If your program's memory is limited to a fixed set of stacks (and, I'm assuming, registers), then the behavior of the program can be determined solely from the PC register and the tops of all of these stacks. Since these stacks have a predetermined fixed size, you could simulate the behavior of the entire system as a finite automaton. In particular:
The automaton has a single state for every possible configuration of the bits of these stacks plus the registers. This might make the automaton exponentially huge, but it's still finite.
The automaton has transitions between two different states if, if the program were in the first state, the program would execute an instruction that would change memory in a way that caused it to look like the memory configuration in the second state.
Consequently, your program could be no stronger than a DFA. The sequence of transitions through its states could thus be described using a regular language, so your program could not, for example, print out balanced series of parentheses, or print out all the prime numbers, etc.
However, it is substantially weaker than a DFA. If all memory has to be stored in finitely many stacks, then you can't run the program on inputs any larger than all of the stacks put together (since you wouldn't have space to store the input). Consequently, your program would essentially work by being a DFA that begins in one of many possible states corresponding to the initial configuration of the stacks. Thus your program could have only finitely many possible sequences of behaviors.