# The Big O on the Dijkstra Fibonacci-heap solution

From Wikipedia: `O(|E| + |V| log|V|)`

From Big O Cheat List: `O((|V| + |E|) log |V|)`

I consider there is a difference between `E + V log V` and `(E+V) log V`, isn't there?

Because, if Wikipedia's one is correct, shouldn't it be shown as `O(|V| log |V|)` only then (Removing `|E|`) for a reason I do not understand?)?

What is the Big O of Dijkstra with Fibonacci-Heap?

The complexity of Dijkstra's shortest path algorithm is:

``````    O(|E| |decrease-key(Q)| + |V| |extract-min(Q)|)
``````

where `Q` is the min-priority queue ordering vertices by their current distance estimate.

For both a Fibonacci heap and a binary heap, the complexity of the extract-min operation on this queue is `O(log |V|)`. This explains the common `|V| log |V|` part in the sum. For a queue implemented with an unsorted array, the extract-min operation would have a complexity of `O(|V|)` (the whole queue has to be traversed) and this part of the sum would be `O(|V|^2)`.

In the remaining part of the sum (the one with the edge factor |E|), the `O(1)` v.s. `O(log |V|)` difference comes precisely from using respectively a Fibonacci heap as opposed to a binary heap. The decrease key operation which may happen for every edge has exactly this complexity. So the remaining part of the sum eventually has complexity `O(|E|)` for a Fibonacci heap and `O(|E| log |V|)` for a binary heap. For a queue implemented with an unsorted array, the decrease-key operation would have a constant-time complexity (the queue directly stores the keys indexed by the vertices) and this part of the sum would thus be `O(|E|)`, which is also `O(|V|^2)`.

To summarize:

• Fibonacci heap: `O(|E| + |V| log |V|)`
• binary heap: `O((|E| + |V|) log |V|)`
• unsorted array: `O(|V|^2)`

Since, in the general case `|E| = O(|V|^2)`, these can't be simplified further without making further assumptions on the kind of graphs dealt with.

• Ok, I think I have understood it. Just to make things clear for me: Because (talking about the `decrease-key(Q)`) Fibonacci-heap is `O(1)` then we have `O(E + V log V)` and binary-heap is `O(log V)` so we have `O((E+V) log V) = O(E log V + V log V)`. If that is correct, can't I say that Fibonacci-heap is just `O(V log V)` as `E` is actually `O(1)`? – Nikola Jan 12 '14 at 17:52
• @Nikola |E| is not O(1). In general |E| = O(|V|^2), so you just can't simplify `O(E + V log V)` to `O(V log V)` (unless you make some additional assumptions on the kind of graphs you're dealing with). – user3146587 Jan 12 '14 at 19:53
• But didn't you say exactly that? `In the remaining part of the sum, the O(1) v.s. O(log(|V|)) difference`? On the Dijkstra unsorted array the `O(E + V^2)` is simplified to `O(V^2)`, isn't `E` the same case here? – Nikola Jan 12 '14 at 20:04
• @Nikola Sorry this wasn't clear: a single `|decrease-key(Q)|` operation is `O(1)` with a Fibonacci heap and `O(log(|V|))` with a binary heap. Total there are `O(|E|)` decrease-key operations. With an unsorted array, `decrease-key(Q)` is `O(1)`, but there are still `O(|E|)` decrease-key operations. Still with an unsorted array, `extract-min(Q)` is `O(|V|)`. Hence the `O(|E| + |V|^2)` complexity for Dijkstra's algorithm with an unsorted array. However, as I wrote previously, `|E|` is `O(|V|^2)`, so this can be simplified further to just `O(|V|^2)`. – user3146587 Jan 12 '14 at 20:11
• @JaviV For rectangular grids `|E|=O(|V|)` (for instance, a N x M grid with |V| = N M vertices has |E| = N (M - 1) + M (N - 1) = O(N M) = O(|V|) edges). Consequently on such a grid, Dijkstra with a Fibonacci heap is `O(|V| + |V| log |V|) = O(|V| log |V|)` and Dijkstra with a binary heap is `O((|V| + |V|) log |V|) = O(|V| log |V|)`. In both cases, `|E|` "disappears" (either being dominated by another term or because it does not add anything). – user3146587 Apr 9 '14 at 22:27

Dijkstra's is O(|E| + |V| log|V|) with Fibonacci heap and O((|V| + |E|) log |V|) without it.

Both correct in some way. Big O Cheat List showing the most common implementation and Wiki the best there is.

O(|E| + |V| log|V|) isn't in O(|V| log|V|) btw. E is in O(|V|^2), not O(|V| log|V|).