foo = do
q <- mapM return [1..]
return q

main :: IO ()
main = print \$ take 20 foo -- [1 .. 20]
``````
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