Big O is asymptotic notation. To use big O, you need a **function** - in other words, the expression must be parametrized by n, even if n is not used. It makes no sense to say that the number 5 is O(n), it's the constant function f(n) = 5 that is O(n).

So, to analyze time complexity in terms of big O you need a function of n. Your algorithm always makes arguably 0 steps, but without a varying parameter talking about asymptotic behaviour makes no sense. Assume that your algorithm is parametrized by n. Only now you may use asymptotic notation. It makes no sense to say that it is O(n^{2}), or even O(1), if you don't specify what is n (or the variable hidden in O(1))!

As soon as you settle on the number of steps, it's a matter of the definition of big O: the function f(n) = 0 is O(0).

Since this is a low-level question it depends on the model of computation.
Under "idealistic" assumptions, it is possible you don't do anything.
But in Python, you cannot say `def f(x):`

, but only `def f(x): pass`

. If you assume that every instruction, even `pass`

(NOP), takes time, then the complexity is f(n) = c for some constant c, and unless `c != 0`

you can only say that `f`

is O(1), not O(0).

It's worth noting big O by itself does not have anything to do with algorithms. For example, you may say sin x = x + O(x^{3}) when discussing Taylor expansion. Also, O(1) does not mean constant, it means bounded by constant.