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I'll get straight to it - is there a way to have a dynamically sized constant-time access data-structure in Haskell, much like an array in any other imperative language?

I'm sure there is a module somewhere that does this for us magically, but I'm hoping for a general explanation of how one would do this in a functional manner :)

As far as I'm aware, Maps use binary tree represenation for access so have log(n) access time, and lists of course have linear access time.

Additionally, if we made it so that it was immutable, it would be pure, right?

Any ideas how I could go about this (beyond something like Array = Array { one :: Int, two :: Int, three :: Int ...} in template Haskell or the like)?

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There's Data.Array in the standard library. –  Mikhail Glushenkov Nov 7 '13 at 9:19
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Thanks! I was hoping for more of a helpful explanation for how one would go about implementing such a thing in a functional sense - I'll have a read of the source and see what I can find out... –  Tetigi Nov 7 '13 at 9:24
    
Data.Array uses GHC.Arr, which defines an array as data Ix i => Array i e = Array !i !i !Int (Array# e), which (perhaps mistakenly) implies to me that there is some wizardry going on under the hood? –  Tetigi Nov 7 '13 at 9:39
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Yes, the implementation is compiler-specific. Array# is a special type provided by GHC. –  Mikhail Glushenkov Nov 7 '13 at 12:06
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3 Answers

up vote 6 down vote accepted

If your key is isomorphic to Int then you can use IntMap as most of its operations are O(min(n,W)), where n is the number of elements and W is the number of bits in Int (usually 32 or 64), which means that as the collection gets large the cost of each individual operation converges to a constant.

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Ah that's clever! Apparently it uses something called "big-endian patricia trees", which if I'm correct are something similar to tries except the paths are the bit representation of the Int - this means that the path is of maximum length W where W is the number of bits in the Int. This gives the constant worst case time of W as long as your index fits into an Int! Pretty cool. –  Tetigi Nov 7 '13 at 9:48
    
So I suppose as long as your key can be split into N parts, where the N <= M, then you can always make a tree with worst case time M, which is constant if M is constant :) –  Tetigi Nov 7 '13 at 9:49
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Yep! It is similar in spirit to the trick used in radix sort to sort a list of n elements with d decimals in just O(n*d) time, which is linear if d is a constant with respect to n. –  Gregory Crosswhite Nov 7 '13 at 9:59
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a dynamically sized constant-time access data-structure in Haskell,

  • Data.Array
  • Data.Vector

etc etc.

For associative structures you can choose between:

  • Log-N tree and trie structures
  • Hash tables
  • Mixed hash mapped tries

With various different log-complexities and constant factors.

All of these are on hackage.

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Thanks Don! I asked this question hoping for some high level overviews of how things like hash tables and other similar structures are implemented in Haskell, but these are all good leads for some further reading. –  Tetigi Nov 7 '13 at 12:03
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@Tetigi Generally, you'll find some explanations on their hackage pages + a reference to a paper explaining how these data structures are implemented. Hopefully that will suffice, but feel free to come back asking questions about those, quite a few people are familiar with the implementations. I did study them myself too at some point, was really helpful in getting more familiar with these data structures. –  Alp Mestanogullari Nov 7 '13 at 22:53
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In addition to the other good answers, it might be useful to say that:

When restricted to Algebraic Data Types and purity, all dynamically sized data structure must have at least logarithmic worst-case access time.

Personally, I like to call this the price of purity.

Haskell offers you three main ways around this:

  • Change the problem: Use hashes or prefix trees.
  • For constant-time reads use pure Arrays or the more recent Vectors; they are not ADTs and need compiler support / hidden IO inside. Constant-time writes are not possible since purity forbids the original data structure to be modified.
  • For constant-time writes use the IO or ST monad, preferring ST when you can to avoid externally visible side effects. These monads are implemented in the compiler.
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