I don't think you understand what complexity is referring to. Suppose you need to sum some elements:

(this sample is C but that doesn't matter)

```
int Sum( int *x, int n ) {
int r = 0;
for( int i = 0; i < n; ++ i ) {
r += x[i];
}
return r;
}
```

This has O(n) complexity. Nothing has been said about the encoding. It could be unary, binary, or trinary, but if we're *interested* in that aspect, we could say it is O(log_b(m)) where b is the base and m is the maximum number representable. Or we could combine these and say it's O(n*log_b(m))

But usually nobody cares about the complexity of adding numbers together or whatnot, so we just omit it. It's constant. It doesn't matter. The algorithm above has O(n) complexity, because n is an interesting parameter. And if something's O(n^2) or O(log(n)) or anything else, changing b (the base) won't ever change that.

Update:

To factor in some of the comments this has been getting, I think I should mention the case of m itself changing:

Suppose we have a factorial function:

```
int Factorial( int n ) {
int r = 1;
for( int i = 1; i <= n; ++ i ) {
r *= i;
}
return r;
}
```

Now we can say that m (the maximum representable number) can be equal to n. Thus the complexity, which is O(n) *and* O(log_b(m)) (each multiplication stage must loop through the entire represented number), so O(n*log_b(m)) can be seen as O(n*log_b(n)). HOWEVER, this relies on the idea that our input number does *not* have a fixed number of significant figures, but instead is the shortest representation within the current base.