Boost Fibonacci Heap Decrease Operation

The new 'heap' boost library includes a fibonacci heap. The complexity of each implementation can be seen here: http://www.boost.org/doc/libs/1_51_0/doc/html/heap/data_structures.html.

My question is this: Why is the fibonacci heap decrease operation O(log(N)), while the increase operation is O(1)?

I would like to experiment with using the fibonacci heap in Dijkstra's algorithm, which is heavily dependent upon a fast decrease operation.

• Read the wikipedia article: en.wikipedia.org/wiki/Fibonacci_heap – Keith Randall Oct 2 '12 at 21:15
• The Wikipedia article only talks about the decrease key being amortised O(1). – user1487088 Oct 2 '12 at 21:39
• Well, min and max are swapped between the wikipedia article (which is a min heap) and the Boost library (which is a max heap). To use the Boost library for Dijkstra's, you'll have to reverse your score comparisons. – Keith Randall Oct 2 '12 at 21:49
• Ok, I am interpreting 'increase' as pushing an element closer to the top of the heap, and decrease and pushing an element further away from the top. Whether the top is the min or max element, it shouldn't matter? Is this correct? – user1487088 Oct 2 '12 at 22:35
• So with your interpretation, increase is amortized O(1) - that's the fundamental advantage of a Fibonacci heap. Decrease is O(log n) because all of the other standard heap operations have that complexity (you could implement decrease with delete + insert). – Keith Randall Oct 2 '12 at 23:12

Essentially it means that `decrease` and `increase` have inverse meanings between textbook and Boost.
If you want to get a min-heap (like the textbook definitions), you must first defined an appropriate `boost::heap::compare` functor for your `fibonacci_heap` (see an example here: Defining compare function for fibonacci heap in boost), then call `increase` whenever you decrease the value associated with a heap element (and are thus increasing the priority) and vice-versa.