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I found a great haskell solution (source) for generating a Hofstadter sequence:

hofstadter = unfoldr (\(r:s:ss) -> Just (r, r+s:delete (r+s) ss)) [1..]

Now, I am trying to write such a solution in F#, too. Unfortunately (I am not really familar to F#) I had no success so far.

My problem is, that when I use a sequence in F#, it seems not to be possible to remove an element (like it is done in the haskell solution).
Other data structures like arrays, list or set which allow to remove elements are not generating an infinite sequence, but operate on certain elements, only.

So my question: Is it possible in F# to generate an infinite sequence, where elements are deleted?

Some stuff I tried so far:

Infinite sequence of numbers:

let infinite =
    Seq.unfold( fun state -> Some( state, state + 1) ) 1

Hofstadter sequence - not working, because there is no del keyword and there are more syntax errors

let hofstadter =
    Seq.unfold( fun (r :: s :: ss) -> Some( r, r+s, del (r+s) ss)) infinite

I thought about using Seq.filter, but found no solution, either.

share|improve this question
    
To get the same perf profile in F# you'll have to write this completely different. LazyList will work, but comes with linear memory growth. –  Daniel Feb 15 '13 at 15:15

3 Answers 3

up vote 4 down vote accepted

pad's solution is nice but, likely due to the way LazyList is implemented, stack overflows somewhere between 3-4K numbers. For curiosity's sake I wrote a version built around a generator function (unit -> 'a) which is called repeatedly to get the next element (to work around the unwieldiness of IEnumerable). I was able to get the first 10K numbers (haven't tried beyond that).

let hofstadter() =

  let delete x f =
    let found = ref false
    let rec loop() =
      let y = f()
      if not !found && x = y
      then found := true; loop()
      else y
    loop

  let cons x f =
    let first = ref true
    fun () -> 
      if !first
      then first := false; x
      else f()

  let next =
    let i = ref 0
    fun () -> incr i; !i

  Seq.unfold (fun next -> 
    let r = next()
    let s = next()
    Some(r, (cons (r+s) (delete (r+s) next)))) next
share|improve this answer
    
Thanks a lot - I accepted your solution, because it seems like the way you should go as a F# developer. –  tanascius Feb 20 '13 at 12:22

I think you need more than a delete function on sequence. Your example requires pattern matching on inifinite collections, which sequence doesn't support.

The F# counterpart of Haskell list is LazyList from F# PowerPack. LazyList is also potentially infinite and it supports pattern matching, which helps you to implement delete easily.

Here is a faithful translation:

open Microsoft.FSharp.Collections.LazyList

let delete x xs =  
    let rec loop x xs = seq {        
        match xs with
        | Nil -> yield! xs
        | Cons(x', xs') when x = x' -> yield! xs'
        | Cons(x', xs') ->
            yield x' 
            yield! loop x xs'
        }
    ofSeq (loop x xs)

let hofstadter =
    1I |> unfold (fun state -> Some(state, state + 1I))
       |> unfold (function | (Cons(r, Cons(s, ss))) -> 
                                 Some(r, cons (r+s) (delete (r+s) ss)) 
                           | _ -> None)
       |> toSeq

There are a few interesting things here:

  • Use sequence expression to implement delete to ensure that the function is tail-recursive. A non-tail-recursive version should be easy.
  • Use BigInteger; if you don't need too many elements, using int and Seq.initInfinite is more efficient.
  • Add a case returning None to ensure exhaustive pattern matching.
  • At last I convert LazyList to sequence. It gives better interoperability with .NET collections.

Implementing delete on sequence is uglier. If you are curious, take a look at Remove a single non-unique value from a sequence in F# for reference.

share|improve this answer
1  
"LazyList is also potentially infinite" It's important to note that, unlike seq<_>, it's not truly infinite. Each computed element remains accessible and therefore memory usage steadily increases as the list is traversed. seq<_>, on the other hand, is a forward-only cursor, which keeps memory use constant. –  Daniel Feb 15 '13 at 21:25
    
Thanks for your answer. Especially the reference to LazyList is very interesting (haven't heard of it before). –  tanascius Feb 20 '13 at 12:23

In fact, you can use filter and a design that follows the haskell solution (but, as @pad says, you don't have pattern matching on sequences; so I used lisp-style destruction):

let infinite = Seq.initInfinite (fun i -> i+1)

let generator = fun ss -> let (r, st)  = (Seq.head ss, Seq.skip 1 ss)                               
                          let (s, stt) = (Seq.head st, Seq.skip 1 st)
                          let srps     = seq [ r + s ]
                          let filtered = Seq.filter (fun t -> (r + s) <> t) stt
                          Some (r, Seq.append srps filtered)

let hofstadter = Seq.unfold generator infinite                               

let t10 = Seq.take 10 hofstadter |> Seq.toList
// val t10 : int list = [1; 3; 7; 12; 18; 26; 35; 45; 56; 69]

I make no claims about efficiency though!

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2  
It's a good thing you made that disclaimer. :) –  Daniel Feb 15 '13 at 16:18
    
yes, I merely wanted to show that there was a solution directly matching Tanascius' formulation. It would be interesting to know just how much worse a naive implementation like this is than @pad's. –  fairflow Feb 15 '13 at 16:56
    
To get the first 1K numbers: pad's - Real: 00:00:01.198, CPU: 00:00:01.248, GC gen0: 56, gen1: 28, gen2: 1; yours - Real: 00:00:53.166, CPU: 00:00:53.149, GC gen0: 1201, gen1: 6, gen2: 0. Yours takes 44x as long and GC's 21x as much. Huge difference. –  Daniel Feb 15 '13 at 17:02
    
And, for the curious, my version for comparison: Real: 00:00:00.081, CPU: 00:00:00.078, GC gen0: 2, gen1: 0, gen2: 0. –  Daniel Feb 15 '13 at 19:22
    
@Daniel: Did you compare both using bigint or both using int? –  pad Feb 15 '13 at 19:35

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