I'm trying to understand how to prove efficiently using Z3 that a somewhat simple function `f : u32 -> u32`

is bijective:

```
def f(n):
for i in range(10):
n *= 3
n &= 0xFFFFFFFF # Let's treat this like a 4 byte unsigned number
n ^= 0xDEADBEEF
return n
```

I know already it is bijective since it's obtained by composition of bijective functions, so this is more of a computational question.

Now, knowing the domain and codomain are finite and of the same size, I thought of first doing this by asking Z3 to find a counterexample to it being injective:

```
N = BitVec('N', 32)
M = BitVec('M', 32)
solve(N != M, f(N) == f(M))
```

However this is taking quite a while (> 10 minutes but shut it down after), and reasonably so, since the search space is pretty much 64 bit and the function may be quite complex to reason about since it mixes a lot of multiplication with binary arithmetic, so I wondered whether it was possible instead to prove it by surjection, maybe resulting faster.

Whether that's actually faster or if there's even a way to solve this efficiently yet may be another question, however I was stuck on thinking how to prove it by surjection, that is ask Z3 to find an `M`

such that `f(N) != M forall N`

.

Is this anywhere different from proving injectivity?

How do I state it in Z3's python bindings?

Is it possible to remove existential qualifiers out of the surjective statement at all?

Are there more efficient ways to prove that a function is bijective? Since for something like this a bruteforce search may be more efficient, as the memory required shouldn't be a lot for 32 bit vectors, but the approach surely wouldn't work on 64 bit input/outputs.

`f`

is bijective, so is its composition with itself 10 times. I'm not sure if you can do a direct proof of this particular function here.) However, if you do manage to do this proof, I'd love to see how it's done. It would be quite educational, please do share your findings. – alias May 28 at 17:26