While thinking about this other question, I realized that the following functions
smoothSeq :: (Integer, Integer, Integer) -> [Integer] smoothSeq (a, b, c) = result where result = 1 : union timesA (union timesB timesC) timesA = map (* a) $ result timesB = map (* b) $ result timesC = map (* c) $ result smoothSeq' :: (Integer, Integer, Integer) -> [Integer] smoothSeq' (a, b, c) = 1 : union timesA (union timesB timesC) where timesA = map (* a) $ smoothSeq' (a, b, c) timesB = map (* b) $ smoothSeq' (a, b, c) timesC = map (* c) $ smoothSeq' (a, b, c) -- | Merge two sorted sequences discarding duplicates. union :: (Ord a) => [a] -> [a] -> [a] union  ys = ys union xs  = xs union (x : xs) (y : ys) | x < y = x : union xs (y : ys) | x > y = y : union (x : xs) ys | otherwise = x : union xs ys
have drastically different performance characteristics:
ghci> smoothSeq (2,3,5) !! 500 944784 (0.01 secs, 311,048 bytes) ghci> smoothSeq' (2,3,5) !! 500 944784 (11.53 secs, 3,745,885,224 bytes)
My impression is that
smoothSeq is linear in memory and time (as was
result is shared in the recursive definition, whereas
smoothSeq' is super-linear because the recursive function definition spawns a tree of computations that independently recompute multiple times the previous terms of the sequence (there is no sharing/memoization of the previous terms; similar to naive Fibonacci).
While looking around for a detailed explanation, I encountered these examples (and others)
fix f = x where x = f x fix' f = f (fix f) cycle xs = res where res = xs ++ res cycle' xs = xs ++ cycle' xs
where again the non-primed version (without
' suffix) is apparently more efficient because it reuses the previous computation.
From what I can see, what differentiates the two versions is whether the recursion involves a function or data (more precisely, a function binding or a pattern binding). Is that enough to explain the difference in behavior? What is the principle behind, that dictates whether something is memoized or not? I couldn't find a definite and comprehensive answer in the Haskell 2010 Language Report, or elsewhere.
Edit: here is another simple example that I could think of:
arithSeq start step = result where result = start : map (+ step) result arithSeq' start step = start : map (+ step) (arithSeq' start step)
ghci> arithSeq 10 100 !! 10000 1000010 (0.01 secs, 1,443,520 bytes) ghci> arithSeq' 10 100 !! 10000 1000010 (1.30 secs, 5,900,741,048 bytes)
The naive recursive definition
arithSeq' is way worse than
arithSeq, where the recursion "happens on data".
x = g xwhere
xis a non-function (and monomorphic) value, the value of
xwill be stored the first time is demanded, and reused later. For functions,
f x = g (f x)won't store any result and recompute
f xfrom scratch each time it's demanded. I'd say that your intuition above is basically correct.
-O2, and possibly use some benchmarking library like criterion. Here on SO we saw many cases where askers wonder why something is slower, when that is no longer the case after proper compilation.
ghci -fobject-code -O2and
:loadit in compiled form (hopefully optimized?). I'll start learning about how to use Criterion soon, thanks for the suggestion!