Reading the question and the code I would also say (A). I am assuming that the processes cannot be preempted before completing their task.
It says the initial state is
S2=0, and from what we know
P2 will execute exactly once.
Concurrent processes can be complex and however I try to describe the flow people will find faults with the way I think about it, that is ok, I'm here to learn too.
Now you have a few situations yielding different results depending on order of processes.
P0 -> P1 -> P0 -> P2 -> P0 = Three times
P0 -> P1 -> P2 -> P0 = Twice
P0 -> P2 -> P1 -> P0 = Twice
This gives us the answer of at least twice.
All this is made under the assumption of wait() blocking while semaphore == 0 and that release() sets semaphore = 1 because otherwise the code would just mostly be insanity.
If the processes can be interrupted at any time, then things can get interesting.
P0 starts out running because S0=1 at start
P0 print '0';
-- here S1 may take over or not --
-- here S2 may take over or not --
P0 goes back to wait(S0)
-- here P0 continues or if S1 *and* S2 have not run blocks --
-- it may also be that only S1 or S2 ran and now the other will run --
Now I tried figuring out a way to visualize how things would work out, and I failed to find a way good to put it in the code block.
If both S1 and S2 runs as soon as they can, since the semaphores are binary and can be in only one of two states, P0 will only be run twice, however if scheduling is perverse enough to delay either S1 or S2 until P0 has passed wait() once more P0 will run three times.
But I think this question was not meant to have interruptable processes, it just gets messy.