I would like to know the complexity (as in O(...) ) of the following sorting algorithm:

- There are B barrels
- that contain a total of N elements, spread unevenly across the barrels.
- The elements in each barrel are already sorted.

The sort combines all the elements from each barrel in a single sorted list:

- using an array of size B to store the last sorted element of each barrel (starting at 0)
- check each barrel (at the last stored index) and find the smallest element
- copy the element in the final sorted array, increment the array counter
- increment the last sorted element for the barrel we picked from
- perform those steps N times

or in pseudo code:

```
for i from 0 to N
smallest = MAX_ELEMENT
foreach b in B
if bIndex[b] < b.length && b[bIndex[b]] < smallest
smallest_barrel = b
smallest = b[bIndex[b]]
result[i] = smallest
bIndex[smallest_barrel] += 1
```

I thought that the complexity would be O(n), but the problem I have with finding the complexity is that if B grows, it has a larger impact than if N grows because it adds another round in the B loop. But maybe that has no effect on the complexity?

`O(N*B)`

(so it could be`O(N^2)`

if N == B, or`O(N^3)`

if N == 2*B, or...) , because it looks like the size of B and N are fixed in this code snippet. – FrustratedWithFormsDesigner May 28 '10 at 19:33