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2550. Count Collisions of Monkeys on a Polygon
Description
There is a regular convex polygon with n vertices. The vertices are labeled from 0 to n - 1 in a clockwise direction, and each vertex has exactly one monkey. The following figure shows a convex polygon of 6 vertices.
Each monkey moves simultaneously to a neighboring vertex. A neighboring vertex for a vertex i can be:
- the vertex
(i + 1) % nin the clockwise direction, or - the vertex
(i - 1 + n) % nin the counter-clockwise direction.
A collision happens if at least two monkeys reside on the same vertex after the movement or intersect on an edge.
Return the number of ways the monkeys can move so that at least one collision happens. Since the answer may be very large, return it modulo 109 + 7.
Note that each monkey can only move once.
Example 1:
Input: n = 3 Output: 6 Explanation: There are 8 total possible movements. Two ways such that they collide at some point are: - Monkey 1 moves in a clockwise direction; monkey 2 moves in an anticlockwise direction; monkey 3 moves in a clockwise direction. Monkeys 1 and 2 collide. - Monkey 1 moves in an anticlockwise direction; monkey 2 moves in an anticlockwise direction; monkey 3 moves in a clockwise direction. Monkeys 1 and 3 collide. It can be shown 6 total movements result in a collision.
Example 2:
Input: n = 4 Output: 14 Explanation: It can be shown that there are 14 ways for the monkeys to collide.
Constraints:
3 <= n <= 109
Solutions
Solution 1: Mathematics (Fast Power)
According to the problem description, each monkey has two ways of moving, either clockwise or counterclockwise. Therefore, there are a total of $2^n$ ways to move. The non-collision ways of moving are only two, that is, all monkeys move clockwise or all monkeys move counterclockwise. Therefore, the number of collision ways of moving is $2^n - 2$.
We can use fast power to calculate the value of $2^n$, then use $2^n - 2$ to calculate the number of collision ways of moving, and finally take the remainder of $10^9 + 7$.
The time complexity is $O(\log n)$, where $n$ is the number of monkeys. The space complexity is $O(1)$.
-
class Solution { public int monkeyMove(int n) { final int mod = (int) 1e9 + 7; return (qpow(2, n, mod) - 2 + mod) % mod; } private int qpow(long a, int n, int mod) { long ans = 1; for (; n > 0; n >>= 1) { if ((n & 1) == 1) { ans = ans * a % mod; } a = a * a % mod; } return (int) ans; } } -
class Solution { public: int monkeyMove(int n) { const int mod = 1e9 + 7; using ll = long long; auto qpow = [&](ll a, int n) { ll ans = 1; for (; n; n >>= 1) { if (n & 1) { ans = ans * a % mod; } a = a * a % mod; } return ans; }; return (qpow(2, n) - 2 + mod) % mod; } }; -
class Solution: def monkeyMove(self, n: int) -> int: mod = 10**9 + 7 return (pow(2, n, mod) - 2) % mod -
func monkeyMove(n int) int { const mod = 1e9 + 7 qpow := func(a, n int) int { ans := 1 for ; n > 0; n >>= 1 { if n&1 == 1 { ans = ans * a % mod } a = a * a % mod } return ans } return (qpow(2, n) - 2 + mod) % mod } -
function monkeyMove(n: number): number { const mod = 10 ** 9 + 7; const qpow = (a: number, n: number): number => { let ans = 1n; for (; n; n >>>= 1) { if (n & 1) { ans = (ans * BigInt(a)) % BigInt(mod); } a = Number((BigInt(a) * BigInt(a)) % BigInt(mod)); } return Number(ans); }; return (qpow(2, n) - 2 + mod) % mod; }