In what seems to me a common implementation of quicksort, the program is composed of a partitioning subroutine and two recursive calls to quicksort those (two) partitions.
So the flow of control, in the quickest and pseudo-est of pseudocode, goes something like this:
quicksort[list, some parameters] . . . q=partition[some other parameters] quicksort[1,q] quicksort[q+1,length[list]] . . . End
The q is the "pivot" after a partitioning. That second quicksort call--the one that'll quicksort the second part of the list, also uses q. This is what I don't understand. If the "flow of control" is going through the first quicksort first, q is going to be updated. How is the same q going to work in the second quicksort, when it comes time to do the second parts of all those partitions?
I think my misunderstanding comes from the limitations of pseudocode. There are details that have been likely left out by expressing this implementation of the quicksort algorithm in pseudocode.
Edit 1 This seems related to my problem:
For[i = 1, i < 5, i = i + 1, Print[i]]
The first time through, we would get i=1, true, i=2, 1. Even though i was updated to 2, i is still 1 in body (i.e., Print[i]=1). This "flow of control" is what I don't understand. Where is the i=1 being stored when it increments to 2 and before it gets to body?
As an example of what I'm trying to get at, I'm pasting this here. It's from here.
Partition(A,p,r) x=A[r] i=p+1 j=r+1 while TRUE repeat j=j-1 until A[j]<=x repeat i=i+1 until A[i]>=x if i<j then exchange A[i] with A[j] else return j Quicksort(A,1,length[A]) Quicksort(A,p,r) if p<r then q=Partition(A,p,r) Quicksort(A,p,q) Quicksort(A,q+1,r)
Where or when in these algorithms is q being put onto a stack?