# Create (pseudo) Cyclic Discriminated Unions in F#

I've run into a small problem here. I wrote the Tortoise and Hare cycle detection algorithm.

``````type Node =
| DataNode of int * Node
| LastNode of int

let next node =
match node with
|DataNode(_,n) -> n
|LastNode(_) -> failwith "Error"

let findCycle(first) =
try
let rec fc slow fast =
match (slow,fast) with
| LastNode(a),LastNode(b) when a=b -> true
| DataNode(_,a), DataNode(_,b) when a=b -> true
| _ -> fc (next slow) (next <| next fast)
fc first <| next first
with
| _ -> false
``````

This is working great for

``````  let first = DataNode(1, DataNode(2, DataNode(3, DataNode(4, LastNode(5)))))
findCycle(first)
``````

It shows false. Right. Now when try to test it for a cycle, I'm unable to create a loop!

Obviously this would never work:

``````  let first = DataNode(1, DataNode(2, DataNode(3, DataNode(4, first))))
``````

But I need something of that kind! Can you tell me how to create one?

-
I'm not sure that your algorithm does what you want - should `findCycle (DataNode(1, DataNode(1, LastNode 2)))` really evaluate to `true`? –  kvb Jan 26 '11 at 19:39
Thank you for pointing that out. I've changed it so that it checks if the Next nodes are same. –  asattar Jan 28 '11 at 11:40
Should you be using reference equality instead of structural equality? –  Jon Harrop Jan 30 '11 at 22:08

Here is one way:

``````  type Node =
| DataNode of int * Lazy<Node>
| LastNode of int

let next node = match node with |DataNode(_,n) -> n.Value |LastNode(_) -> failwith "Error"

let findCycle(first) =
try
let rec fc slow fast =
match (slow,fast) with
| LastNode(a),LastNode(b) when a=b->true
| DataNode(a,_), DataNode(b,_) when a=b -> true
| _ -> fc (next slow) (next <| next fast)
fc first <| next first
with
| _ -> false

let first = DataNode(1, lazy DataNode(2, lazy DataNode(3, lazy DataNode(4, lazy LastNode(5)))))
printfn "%A" (findCycle(first))

let rec first2 = lazy DataNode(1, lazy DataNode(2, lazy DataNode(3, lazy DataNode(4, first2))))
printfn "%A" (findCycle(first2.Value))
``````
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Is there a particular reason you made `first2` a function? It seems like what you created is an infinite list, whereas using `first2` and `lazy first2` in place of `first2()` and `Lazy.Create first2` would create a true cycle (e.g. iterating arbitrarily far would only require a constant amount of memory). –  kvb Jan 26 '11 at 21:48
You're right, I typed this up in a rush and got sloppy; I fixed it now. –  Brian Jan 27 '11 at 1:11

You can't do this with your type as you've defined it. See How to create a recursive data structure value in (functional) F#? for some alternative approaches which would work.

As an alternative to Brian's solution, you might try something like:

``````type Node =
| DataNode of int * NodeRec
| LastNode of int
and NodeRec = { node : Node }

let rec cycle = DataNode(1, { node =
DataNode(2, { node =
DataNode(3, { node =
DataNode(4, { node = cycle}) }) }) })
``````
-
Why does F# forbid recursive values using just union types when other languages like OCaml allow it? –  Jon Harrop Jan 27 '11 at 9:39
Jon: If you mean "type Node = Node of int * Node" it's perfectly valid F#. –  thr Jan 27 '11 at 19:19
@Jon - I can't answer authoritatively, but I suspect that it's partly due to code gen issues on the CLR - recursive values require mutability to tie the knot, but the value should be logically immutable. Even if the F# compiler hid the mutability, a mutable implementation would be visible from other .NET languages. Another potential reason is that structural equality and comparison don't handle infinite structures gracefully (e.g. `x = x` will blow up if `x` is a cyclic value). –  kvb Jan 27 '11 at 19:28
@thr: I mean value definitions like `let rec x = Node(3, x)`. Legal in OCaml. Illegal in F#. –  Jon Harrop Jan 27 '11 at 23:05
@kvb: But wouldn't those reasons apply equally to unions and records? –  Jon Harrop Jan 27 '11 at 23:06
show 1 more comment

Even though both Brian and kvb posted answers that work, I still felt I needed to see if it was possible to achieve the same thing in a different way. This code will give you a cyclic structure wrapped as a Seq<'a>

``````type Node<'a> = Empty | Node of 'a * Node<'a>

let cyclic (n:Node<_>) : _ =
let rn = ref n

let rec next _ =
match !rn with
| Empty -> rn := n; next Unchecked.defaultof<_>
| Node(v, x) -> rn := x; v

Seq.initInfinite next

let nodes = Node(1, Node(2, Node(3, Empty)))
cyclic <| nodes |> Seq.take 40 // val it : seq<int> = seq [1; 2; 3; 1; ...]
``````

The structure itself is not cyclic, but it looks like it from the outside.

Or you could do this:

``````//removes warning about x being recursive
#nowarn "40"

type Node<'a> = Empty | Node of 'a * Lazy<Node<'a>>

let rec x = Node(1, lazy Node(2, lazy x))

let first =
match x with
| Node(1, Lazy(Node(2,first))) -> first.Value
| _ -> Empty
``````
-

Can you tell me how to create one?

There are various hacks to get a directly cyclic value in F# (as Brian and kvb have shown) but I'd note that this is rarely what you actually want. Directly cyclic data structures are a pig to debug and are usually used for performance and, therefore, made mutable.

For example, your cyclic graph might be represented as:

``````> Map[1, 2; 2, 3; 3, 4; 4, 1];;
val it : Map<int,int> = map [(1, 2); (2, 3); (3, 4); (4, 1)]
``````

The idiomatic way to represent a graph in F# is to store a dictionary that maps from handles to vertices and, if necessary, another for edges. This approach is much easier to debug because you traverse indirect recursion via lookup tables that are comprehensible as opposed to trying to decipher a graph in the heap. However, if you want to have the GC collect unreachable subgraphs for you then a purely functional alternative to a weak hash map is apparently an unsolved problem in computer science.

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