# Should this sequence expression be tail-recursive?

This F# seq expression looks tail-recursive to me, but I'm getting stack overflow exceptions (with tail-calls enabled). Does anybody know what I'm missing?

``````let buildSecondLevelExpressions expressions =
let initialState = vector expressions |> randomize
let rec allSeq state = seq {
for partial in state do
if count partial = 1
if count partial > 1 || (count partial = 1 && depth (Seq.head partial) <= MAX_DEPTH) then
let allUns = partial
|> pick false 1
|> Seq.collect (fun (el, rr) -> (createExpUnaries el |> Seq.map (fun bn -> add rr bn)))
let allBins = partial  // Careful: this case alone produces result recursivley only if |numbers| is even (rightly!).
|> pick false 2
|> Seq.collect (fun (el, rr) -> (createExpBinaries el |> Seq.map (fun bn -> add rr bn)))
yield! allSeq (interleave allBins allUns)
}
allSeq initialState
``````

If you're wondering, though it shouldn't be important, `pick` is used to generate combinations of elements in a sequence and `interleave` interleaves elements from 2 sequences. `vector` is a constructor for a `ResizeArray`.

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`yield! allSeq ...` is inside a for loop. It is not tail recursive. –  Yin Zhu Jul 16 '10 at 13:46
@Yin: `yield!` is not tail recursive at all, e.g. enumerating `let rec xs() = seq {yield! xs()}` also stack overflows. –  Jon Harrop Jul 17 '10 at 19:22
`yield!` is tail-recursive when it is in a tail-call position, but it doesn't seem to work in the degenerated example that Jon posted (which I think is a bug). However, in all realistic examples, this should work. –  Tomas Petricek Jul 18 '10 at 20:07

As Gideon pointed out, this is not tail-recursive, because you still have other elements in the 'state' list to process. Making this tail-recursive isn't straightforward, because you need some queue of elements that should be processed.

The following pseudo-code shows one possible solution. I added `work` parameter that stores the remaining work to be done. At every call, we process just the first element. All other elements are added to the queue. When we finish, we pick more work from the queue:

``````let rec allSeq state work = seq {
match state with
| partial::rest ->
// Yield single thing to the result - this is fine
if count partial = 1 then yield Seq.head partial
// Check if we need to make more recursive calls...
if count partial > 1 || (* ... *) then
let allUns, allBins = // ...
// Tail-recursive call to process the current state. We add 'rest' to
// the collected work to be done after the current state is processed
yield! allSeq (interleave allBins allUns) (rest :: work)
else
// No more processing for current state - let's take remaining
// work from the 'work' list and run it (tail-recursively)
match work with
| state::rest -> yield! allSeq state rest
| [] -> () //completed
| _ ->
// This is the same thing as in the 'else' clause above.
// You could use clever pattern matching to handle both cases at once
match work with
| state::rest -> yield! allSeq state rest
| [] -> () } //completed
``````
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Nice! Thanks Tomas! –  Mau Jul 16 '10 at 14:56
@Tomas Petricek -- is this a continuation? Seriously, I'm trying to understand the concept of a continuation and this looks like one to me. –  Onorio Catenacci Jul 16 '10 at 17:30
Have you tested it? I think it is wrong: you should never recurse inside a `yield`... –  Jon Harrop Jul 17 '10 at 19:34
@Jon: I didn't test it (it is pretty incomplete snippet), but I think that all recursive uses of `allSeq` are in tail-call position and are returned using `yield!` - the sequence expression compiler looks exactly for this case. –  Tomas Petricek Jul 17 '10 at 20:14
@Tomas: Surely if that were true you would be able to enumerate `let rec xs() = seq {yield! xs()}` yet that stack overflows. –  Jon Harrop Jul 17 '10 at 20:46

This is not going to be tail recursive because you could be calling recursively multiple times. To translate to a pseudo-code:

``````allSeq(state)
{
foreach (partial in state)
{
if (...)
{
yield ...
}
if (...)
{
...
//this could be reached multiple times
yield! allSeq(...)
}
}
}
``````
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Oohh yes, you're right. So dumb :-) –  Mau Jul 16 '10 at 13:44
Yes, it will generate a tree... –  Skilldrick Jul 16 '10 at 13:44
Now...how to make it TR... –  Mau Jul 16 '10 at 14:06

I cannot find a definition of which calls inside a sequence expression are in tail position in F# so I would strongly recommend not writing code that depends upon the semantics of the current implementation, i.e. this is undefined behaviour.

For example, trying to enumerate (e.g. applying `Seq.length`) the following sequence causes a stack overflow:

``````let rec xs() = seq { yield! xs() }
``````

but, as Tomas pointed out, the following does actually work:

``````let rec xs n = seq { yield n; yield! xs(n+1) }
``````

My advice is to always replace recursive sequence expressions with `Seq.unfold` instead. In this case, you probably want to accumulate the work to be done (e.g. when you recurse into a left branch you push the right branch onto the stack in the accumulator).

FWIW, even the F# language reference gets this wrong. It gives the following code for flattening a tree:

``````type Tree<'a> =
| Tree of 'a * Tree<'a> * Tree<'a>
| Leaf of 'a

let rec inorder tree =
seq {
match tree with
| Tree(x, left, right) ->
yield! inorder left
yield x
yield! inorder right
| Leaf x -> yield x
}
``````

Their own code kills F# interactive with a stack overflow when fed a deep tree on the left.

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I think you're wrong: yield!, let!, do! can be tail-recursive, just not in this case. +1 for Seq.unfold though, thanks. –  Mau Jul 18 '10 at 9:33
@Mau: Tomas has given me a counter example where a recursive call can be in tail position inside a sequence expression. However, without any clue as to when this occurs I would absolutely avoid depending upon it. –  Jon Harrop Jul 18 '10 at 19:14
@Jon: I think the case you posted could be a considered as a bug in F#, because all `yield!` in tail-call position should be optimized. I'll send a link to the F# team. –  Tomas Petricek Jul 18 '10 at 19:56
@Jon: I don't understand what are you referring to when you say "F# language reference gets this wrong". What does it get wrong? It doesn't claim that the solution doesn't stack-overflow (and I think it isn't a surprise for any functional programmers). –  Tomas Petricek Jul 18 '10 at 20:00
@Jon: I think it depends on how you understand computation expressions. My understanding is that they are just like standard F# computations with some additional aspect. This understanding suggests that e.g. stack overflow can be caused by similar patterns as in regular F# code. However, I agree that this should be clearly documented in the F# docs. Redarding C# documentation - I of course don't expect that loop will break, but I also don't expect that C# compiler will magicaly resolve NullReferenceExceptions in places where I see they can occur in their samples. –  Tomas Petricek Jul 18 '10 at 23:41