I'd like to be able to use O(1) amortized addressing with a vector type that grows lazily according to the demanded index.

This could be achieved by using pairing an MVector (PrimState m) a: with a PrimRef m [a] to hold the remainder, using the standard doubling-algorithm for amoritzed O(1) access:

{-# LANGUAGE ExistentialQuantification #-}
module LazyVec where

import Control.Monad.Primitive
import Data.PrimRef
import Data.Vector.Mutable (MVector)
import qualified Data.Vector.Mutable as M
import Data.Vector (fromList, thaw)
import Control.Monad (forM_)

data LazyVec m a = PrimMonad m => LazyVec (MVector (PrimState m) a) (PrimRef m [a])

-- prime the LazyVec with the first n elements
lazyFromListN :: PrimMonad m => Int -> [a] -> m (LazyVec m a)
lazyFromListN n xs = do
  let (as,bs) = splitAt n xs
  mvec <- thaw $ fromList as
  mref <- newPrimRef bs
  return $ LazyVec mvec mref

-- look up the i'th element
lazyIndex :: PrimMonad m => Int -> LazyVec m a -> m a
lazyIndex i lv@(LazyVec mvec mref) | i < 0     = error "negative index"
                                   | i < n     = M.read mvec i
                                   | otherwise = do
    xs <- readPrimRef mref
    if null xs
      then error "index out of range"
      else do
        -- expand the mvec by some power of 2
        -- so that it includes the i'th index
        -- or ends
        let n' = n * 2 ^ ( 1 +  floor (logBase 2 (toEnum (i `div` n))))
        let growth = n' - n
        let (as, bs) = splitAt growth xs
        M.grow mvec $ if null bs then length as else growth
        forM_ (zip [n,n+1..] as) . uncurry $ M.write mvec
        writePrimRef mref bs
        lazyIndex i lv
  where n = M.length mvec

And I could just use my code - but I'd rather reuse someone else's (for one, I haven't tested mine).

Does a vector type with these semantics (lazy creation from a possibly-infinite list, O(1) amortized access) exist in some package?

  • 7
    You can use IntMap, it's O(1). – augustss Mar 7 '14 at 17:16
  • 4
    @augustss: Using O(min(n,W)) is an odd choice on that page, it would only matter for extremely small list sizes, which don't follow the rules of big O anyway... But it does appear to be O(1) for lookup. – Guvante Mar 7 '14 at 17:28
  • 4
    You could use a lazily generated trie, which has the same time complexity as IntMap (provided the keys are also Ints) but would have the laziness you are after. The constant factors would be worse, but since you are looking for laziness anyway, I doubt this is going to be too much of a problem. – Jake McArthur Mar 7 '14 at 20:28
  • 4
    Note, however, that the cost model is different from what I imagine you might be after. If you generate the trie from a list, each time you visit an element for the first time you will traverse the list from the beginning to its location. So for example if you visit the first n elements of the original list in the trie it takes O(n^2). However, revisiting all n of them again takes O(n), as one would hope. That's necessary because you have to unfold the trie, not fold the list. There may be some interesting optimizations possible, but I will have to talk about those later, if interested. – Jake McArthur Mar 7 '14 at 20:32
  • 7
    @JakeMcArthur, do you want to make an answer for your MemoTrie suggestion? This is one of the highest voted Haskell questions without an answer. – Cirdec Apr 2 '14 at 3:30

As Jake McArthur noted in the comments: "If it's just a function, then I recommend just using one of the existing memoization packages like MemoTrie or data-memocombinators. They should make it easy."

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