I'm trying to wrap my head around the concept of studying an algorithm's time complexity with respect to **bit cost** (instead of unit cost) and it seems to be impossible to find anything on the subject.

Here's what I have so far:

The bit cost of multiplication and division of two numbers with n bits is, with arbitrary arithmetics, O(n^2).

So, for example:

```
int number = 2;
for(int i = 0; i < n; i++ ){
number = i*i;
}
```

has a time complexity with respect to bit cost of O(log(n)^2*n), because it does n multiplications and `i`

has `log(i)`

bits.

But in a regular scenario we want the time complexity with respect to the input. So, how does that scenario work? The number of bits in `i`

could be considered a constant. Which would make the time complexity the same as with unit cost except with a bigger constant (and therefore both would be linear).

Addition, subtraction, comparisons and assigning variables are all O(n), n being the number of bits, for arbitrary precision arithmetic.