Parallel algorithms O(log p)

First off this isn't for any homework question, it's just on a general type of algorithm. In a parallel computing course I'm taking I'm having trouble wrapping my head around a style of algorithm that has runtime O( something + ... log p). For example we've looked at sequence reduction algorithms that are O(n/p + log p) where p = #procs and n is problem size. Log base 2.

The problem I have is the idea of log(p). For one I'm used to seeing log(n) everywhere in reducing problems to two subproblems of size n/2 etc. The second is just the idea of having the step complexity of an algorithm as log(p). Because that would imply that for a problem of fixed size if I increase the number of processors then I am increasing the number of steps in the algorithm? I have always thought of the step complexity of an algorithm as the sort of inherent sequential aspect of the algorithm and hence increasing or decreasing the number of processors shouldn't have any effect on this. Is this a bad way to think of it?

I guess what would be helpful is some pseudocode of algorithms that have log(p) running time somewhere in them.

-
"where p = #procs" sorry, should have put that at the top –  WtLgi Sep 3 '11 at 17:24
How huge is p. Is it about real systems (up to 32), huge real systems (up to 1k or 200-300 k for top supercomputer) or theoretical (p is unlimited) –  osgx Sep 3 '11 at 17:28
Just strictly theoretical. No notions of overhead due to thread creation or communication across nodes or anything. –  WtLgi Sep 3 '11 at 17:33
Can you give us an example of an algorithm with that running time? Looking at an actual algorithm will help us point out where that factor comes from. Outside of that, log(p) factors like that tend to arise from dissemination of the input to all processors and amalgamation of the results. –  Aubrey da Cunha Sep 3 '11 at 18:36