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I am starting to doubt if my plan of getting into Haskell and functional programming by using Haskell for my next course on algorithms is a good one.

To get some Haskell lines under my belt I started trying to implement some simple algos. First: Gale-Shapley for the Stable Marriage Problem. Having not yet gotten into monads, all that mutable state looks daunting, so instead I used the characterization of stable matchings as fixed-points of a mapping on the lattice of semi-matchings. It was fun, but its no longer Gale-Shapley and the complexity isn't nice (those chains in the lattice can get pretty long apparently :)

Next up I have the algorithm for Closest Pair of points in the plane, but am stuck on getting the usual O(n*log n) complexity because I can't work out how to get a set-like data structure with O(1) checking for membership.

So my question is: Can one in general implement most algorithms eg. Dijkstra, Ford-Fulkerson (Gale-Shapley !?) getting the complexities from procedural implementations if one gets a better command of Haskell and functional programming in general ?

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Just ask lambdabot. Q: Can Haskell do xyz? A: Yes! Haskell can do that! – FUZxxl Jul 23 '11 at 0:03
up vote 15 down vote accepted

This probably can't be answered in general. A lot of standard algorithms are designed around mutability, and translations exist in some cases, not in others. Sometimes alternate algorithms exist that give equivalent performance characteristics, sometimes you really do need mutability.

A good place to start, if you want understanding of how to approach algorithms in this setting, is Chris Okasaki's book Purely Functional Data Structures. The book is an expanded version of his thesis, which is available online in PDF format.

If you want help with specific algorithms, such as the O(1) membership checking (which is actually misleading--there's no such thing, such data structures usually have something like O(k) where k is the size of elements being stored) you'd be better off asking that as a specific, single question instead of a very general question like this.

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+1 for mentioning Okasaki's book. – Ivan Danilov Jul 23 '11 at 1:30
Well, you could mention it only if you aware of it. And not everyone is. Knowledge -> reputation, essential formula of SO :) – Ivan Danilov Jul 23 '11 at 1:39
You can always emulate an imperative algorithm that assumes mutable state in an immutable world by emulating mutable variables with a tree-based lookup table, at the cost of a O(log n) factor. And this O(log n) slowdown is provably the best you can do in a strict language with no mutation. However, in call-by-need languages, we have a limited form of mutation available to us in the form of thunk evaluation, so while the upper bound holds, the argument used to establish the lower bound doesn't apply. So in general you can get within O(log n), and sometimes you can get all the way there. – Edward KMETT Jul 24 '11 at 5:29
Pippinger and Ben-Amram and Galil provide the proof in a strict setting, while Bird, Jones and de Moor provide a counter example of an algorithm that can run with the same asymptotics in a call-by-need language as a strict language with mutation, but runs slower in a strict language without mutation. – Edward KMETT Jul 26 '11 at 3:26
One important point re: Okasaki. One of the lovely benefits of purely functional data structures is persistence in the sense that unlike traditional mutable data structures, the old version of a purely functional data structure is still available for further operations. This is a feature that is sometimes required and that could be expensive to retrofit onto a mutable data structure. So it's apples and oranges. – Lambdageek Jul 28 '11 at 18:50

Since you have the ST monad in Haskell you can do anything with mutable state at the same speed of an imperative language. To the outside it can have a non-monadic interface. See for instance Launchbury and Peyton-Jones: "Lazy functional state threads"

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Existence proof for implementing algorithms with mutable data structures. Just recurse over an IO record. In this case, a Game record that holds the relevant variables.

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