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I'm working with the Sieve of Eratosthenes code from Literate Programming (http://en.literateprograms.org/Sieve_of_Eratosthenes_%28Haskell%29), modified slightly to include edge cases on merge and diff:

primesInit = [2,3,5,7,11,13]
primes = primesInit ++ [i | i <- diff [15,17..] nonprimes]

nonprimes = foldr1 f . map g $ tail primes
        where g p = [n * p | n <- [p,p+2..]]
              f (x:xt) ys = x : (merge xt ys)

merge :: (Ord a) => [a] -> [a] -> [a]
merge [] ys = ys
merge xs [] = xs
merge xs@(x:xt) ys@(y:yt)
    | x < y  = x : merge xt ys
    | x == y = x : merge xt yt
    | x > y  = y : merge xs yt

diff :: (Ord a) => [a] -> [a] -> [a]
diff [] ys = []
diff xs [] = xs
diff xs@(x:xt) ys@(y:yt)
    | x < y  = x : diff xt ys
    | x == y = diff xt yt
    | x > y  = diff xs yt

Both merge and diff on their own are lazy. So is nonprimes and primes. But if we change the definition of primes to remove f, as in:

nonprimes = foldr1 merge . map g $ tail primes
        where g p = [n * p | n <- [p,p+2..]]

Now nonprimes isn't lazy. I've also recreated this with take 20 $ foldr1 merge [[i*n | n <- [3,7..]] | i <- [5,9..]] (GHCI runs out of memory and exits).

Based on http://www.haskell.org/haskellwiki/Performance/Laziness , one easy source of non-laziness is recursing before returning a data constructor. But merge doesn't have this problem; it returns a cons-cell that contains the recursive call as the second item. Nor should the use of foldr be a culprit here by itself (It's foldl that can't do infinite lists).

So, why does merge need to be separated from foldr1 by f, which essentially does the first call to merge manually? All f does is return a cons cell that contains the call to merge as the second item, right?

NOTE: Someone else on Stack Overflow was working with similar code and ran into the same problem I did, but they accepted an answer that looked to me like basically different code. I'm asking why, not how, as it seems that laziness is somewhat important in Haskell.

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3 Answers 3

up vote 3 down vote accepted

Let's compare those two functions again:

merge [] ys = ys
merge xs [] = xs
merge xs@(x:xt) ys@(y:yt)
    | x < y  = x : merge xt ys
    | x == y = x : merge xt yt
    | x > y  = y : merge xs yt

and

f (x:xt) ys = x : (merge xt ys)

Let's ignore the semantic differences between the two, though they are significant - f is a lot more restricted as far as when it's valid to call. Instead, lets look at only the strictness properties.

Pattern matches in multiple equations are checked top-down. Multiple pattern matches within a single equation are checked left-to-right. So the first thing merge does is force the constructor of its first argument, in order to determine if the first equation matches. If the first equation doesn't match, it forces the constructor of the second argument, in order to determine if the second equation matches. Only if neither equation matches does it move to the third case. The compiler is smart enough to know it's already forced both arguments at this point, so it doesn't do it again - but those pattern matches would require the arguments to be forced if it hadn't already been.

But the important thing here is that the process of figuring out which equation matches causes both arguments to be forced before any constructor is produced.

Now, contrast that with f. In the definition of f, the only pattern-matching is on the first argument. As such, f is somewhat less strict than merge. It produces a constructor before examining its second argument.

And it turns out that if you closely examine the behavior of foldr, it works on infinite lists precisely when the function passed to it doesn't (always) examine its second argument before producing a constructor.

The parenthetical "always" there is interesting. One of my favorite examples of using foldr and laziness together is:

dropRWhile :: (a -> Bool) -> [a] -> [a]
dropRWhile p = foldr (\x xs -> if p x && null xs then [] else x:xs) []

This is a maximally-lazy function that works like dropWhile, except from the back (right) of the list. If the current element doesn't match the predicate, it's returned immediately. If it does match the predicate, it looks ahead until it finds something that either doesn't match, or the end of the list. This will be productive on infinite lists, so long as it eventually finds an element that doesn't match the predicate. And that is the source of the "always" parenthetical up above - a function that usually doesn't examine its second argument before producing a constructor still allows foldr to usually work on infinite lists.

