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In Haskell, I'd like to generate a list of random integers of undetermined length. (However, less than say 1 million.)

I'm not likely to need all the elements of the list immediately, so I'd like to generate it lazily. However, once generated, I'll need to access elements in the list with random access. So, I assume the best technique would be to copy an infinite list to an array. However, I don't know if arrays can be "interchanged" with lists very easily -- for instance, once I want to generate more items of the list, I want to start where I left off but expand the array.

Anyways, perhaps I should settle for some log(n) tree structure instead of an array? What do you think?

Does Haskell have a tree structure for sequential elements that can be accessed using a list-like API?

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5 Answers 5

up vote 7 down vote accepted

If you have a good PRNG, then values which are generated with seeds which are close together should be independent, so you can just choose an initial seed, then each cell i in the array will be prng(seed+i).

This is essentially just using it as a hash function :P

If you do it this way, you don't even really need the array, you can just have a function getRandomValue seed i = prng (seed+i). Whether or not this is better than an array of lazy values will depend on the complexity of your PRNG, but either way you'll get O(1) access.

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Very clever idea! –  luqui Feb 10 '11 at 6:28
    
I like this idea, but you would have to be sure it wouldn't be a bad thing for an attacker to know all your random numbers. Given a small set of sequential generated numbers, it wouldn't be hard to brute force the seed, and thus all the random numbers. –  amccausl Feb 10 '11 at 7:22
    
So, basically just re-seeding the generator for every value.. why didn't I think of that. Very nice, thanks. I might use that. @amccausl: in my particular application security isn't important, it's for a short-term statistical study, not any kind of long-running web service or OS daemon, but you've got a good point. –  Steve Feb 10 '11 at 14:55
    
Note that you can use a cryptographic primitive (e.g., a block cipher) in exactly the same way (this is called the counter mode of operation, and is quite common). It may or may not give you better properties than using a more typical PRNG. (this was also mentioned in Jeremiah Willcock's answer) –  John Bartholomew Feb 10 '11 at 16:00

This seems like it might be useful, but you would need to generate increasingly larger trees as the list gets longer: http://www.codeproject.com/KB/recipes/persistentdatastructures.aspx#RandomAccessLists (it is a log(n) structure, though). Something like http://research.janelia.org/myers/Papers/applicative.stack.pdf might be useful as well, but I don't see off hand how to make it work efficiently (with shared structure) when the list is generated dynamically.

One possible approach would be to use a pseudorandom number generator that allows "leapfrogging," or skipping forward n steps in sub-linear time. One method (that is slow, but works in constant time) is to use a block cipher in counter mode; see http://en.wikipedia.org/wiki/Cryptographically_secure_pseudorandom_number_generator#Designs_based_on_cryptographic_primitives. See http://cs.berkeley.edu/~mhoemmen/cs194/Tutorials/prng.pdf for more information.

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"there are some pseudorandom number generators that have constant or logarithmic time access to any element in their output sequence" This I did not know actually. However, for statistical purposes it should be as well-distributed as possible, but I'd like to know about that regardless, I'll look it up. –  Steve Feb 10 '11 at 4:02
    
@Steve: I added the info from my comments into the answer, so I'll remove the comments. –  Jeremiah Willcock Feb 10 '11 at 4:17

Not an answer, but a consideration: note that any standard technique for generating a list of random values will involve threading through a seed. So if I generate a lazy random infinite list and force the value of the 100th element, that forces not only the spine of the cons cells 0-99 but also their values as well.

In any case, I'd recommend lazy storable vectors: http://hackage.haskell.org/package/storablevector

You still have O(n) access, but you've reduced it by the factor of your chunk size, so in practice this is much faster than a plain list. And you still get, modulo chunk size, the laziness properties you're interested in.

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Very nice, thanks, that's along the lines of what I was thinking. Sure is hard to get familiar with all the options available on Hackage.. ;) –  Steve Feb 10 '11 at 14:53

What about Data.Sequence.Seq? It's not lazy, but it does support O(1) appends at either end, and lookups are O(log(min(i,n-i))), which should be better than most other tree structures. You could keep a Seq and generate/append more outputs as necessary.

There's also an instance for ListLike if you prefer that API over the one provided by Seq.

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Great to know about Seq, thanks. –  Steve Feb 10 '11 at 14:53

One thing you could do is create a list of arrays. So if each array stores M elements of your sequence, then accessing element n is O(n/M). This might be a good middle ground.

For example:

import Data.Array
import Data.List

fibsList :: (Num a) => [a]
fibsList = 1 : 1 : zipWith (+) fibsList (tail fibsList)

chunkSize :: (Num a, Ix a) => a
chunkSize = 100000

fibsChunks :: (Num i, Ix i, Num e) => [Array i e]
fibsChunks = mkChunks fibsList
  where mkChunks fs = listArray (0,chunkSize-1) xs : mkChunks ys
          where (xs,ys) = splitAt chunkSize fs

lookupFib :: (Integral i, Ix i, Num e) => i -> e
lookupFib n = fibsChunks `genericIndex` q ! r
  where (q,r) = n `divMod` chunkSize
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1  
That's the same thing as the storable vector solution I proposed earlier. –  sclv Feb 10 '11 at 16:21
    
@sclv: right you are! –  rampion Feb 10 '11 at 16:25

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