There is a frog staying to the left of the string $s = s_1 s_2 \ldots s_n$ consisting of $n$ characters (to be more precise, the frog initially stays at the cell $0$). Each character of $s$ is either 'L' or 'R'. It means that if the frog is staying at the $i$-th cell and the $i$-th character is 'L', the frog can jump only to the left. If the frog is staying at the $i$-th cell and the $i$-th character is 'R', the frog can jump only to the right. The frog can jump only to the right from the cell $0$.

Note that the frog can jump into the same cell twice and can perform as many jumps as it needs.

The frog wants to reach the $n+1$-th cell. The frog chooses some positive integer value $d$ before the first jump (and cannot change it later) and jumps by no more than $d$ cells at once. I.e. if the $i$-th character is 'L' then the frog can jump to any cell in a range $[max(0, i - d); i - 1]$, and if the $i$-th character is 'R' then the frog can jump to any cell in a range $[i + 1; min(n + 1; i + d)]$.

The frog doesn't want to jump far, so your task is to find the minimum possible value of $d$ such that the frog can reach the cell $n+1$ from the cell $0$ if it can jump by no more than $d$ cells at once. It is guaranteed that it is always possible to reach $n+1$ from $0$.

You have to answer $t$ independent test cases.

The first line of the input contains one integer $t$ ($1 \le t \le 10^4$) — the number of test cases.

The next $t$ lines describe test cases. The $i$-th test case is described as a string $s$ consisting of at least $1$ and at most $2 \cdot 10^5$ characters 'L' and 'R'.

It is guaranteed that the sum of lengths of strings over all test cases does not exceed $2 \cdot 10^5$ ($\sum |s| \le 2 \cdot 10^5$).

For each test case, print the answer — the minimum possible value of $d$ such that the frog can reach the cell $n+1$ from the cell $0$ if it jumps by no more than $d$ at once.