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I double-checked what commenting out the empty list checks in merge would do. GHCI still crashed. –  proegssilb Jan 6 '14 at 3:33
    
Coincidentally, while there is a way to make merge simply alternate between the lists, it won't work for this case; diff needs the two lists it is working on to be sorted in order for it to work. –  proegssilb Jan 6 '14 at 3:43
    
@proegssilb The third equation still branches (the guards) before determining which expression to evaluate to. This results in examining the arguments before producing a constructor. You could try re-writing merge to produce a (:) constructor before branching at all, but it would necessarily only work with infinite lists in that case. –  Carl Jan 6 '14 at 4:15
    
If this were anything except a prime sieve disguised as an infinite list, that might work. diff needs its two arguments to be sorted, and merge can't maintain sort order if it doesn't do a comparison. But a comparison increases strictness. I'm pretty OK with how this turned out. Thanks for the help! –  proegssilb Jan 6 '14 at 5:13
    
@Carl the very presence of the pattern (y:yt) is what triggers the demand for the first element of the 2nd argument. Guards later force its value to be known, but the problem is the very taking of the head element even without knowing its value, because this triggers the evaluation of the 2nd argument. –  Will Ness Jan 6 '14 at 13:45

To determine the first element of its output, merge needs to evaluate both arguments enough to determine if they are empty lists or not. Without that information it can't be determined which case of the function definition applies.

In combination with foldr1 it becomes a problem that merge tries to evaluate its second argument. nonprimes in an expression of this form:

foldr1 merge [a,b,c,...]

To evaluate this, first `foldr1 is expanded:

merge a (foldr1 merge [b,c,...])

To now evaluate merge, the cases of its function definition are checked. First a is evaluated, and it turns out to not be an empty list. So the first case of merge doesn't apply. Next, the second parameter of merge needs to be evaluated to see if it is an empty list and if the second case of the definition of merge applies. This second parameter is foldr1 merge [b,c,...].

But to evaluate this we are in the same situation as before with foldr1 merge [a,b,c,...], and we just the same end up with merge b (foldr1 merge [c,...]), where merge again needs to evaluate it's second parameter to check if it's an empty list.

And so on. Each evaluation of merge requires another evaluation of merge first, which ends up in infinite recursion.

With f that problem is avoided, since it doesn't need to look at its second parameter for the top level evaluation. foldr1 f [a,b,c...] is f a (foldr1 f [b,c,...]) which evaluates to a non-empty list a0 : merge a' (foldr1 f [b,c,...]). So foldr1 f ... never is an empty list. This can be determined without any infinite recursion.

Now also the evaluation of merge a' (foldr1 f [b,c,...]) isn't a problem, since the second parameter evaluates to some b0 : ..., which is all merge needs to know to start producing a result.

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"Now nonprimes isn't lazy."

The proper term is non-productive, meaning, there is an infinite loop there, a "black hole". You can recreate this behaviour with just head $ foldr1 merge [[x] | x<-[1..]] which never produces any output.

The answer is in the definition of foldr1: the above example is equivalent to

      merge [1] (merge [2] (merge [3] (merge [4] (merge [5] ... ))))

(sth's answer explains this in some detail). Each merge, to produce even a head of its output list, demands1 to know the head of the output of the expression on its right (its 2nd argument). This chain of demands never stops. Thus, a black hole.


1 because it is strict in both its arguments, like Carl's answer explains.

f is non-strict in its 2nd argument, meaning, it does not demand right away the head of its 2nd argument, and produces its first element unconditionally, when asked to, taking the head of its 1st argument list (which is really a stream, under Haskell's lazy evaluation model).

The uncontrolled recursion of merge down its right argument's spine is guarded against by the call to f which ensures that one element is produced unconditionally, first; this illustrates why this is known as guarded recursion.

The reason this works is because our lists are ordered not only by themselves, but also as a collection: by construction, we know in advance that the head of any stream to the left is smaller than the head of stream to its right.


some tangential comments:

  • merge is wrong name there, as it removes the duplicates. It's really about making a union of two sets represented by ordered lists. "merge" as part of mergesort will usually be written to preserve duplicates.

  • you don't really need the edge cases on diff and merge when you work only with infinite lists, as indeed are the lists of primes, and each prime's multiples.

  • [i | i <- diff [15,17..] nonprimes] is the same as diff [15,17..] nonprimes.

  • foldr1 f . map g is the same as foldr1 (f . g): for an input list [a,b,c, ...], we have

        f (g a) (f (g b) (f (g c) ( ... ))) === (f.g) a ((f.g) b ((f.g) c ( ... )))

so we can re-write

    nonprimes = foldr1 (\p-> (p*p :) . merge [p*p+2*p, p*p+4*p..])
                     $ tail primes
        {-  where g p = [n * p | n <- [p,p+2..]] 
                      = map (p*) [p,p+2..] 
                      = [p*p,p*p+2*p..]
                  f (x:xt) = (x :) . merge xt
                  (f . g) p = (p*p :) . merge [p*p+2*p, p*p+4*p..]  -}

where the structure of the code is more immediately visually apparent. All the extra helper functions have been fused into one. What's important is the presence of cons (:) guarding against the uncontrolled recursion of merge.

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