An array is called beautiful if all the elements in the array are equal.

You can transform an array using the following steps any number of times:

1. Choose two indices $i$ and $j$ ($1 \leq i,j \leq n$), and an integer $x$ ($1 \leq x \leq a_i$). Let $i$ be the source index and $j$ be the sink index.
2. Decrease the $i$-th element by $x$, and increase the $j$-th element by $x$. The resulting values at $i$-th and $j$-th index are $a_i-x$ and $a_j+x$ respectively.
3. The cost of this operation is $x \cdot |j-i| $.
4. Now the $i$-th index can no longer be the sink and the $j$-th index can no longer be the source.

The total cost of a transformation is the sum of all the costs in step $3$.

For example, array $[0, 2, 3, 3]$ can be transformed into a beautiful array $[2, 2, 2, 2]$ with total cost $1 \cdot |1-3| + 1 \cdot |1-4| = 5$.

An array is called balanced, if it can be transformed into a beautiful array, and the cost of such transformation is uniquely defined. In other words, the minimum cost of transformation into a beautiful array equals the maximum cost.

You are given an array $a_1, a_2, \ldots, a_n$ of length $n$, consisting of non-negative integers. Your task is to find the number of balanced arrays which are permutations of the given array. Two arrays are considered different, if elements at some position differ. Since the answer can be large, output it modulo $10^9 + 7$.

3
1 2 3

6

4
0 4 0 4

2

5
0 11 12 13 14

120