I don't think that you'll be able to do the same thing with the lock function, since you would be trying to yield from within it. Having said that, this looks like a dangerous approach in either language, since it means that the lock can be held for an arbitrary amount of time (e.g. if one thread calls
Enumerate() but doesn't enumerate all the way through the resulting
IEnumerable<_>, then the lock will continue to be held).
It may make more sense to invert the logic, providing an
iter method along the lines of:
let iter f =
if synchronize then
lock locker (fun () -> Seq.iter f dict)
Seq.iter f dict
This brings the iteration back under your control, ensuring that the sequence is fully iterated (assuming that
f doesn't block, which seems like a necessary assumption in any case) and that the lock is released immediately thereafter.
Here's an example of code that could hold the lock forever.
let cached = enumerate() |> Seq.cache
let firstFive = Seq.take 5 cached |> Seq.toList
We've taken the lock in order to start enumerating through the first 5 items. However, we haven't continued through the rest of the sequence, so the lock won't be released (maybe we would enumerate the rest of the way later based on user feedback or something, in which case the lock would finally be released).
In most cases, correctly written code will ensure that it disposes of the original enumerator, but there's no way to guarantee that in general. Therefore, your sequence expressions should be designed to be robust to only being enumerated part way. If you intend to require your callers to enumerate the collection all at once, then forcing them to pass you the function to apply to each element is better than returning a sequence which they can enumerate as they please.