Suppose you have a decision problem A and you wish to prove that it is NP-Complete then the way to do it is, take an existing NP-Complete problem and reduce it to A.
What I mean by reduction here is a polynomial time reduction.
So suppose you wanted to show that 3-SAT is NP-Complete then you can show a reduction from the SAT problem.
The important thing to note here is that the reduction must be poly-time. It doesn't matter whether you call solve_A() multiple times. You can choose to call solve_A() multiple times as long as you make a polynomial number of calls to solve_A().
Why does it work? You can prove it by contradiction.
Suppose you had a poly-time algorithm for 3SAT. Then you could solve SAT also in poly-time. Since a polynomial number of calls to a polynomial function is still polynomial.
So unless P=NP, this would imply that SAT can also be solved in polynomial time using the newly discovered poly-time algorithm for 3SAT. But we know that SAT is NP-Complete, hence 3SAT must also be NP-Complete.
In short, to show NP-Completeness two things are required.
Existence of a certificate.
A reduction from an existing NP-Complete problem.