This should work:
public static IObservable<bool> IsAlive<T>(this IObservable<T> source,
return source.Buffer(timeout, 1, sched)
.Select(l => l.Any())
This approach makes semantic sense, too. Every time an item comes in, it fills the buffer and then true is passed along. And every timeout, an empty buffer will be created and false will be passed along.
This is why the buffer-1 approach is better than windowing:
var sched = new TestScheduler();
var subj = new Subject<Unit>();
var timeout = TimeSpan.FromTicks(10);
.Buffer(timeout, 1, sched)
.Subscribe(x => Console.WriteLine("Buffer(timeout, 1): " + x));
.Select(wind => wind.Any())
.SelectMany(a => a)
.Subscribe(x => Console.WriteLine("Window(timeout): "+x));
Buffer(timeout, 1): True
Buffer(timeout, 1): False
To be specific, the window is open for the whole timeout and doesn't close and reset as soon as an item comes in. This is where the buffer limit of 1 comes into play. As soon as an item comes in, the buffer and its timer get restarted.
I could re-implement my buffer as a window, as buffer's implementation is a window, but a) I think buffer makes better semantic sense and b) I don't have to SelectMany. Scott's Select and SelectMany could be combined into a single SelectMany(x => x.Any()), but I can avoid the entire lambda and specify the Enumerable.Any method group, which will bind faster (trivial) anyway.