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For a description of the data structure see

An half-edge data structure involves cycles.

  • is it possible to implement it in a functional language like Haskell ?
  • are mutable references (STRef) to way to go ?

Thanks

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2  
Generally, there is no problem with cycles due to lazy evaluation. In fact, it saves you from any additional indirection (mutable references). ones = 1 : ones ... –  Dario Oct 27 '10 at 12:17
    
@Dario you're right, I was probably confusing the data structure itself and the algorithm operating on it: the first is fine, but you have to be careful with the second (exactly like in 'ones') haskell.org/haskellwiki/Tying_the_Knot helped me clearing up my mind –  andreabedini Oct 28 '10 at 0:36

3 Answers 3

up vote 2 down vote accepted

Obviously the problem is that a half-edge references the next and the opposite half-edge (the other references are no problem). You can "break the cycle" e.g. by referencing not directly to other half-edges, but to reference just an ID (e.g. simple Ints). In order to look up a half-edge by ID, you can store them in a Data.Map. Of course this approach requires some book-keeping in order to avoid a big hairy mess, but it is the easiest way I can think of.

Stupid me, I'm not thinking lazy enough. The solution above works for strict functional languages, but is unnecessary for Haskell.

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This shouldn't be necessary, thanks to laziness. For instances, let e = HalfEdge { ... partner = f ... } ; f = HalfEdge { ... partner = e ... } in ... will work just fine. –  Antal S-Z Oct 28 '10 at 16:22

If the task in question allows you to build the half-edge structure once and then query it many times, then lazy tying-the-know approach is the way to go, as was pointed out in the comments and the other answer.

However, if you want to update your structure, then purely-functional interface might prove cumbersome to work with. Also, you need to consider O(..) requirements for update functions. It might turn out that you need mutable internal representation (probably with pure API on top) after all.

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Thanks for your answer. In the tie-the-knot approach, wouldn't the updates be done in constant time (provided, of course, the updates are 'local') ? –  andreabedini Oct 31 '10 at 5:10
    
That's the crux of the matter: would they be local? Or, would you be able to create and maintain a zipper or something like that to contain them or keep them local? Consider tree: update in the leaf may require updates in the nodes that lie on the path from the root to this leaf. I expect something similar to take place here. –  ADEpt Nov 1 '10 at 23:49

I've run into a helpful application of polymorphism for this sort of thing. You'll commonly desire both a static non-infinite version for serialization, as well as a knot-tyed version for internal representation.

If you make one version that's polymorphic, then you can update that particular value using record syntax :

data Foo edge_type_t = Depot {
   edge_type :: edge_type_t,
   idxI, idxE, idxF, idxL :: !Int
} deriving (Show, Read)

loadFoo edgetypes d = d { edge_type = edgetypes ! edge_type d }
unloadFoo d = d { edge_type = edgetype_id $ edge_type d }

There is however one major caveat : You cannot make a Foo (Foo (Foo( ...))) type this way because Haskell must understand the type's recursively. :(

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