You could generate a list of all possible pops of the stack and then simulate:

However, there are going to be duplicates, consider the case when there are only two elements on each stack. If a is pushed to c and b to d, it doesn't matter which order they are pushed.

```
def simulate(steps):
source={'a':range(4),'b':range(4,8)}
res = {'c':"",'d':""};
for i,step in enumerate(steps):
res[step[1]]+=str(source[step[0]].pop())
# this is what each stack will look like
return res['c']+'-'+res['d']
def steps(a_left,b_left):
ret = []
if a_left>0:
substeps = steps(a_left-1,b_left)
ret.extend( [ x + [('a','c')] for x in substeps] )
ret.extend( [ x + [('a','d')] for x in substeps] )
if b_left>0:
substeps = steps(a_left,b_left-1)
ret.extend( [ x + [('b','c')] for x in substeps] )
ret.extend( [ x + [('b','d')] for x in substeps] )
if(len(ret)==0):
return [[]]
return ret;
```

And the result:

```
>>> [x for x in steps(1,1)]
[[('b', 'c'), ('a', 'c')], [('b', 'd'), ('a', 'c')], [('b', 'c'), ('a', 'd')], [
('b', 'd'), ('a', 'd')], [('a', 'c'), ('b', 'c')], [('a', 'd'), ('b', 'c')], [('
a', 'c'), ('b', 'd')], [('a', 'd'), ('b', 'd')]]
>>> [simulate(x) for x in steps(1,1)]
['73-', '3-7', '7-3', '-73', '37-', '7-3', '3-7', '-37']
>>> len(set([simulate(x) for x in steps(4,4)]))
5136
```

If we consider two stacks with only one target stack, we can find the number of unique stacks at (2*n)!/(n!)^2. This is the same as the number of permutations of 8 elements, 4 of which are 'A's and 4 of which are 'B's. We can then assign them to each individual stack by dividing them up in to subsets - the number of subsets with N unique numbers per stack is going to be 2^(2^n)

```
(2^(2*n))/((2*n)!/(n!)^2)
```

I don't see a way to generate these more efficiently, though.