This is a typical application of Newton's method for calculating the square root of `n`

. You're calculating the limit of the sequence:

```
x_0 = n
x_{i+1} = (x_i + n / x_i) / 2
```

Your variable `x`

is the current term `x_i`

and your variable `y`

is `n / x_i`

.

To understand why you have to calculate this limit, you need to think of the function:

```
f(x) = x^2 - n
```

You want to find the root of this function. Its derivative is

```
f'(x) = 2 * x
```

and Newton's method gives you the formula:

```
x_{i+1} = x_i - f(x_i) / f'(x_1) = ... = (x_i + n / x_i) / 2
```

For completeness, I'm copying here the rationale from @rodrigo's answer, combined with my comment to it. This is helpful if you want to forget about Newton's method and try to understand this algorithm alone.

The trick is that if `x`

is not the square root of `n`

, then it is
an approximation which lies either above or below the real root, and `y = n/x`

is always on the
other side. So if you calculate the midpoint of `(x+y)/2`

, it will be
nearer to the real root than the worst of these two approximations
(`x`

or `y`

). When `x`

and `y`

are close enough, you're done.

This will also help you find the complexity of the algorithm. Say that `d`

is the distance of the worst of the two approximations to the real root `r`

. Then the distance between the midpoint `(x+y)/2`

and `r`

is at most `d/2`

(it will help you if you draw a line to visualize this). This means that, with each iteration, the distance is halved. Therefore, the worst-case complexity is logarithmic w.r.t. to the distance of the initial approximation and the precision that is sought. For the given program, it is

```
log(|n-sqrt(n)|/epsilon)
```