When I have to implement Dijkstra's algorithm, I usually do it using a binary heap *without* a decrease_key operation.

To do that, you put (cost,vertex) records in the heap, and whenever the cost for a vertex goes down, you just put in a new one. When you pop a vertex out of the heap, then, just ignore it if it's already done. You have to keep track of which vertexes are done anyway, so that is easy.

This takes a bit more space, but the complexity remains O(|E| log V) (which is the same as O(|V+E| log |V|) or O(|E| log |E|) for the connected component that the algorithm will traverse )

Now the factor of log|E| above derives from the fact that there are up to |E| elements in the heap. If you group all elements with the same priority into lists and put those lists in the priority queue, then the that log |E| factor turns into log(number of distinct priorities). Note that a heap array ceases to be an appropriate structure for the priority queue, but various kinds of ordered trees work fine. It's easy when you don't need decrease_key.

In your case, the difference in cost between vertexes at the front of the priority queue, and the highest cost in the priority queue is at most 2^W. That implies that there are at most 2^W distinct priorities in the queue and the complexity of Dijkstra's algorithm using this kind of priority queue is O(|E|W).

Since you don't want to allocate 2^W buckets, a Patricia tree of linked lists would make a viable priority queue for your case.

O(VW+E)*, it is alreadyO((V+E) W), since the former is complexity-wisefaster. – Willem Van Onsem Jan 24 '19 at 19:28