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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

3 Answers 3

up vote 10 down vote accepted

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)

i.e., it has to "re-build" the entire first list as the result is traversed. This article is very helpful for understanding how to reason about lazy code in this way.

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
1  
@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
1  
@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
1  
@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 takes 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

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