Did you think there was going to be a JoJo legend here? But no, that was me, Dio!

Given a binary string $$$s$$$ of length $$$n$$$, consisting of characters 0 and 1. Let's build a square table of size $$$n \times n$$$, consisting of 0 and 1 characters as follows.

In the first row of the table write the original string $$$s$$$. In the second row of the table write cyclic shift of the string $$$s$$$ by one to the right. In the third row of the table, write the cyclic shift of line $$$s$$$ by two to the right. And so on. Thus, the row with number $$$k$$$ will contain a cyclic shift of string $$$s$$$ by $$$k$$$ to the right. The rows are numbered from $$$0$$$ to $$$n - 1$$$ top-to-bottom.

In the resulting table we need to find the rectangle consisting only of ones that has the largest area.

We call a rectangle the set of all cells $$$(i, j)$$$ in the table, such that $$$x_1 \le i \le x_2$$$ and $$$y_1 \le j \le y_2$$$ for some integers $$$0 \le x_1 \le x_2 < n$$$ and $$$0 \le y_1 \le y_2 < n$$$.

Recall that the cyclic shift of string $$$s$$$ by $$$k$$$ to the right is the string $$$s_{n-k+1} \ldots s_n s_1 s_2 \ldots s_{n-k}$$$. For example, the cyclic shift of the string "01011" by $$$0$$$ to the right is the string itself "01011", its cyclic shift by $$$3$$$ to the right is the string "01101".