I'm working on a real-time application centered around a priority queue, which has a twist: I need to support "cancelations" of any event sitting in the queue.
Obviously the traditional implementation of a priority queue, a heap, doesn't lend itself well to this application because locating an arbitrary item for deletion is O(n).
If you have a pointer to an item, though, deletion is only O(log n). I figure I can do this by maintaining a hash table whose nodes are also linked together as a heap. This should allow for O(log n) insertion, deletion, and pop-max.
Then again, how is that better than a binary search tree? All operations there are also O(log n), so why maintain a cumbersome dual data structure?
It also seems to me like a skip list would be better overall; pop-max would be O(1), and other operations would be amortized O(log n).
And for some reason I keep coming back to the idea of a beap, which has O(sqrt n) performance for all operations.
I think any of these solutions would work, but my question is... Which would work best in a real-time system that strives to service requests with minimal latency? Asymptotic analysis is useful, but big-O notation doesn't tell you how expensive an individual operation is. My data set isn't huge -- a few thousand entries tops -- so although a binary search tree looks better on paper than a beap, the beap may very well outperform it in my case because it doesn't waste time with rebalancing operations.
Anyway, I was hoping someone had similar experiences here. A priority queue with cancelation support doesn't seem to be well-described, but it doesn't seem to me like it's THAT far-out of a problem that nobody else has implemented one before.