Expected Value Again
Description
You are given integers $n$, $k$. Let's consider the alphabet consisting of $k$ different elements.
Let beauty $f(s)$ of the string $s$ be the number of indexes $i$, $1\le i<|s|$, for which prefix of $s$ of length $i$ equals to suffix of $s$ of length $i$. For example, beauty of the string $abacaba$ equals $2$, as for $i = 1, 3$ prefix and suffix of length $i$ are equal.
Consider all words of length $n$ in the given alphabet. Find the expected value of $f(s)^2$ of a uniformly chosen at random word. We can show that it can be expressed as $\frac{P}{Q}$, where $P$ and $Q$ are coprime and $Q$ isn't divided by $10^9 + 7$. Output $P\cdot Q^{-1} \bmod 10^9 + 7$.
The first and the only line contains two integers $n$, $k$ ($1\le n \le 10^5$, $1\le k\le 10^9$) — the length of a string and the size of alphabet respectively.
Output a single integer — $P\times Q^{-1} \bmod 10^9 + 7$.
Input
The first and the only line contains two integers $n$, $k$ ($1\le n \le 10^5$, $1\le k\le 10^9$) — the length of a string and the size of alphabet respectively.
Output
Output a single integer — $P\times Q^{-1} \bmod 10^9 + 7$.
Samples
2 3
333333336
1 5
0
100 1
9801
10 10
412377396
Note
In the first example, there are $9$ words of length $2$ in alphabet of size $3$ — $aa$, $ab$, $ac$, $ba$, $bb$, $bc$, $ca$, $cb$, $cc$. $3$ of them have beauty $1$ and $6$ of them have beauty $0$, so the average value is $\frac{1}{3}$.
In the third example, there is only one such word, and it has beauty $99$, so the average value is $99^2$.