This is the easy version of the problem. The only difference between the two versions is the constraint on $k$. You can make hacks only if all versions of the problem are solved.

In this statement, all strings are $0$-indexed.

For two strings $a$, $b$ of the same length $p$, we define the following definitions:

• The hamming distance between $a$ and $b$, denoted as $h(a, b)$, is defined as the number of positions $i$ such that $0 \le i < p$ and $a_i \ne b_i$.
• $b$ is a cyclic shift of $a$ if there exists some $0 \leq k < p$ such that $b_{(i+k) \bmod p} = a_i$ for all $0 \le i < p$. Here $x \bmod y$ denotes the remainder from dividing $x$ by $y$.

You are given two binary strings $s$ and $t$ of length $2^{k+1}$ each. Both strings may contain missing characters (denoted by the character '?'). Your task is to count the number of ways to replace the missing characters in both strings with the characters '0' or '1' such that:

• Each string $s$ and $t$ contains exactly $2^k$ occurrences of each character '0' and '1'
• $h(s, c) \ge 2^k$ for all strings $c$ that is a cyclic shift of $t$.

As the result can be very large, you should print the value modulo $998\,244\,353$.

The first line of the input contains a single integer $k$ ($1 \le k \le 7$).

The second line of the input contains string $s$ of size $2^{k+1}$, consisting of the characters '0', '1' and '?'.

The third line of the input contains string $t$ of size $2^{k+1}$, consisting of the characters '0', '1' and '?'.

It is guaranteed that both strings $s$ and $t$ contains no more than $2^k$ character '0' or '1'.

Print a single integer — the answer to the problem modulo $998\,244\,353$.