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Thanks to lazy evaluation, Haskell can process following expression in a moment.

head.head $ let m = 1000000000000000 in map (\n -> [m*n .. m*(n+1)]) [1 .. m] 

But I noticed following expression doesn't finish, yet the memory usage stayed low.

last.last $ let m = 1000000000000000 in map (\n -> [m*n .. m*(n+1)]) [1 .. m]

It is not suprising that haskell can do that. But I wonder how it works. More precisely, how haskell allocate memory. Is there any way to check memory layout or something like that?

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Read more on Haskell profiling: haskell.org/haskellwiki/How_to_profile_a_Haskell_program . You can control memory usage in details. –  EarlGray Nov 28 '12 at 11:01
The second code snippet does not consume a lot of memory, because it operates on lazy lists only with map and generators, cycling through it and requiring only one its item at a time. When previous items are not needed they're garbage collected. –  EarlGray Nov 28 '12 at 11:04

2 Answers 2

up vote 8 down vote accepted

Let's simplify this example a bit to see what happens. You can mostly figure it out just thinking about lazy evaluation and graph reduction, without needing to go any lower-level than that. Let's look at a simplified reduction of ourLast (mkList 3) with this code:

ourLast :: [a] -> a
ourLast [] = error "ourLast []"
ourLast (x:[]) = x
ourLast (_:xs) = ourLast xs

mkList :: Int -> [Int]
mkList 0 = []
mkList n = let rest = mkList (n-1) in n : rest

?foo means "a value we haven't looked at yet". We create these with "let". foo@bar means "a value we've already computed which we've figured out is bar" when we examine ?foo, it becomes foo@bar foo := bar means "we've not figured out that foo is bar"

    -- We start here by creating some value and giving it to ourLast to
    -- look at.
let ?list3 = mkList 3
ourLast ?list3
    -- At this point ourLast examines its argument to figure out whether
    -- it's of the form (_:_) or []
    -- mkList sees that 3 /= 0, so it can pick the second case, and it
    -- computes the value for ?list3.
    -- (I'll skip the arithmetic reductions and other boring things.)
    let ?list2 = mkList 2
    list3 := 3 : ?list2 -- we don't need to compute ?list2 yet, so
                        -- (mkList 3) is done and we can go back to ourLast
ourLast list3@(3 : ?list2)
    -- ourLast needs to examine ?list2 to find out whether it's [] or not,
    -- so mkList does the same thing again
    let ?list1 = mkList 1
    list2 := 2 : ?list1
ourLast list3@(3 : list2@(2 : ?list1))
    -- Now ourLast has enough information to continue;
    -- ourLast (_ : xs@(_ : _)) = ourLast xs
    -- Notice how we don't need to compute list2 a second time; we save its
    -- value the first time we compute it. This is what lazy evaluation is.
ourLast list2@(2 : ?list1)
    -- at this point, there are no references to `list3` anywhere, so it
    -- can be GCed.
    -- Repeat (ourLast examines ?list1, mkList sees that 1 /= 0).
    let ?list0 = mkList 0
    list1 := 1 : ?list0
ourLast list2@(2 : list1@(1 : ?list0))
ourLast list1@(1 : ?list0)
    -- Can GC list2.
    -- Now mkList is being called with 0, so it just returns an empty list.
    list0 := []
ourLast list1@(1 : list0@[])
    -- We're done! (And we can GC list1.)

Notice how at any given time we only need to have a couple thunks actually allocated, and the rest either aren't computed yet or can be GCed. When we evaluate ourLast list3, evaluation jumps back and forth between ourLast and mkList (sort of like coroutines).

If you want to get a more precise idea of how Haskell compilers tend to work, on the level of "when and how does allocation happend", the following are helpful:

A general understanding how lazy evaluation works just from the perspective of graph reduction -- e.g. this article -- is useful.

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I would do some heap-profiling as explained here. For this you need to install the profiling libraries with cabal. The explanation is pretty comprehensive and easy to follow.

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