So looking at the program, it appears to get all prime factors of `n`

and return the largest one. Let's go over it one line at a time:

```
while i * i < n:
```

This particular piece of code looks like a mistake at first, but it works when you realize that `n`

is continually growing smaller. The program is using repeated division to reduce `n`

to its largest prime factor.

```
while n%i == 0:
```

The operation `n % i`

returns the remainder of `n / i`

. So if `n % i == 0`

, then the current value of `i`

can evenly divide into `n`

, i.e. `i`

is a factor of `n`

.

```
n = n / i
```

Here, we are continually dividing `n`

by `i`

; we will keep doing this division until the `while`

condition is no longer true. We need to divide as many times as we can, as this has the effect of removing any possible composite factors. If our given number was 24, for example, we would divide it by 2 three times, eventually making `n`

equal to 3. This eliminates any possible composite factors that are a multiple of 2.

```
i = i + 1
```

Increment our number and repeat.

This works well because, by using `n = n / i`

repeatedly, we are removing successively larger prime factors from `n`

. The more of these prime factors we eliminate, the smaller `n`

gets, until it is eventually indivisible by anything except 1. At this point, `n`

is equal to the largest prime factor of the original number, and so we return it.

Now our stopping condition makes more sense, as well. At the time when `n`

becomes prime (the largest prime factor), then there is no value of `i`

we can produce that will be evenly divisible. We will know this when `i * i`

is greater than `n`

- if you have a composite number, then one of the factors is necessarily `>= n^1/2`

.

As mentioned by Ionut Hulub, this specific solution will fail if `n`

is any perfect square. As a safeguard against this, you should print out both `n`

and the largest `i`

that evenly divided the number.