There's already two answers here that are correct, but I often think a fully laid out
proof can make things clearer. You said you wanted an answer for a 9-year-old, but
I don't think it's feasible (I think it's easy to *be fooled into thinking it's true*
without actually having any intuition for why it's true). Maybe working through this answer will help.

First off, the outer loop runs `n`

times clearly because `i`

is not modified
within the loop. The only code within the loop that could run more than once is
the block

```
while (j > 0 && s[i] != s[j])
{
j = pi[j-1]
}
```

So how many times can that run? Well notice that every time that condition is
satisfied we decrease the value of `j`

which, at this point, is at most
`pi[i-1]`

. If it hits 0 then the `while`

loop is done. To see why this is important,
we first prove a lemma (you're a very smart 9-year-old):

```
pi[i] <= i
```

This is done by induction. `pi[0] <= 0`

since it's set once in the initialization of `pi`

and never touched again. Then inductively we let `0 < k < n`

and assume
the claim holds for `0 <= a < k`

. Consider the value of `p[k]`

. It's set
precisely once in the line `pi[i] = j`

. Well how big can `j`

be? It's initialized
to `pi[k-1] <= k-1`

by induction. In the while block it then may be updated to `pi[j-1] <= j-1 < pi[k-1]`

. By another mini-induction you can see that `j`

will never increase past `pi[k-1]`

. Hence after the
`while`

loop we still have `j <= k-1`

. Finally it might be incremented once so we have
`j <= k`

and so `pi[k] = j <= k`

(which is what we needed to prove to finish our induction).

Now returning back to the original point, we ask "how many times can we decrease the value of
`j`

"? Well with our lemma we can now see that every iteration of the `while`

loop will
monotonically decrease the value of `j`

. In particular we have:

```
pi[j-1] <= j-1 < j
```

So how many times can this run? At most `pi[i-1]`

times. The astute reader might think
"you've proven nothing! We have `pi[i-1] <= i-1`

but it's inside the while loop so
it's still `O(n^2)`

!". The slightly more astute reader notices this extra fact:

However many times we run `j = pi[j-1]`

we then decrease the value of `pi[i]`

which shortens the next iteration of the loop!

For example, let's say `j = pi[i-1] = 10`

. But after ~6 iterations of the `while`

loop we have
`j = 3`

and let's say it gets incremented by 1 in the `s[i] == s[j]`

line so `j = 4 = pi[i]`

.
Well then at the next iteration of the outer loop we start with `j = 4`

... so we can only execute the `while`

at most 4 times.

The final piece of the puzzle is that `++j`

runs at most once per loop. So it's not like we can have
something like this in our `pi`

vector:

```
0 1 2 3 4 5 1 6 1 7 1 8 1 9 1
^ ^ ^ ^ ^
Those spots might mean multiple iterations of the while loop if this
could happen
```

To make this actually formal you might establish the invariants described above and then use induction
to show that the *total* number of times that `while`

loop is run, summed with `pi[i]`

is at most `i`

.
From that, it follows that the *total* number of times the `while`

loop is run is `O(n)`

which means that the entire outer loop has complexity:

```
O(n) // from the rest of the outer loop excluding the while loop
+ O(n) // from the while loop
=> O(n)
```