# An Existing Size-Lazy Vector Type In Haskell

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 Data.PrimRef
import Data.Vector.Mutable (MVector)
import qualified Data.Vector.Mutable as M
import Data.Vector (fromList, thaw)

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
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?

• You can use `IntMap`, it's O(1). – augustss Mar 7 '14 at 17:16
• @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
• You could use a lazily generated trie, which has the same time complexity as `IntMap` (provided the keys are also `Int`s) 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
• 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
• @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