If you use a Fibonacci heap, then extracting the min is `O(lg V)`

amortized cost and updating an entry in it is `O(1)`

amortized.

If we use this pseudo code

```
while priorityQueue not empty
u = priorityQueue.exractMin()
for each v in u.adjacencies
if priorityQueue.contains(v) and needsWeightReduction(u, v)
priorityQueue.updateKeyWeight(u, v)
```

Assume that the implementation has constant time for both `priorityQueue.contains(v)`

and `needsWeightReduction(u, v)`

.

Something to note is that you can bound slightly tighter for checking adjacencies. While the outer loop runs `V`

times, and checking the adjacencies of any single node is at worst `V`

operations, you can use aggregate analysis to realize that you will never check for more than `E`

adjacencies(because theres only E edges). And `E <= V^2`

, so this is a slightly better bound.

So, you have the outer loop V times, and the inner loop E times. Extracting the min runs `V`

times, and updating an entry in the heap runs `E`

times.

```
V*lgV + E*1
= O(V lgV + E)
```

Again, since `E <= V^2`

you could use this fact to substitute and get

```
O(V lgV + V^2)
= O(V^2)
```

But this is a looser bound when considering sparse graphs(although correct).