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# How lazy is Haskell's `++`?

I'm curious how I should go about improving the performance of a Haskell routine that finds the lexicographically minimal cyclic rotation of a string.

``````import Data.List
swapAt n = f . splitAt n where f (a,b) = b++a
minimumrotation x = minimum \$ map (\i -> swapAt i x) \$ elemIndices (minimum x) x
``````

I'd imagine that I should use Data.Vector rather than lists because Data.Vector provides in-place operations, probably just manipulating some indices into the original data. I shouldn't actually need to bother tracking the indices myself to avoid excess copying, right?

I'm curious how the `++` impact the optimization though. I'd imagine it produces a lazy string thunk that never does the appending until the string gets read that far. Ergo, the `a` should never actually be appended onto the `b` whenever minimum can eliminate that string early, like because it begins with some very later letter. Is this correct?

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@LightnessRacesinOrbit: Clearly you've never seen the Haskell programs in the benchmarks game! – ehird Jan 16 '12 at 0:53
My humourous and well-intentioned comment got deleted. :( Go figure. – Lightness Races in Orbit Jan 16 '12 at 14:40

`xs ++ ys` adds some overhead in all the list cells from `xs`, but once it reaches the end of `xs` it's free — it just returns `ys`.

Looking at the definition of `(++)` helps to see why:

``````[] ++ ys = ys
(x:xs) ++ ys = x : (xs ++ ys)
``````

The key thing to realise is that appending isn't done all at once; a new linked list is incrementally built by first walking through all of `xs`, and then putting `ys` where the `[]` would go.

So, you don't have to worry about reaching the end of `b` and suddenly incurring the one-time cost of "appending" `a` to it; the cost is spread out over all the elements of `b`.

Vectors are a different matter entirely; they're strict in their structure, so even examining just the first element of `xs V.++ ys` incurs the entire overhead of allocating a new vector and copying `xs` and `ys` to it — just like in a strict language. The same applies to mutable vectors (except that the cost is incurred when you perform the operation, rather than when you force the resulting vector), although I think you'd have to write your own append operation with those anyway. You could represent a bunch of appended (immutable) vectors as `[Vector a]` or similar if this is a problem for you, but that just moves the overhead to when you flattening it back into a single Vector, and it sounds like you're more interested in mutable vectors.

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Fine, but presumably switching to `Data.Vector` fixes this, yes? Or does it create a separate copy penalty? In that case, I should simply create my own `twovectors` type or something? – Jeff Burdges Jan 15 '12 at 20:05
@JeffBurdges: I've expanded my answer to cover Vectors :) – ehird Jan 15 '12 at 20:07
Thanks! Another small question : If I wrote `minimumrotation x = minimum \$ map f \$ elemIndices (minimum x) x where f i = take (length x) \$ drop i (x++x)`. Are the `length x` and `x++x` evaluated only once when `f` is dethunked? – Jeff Burdges Jan 16 '12 at 0:38
@JeffBurdges: Maybe, but I wouldn't count on it; GHC is conservative about that kind of optimisation. You should probably give `length x` a name (in the same where block as `f`'s definition); I wouldn't worry about the `(x++x)` part. (Note that `f` itself is already in weak-head normal form, and so never gets forced ("dethunked"); it's `f i` that will get forced, for varying values of `i`.) – ehird Jan 16 '12 at 0:48
@JeffBurdges: That won't help; you have to lift the expression outside of the lambda-expression. – ehird Jan 17 '12 at 11:41

Try

``````minimumrotation :: Ord a => [a] -> [a]
minimumrotation xs = minimum . take len . map (take len) \$ tails (cycle xs)
where
len = length xs
``````

I expect that to be faster than what you have, though index-juggling on an unboxed `Vector` or `UArray` would probably be still faster. But, is it really a bottleneck?

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I suppose you mean `map (take len)`, interesting thanks. – Jeff Burdges Jan 15 '12 at 20:57
Of course I did. Thanks for spotting it. – Daniel Fischer Jan 15 '12 at 20:58
Is cycle faster than `xs++xs`? I'd assume yes a priori. Am I correct that swapping the two `take`s shouldn't impact performance since all those thunks must be computed anyways? – Jeff Burdges Jan 16 '12 at 0:32
`cycle xs` is just `fix (xs ++)`, so if anything `xs ++ xs` will be cheaper, but I wouldn't worry about it; the overhead will be minuscule. Swapping the `take len` and `map (take len)` will have no effect. – ehird Jan 16 '12 at 0:46
If there's any performance difference between `xs ++ xs` and `cycle xs` here, I would be surprised if it wasn't minuscule. I don't think swapping `take len` and `map (take len)` would make a measurable difference, but I haven't benchmarked it. – Daniel Fischer Jan 16 '12 at 0:47

If you're interested in fast concatenation and a fast `splitAt`, use Data.Sequence.

I've made some stylistic modifications to your code, to make it look more like idiomatic Haskell, but the logic is exactly the same, except for a few conversions to and from `Seq`:

``````import qualified Data.Sequence as S
import qualified Data.Foldable as F

minimumRotation :: Ord a => [a] -> [a]
minimumRotation xs = F.toList
. F.minimum
. fmap (`swapAt` xs')
. S.elemIndicesL (F.minimum xs')
\$ xs'
where xs' = S.fromList xs
swapAt n = f . S.splitAt n
where f (a,b) = b S.>< a
``````
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Ahh, several slick tricks there, including the infix `swapAt`. lol – Jeff Burdges Jan 16 '12 at 1:19
@JeffBurdges - another option is `(flip swapAt xs')`, but I personally prefer the infix section. – Dan Burton Jan 16 '12 at 1:24
Naturally it would be best to use sequences all the way through so that `toList` and `fromList` don't take up a lot of time for the program – alternative Apr 15 '12 at 1:21