You are given an array which is initially empty. You need to perform $n$ operations of the given format:

• "$a$ $l$ $r$ $k$": append $a$ to the end of the array. After that count the number of integer pairs $x, y$ such that $l \leq x \leq y \leq r$ and $\operatorname{mex}(a_{x}, a_{x+1}, \ldots, a_{y}) = k$.

The elements of the array are numerated from $1$ in the order they are added to the array.

To make this problem more tricky we don't say your real parameters of the queries. Instead your are given $a'$, $l'$, $r'$, $k'$. To get $a$, $l$, $r$, $k$ on the $i$-th operation you need to perform the following:

• $a := (a' + lans) \bmod(n + 1)$,
• $l := (l' + lans) \bmod{i} + 1$,
• $r := (r' + lans) \bmod{i} + 1$,
• if $l > r$ swap $l$ and $r$,
• $k := (k' + lans) \bmod(n + 1)$,

The $\operatorname{mex}(S)$, where $S$ is a multiset of non-negative integers, is the smallest non-negative integer which does not appear in the set. For example, $\operatorname{mex}(\{2, 2, 3\}) = 0$ and $\operatorname{mex} (\{0, 1, 4, 1, 6\}) = 2$.

The first line contains a single integer $n$ ($1 \leq n \leq 2 \cdot 10^5$) — the length of the array.

The next $n$ lines contain the description of queries.

Each of them $n$ lines contains four non-negative integers $a'$, $l'$, $r'$, $k'$ ($0, \leq a', l', r', k' \leq 10^9$), describing one operation.

For each query print a single integer — the answer to this query.