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1766\. Tree of Coprimes

Hard

There is a tree (i.e., a connected, undirected graph that has no cycles) consisting of `n` nodes numbered from `0` to `n - 1` and exactly `n - 1` edges. Each node has a value associated with it, and the **root** of the tree is node `0`.

To represent this tree, you are given an integer array `nums` and a 2D array `edges`. Each `nums[i]` represents the ith node's value, and each edges[j] = [uj, vj] represents an edge between nodes uj and vj in the tree.

Two values `x` and `y` are **coprime** if `gcd(x, y) == 1` where `gcd(x, y)` is the **greatest common divisor** of `x` and `y`.

An ancestor of a node `i` is any other node on the shortest path from node `i` to the **root**. A node is **not** considered an ancestor of itself.

Return _an array_ `ans` _of size_ `n`, _where_ `ans[i]` _is the closest ancestor to node_ `i` _such that_ `nums[i]` _and_ `nums[ans[i]]` are **coprime**, or `-1` _if there is no such ancestor_.

**Example 1:**

**![](https://assets.leetcode.com/uploads/2021/01/06/untitled-diagram.png)**

**Input:** nums = [2,3,3,2], edges = [[0,1],[1,2],[1,3]]

**Output:** [-1,0,0,1]

**Explanation:** In the above figure, each node's value is in parentheses. 

- Node 0 has no coprime ancestors. 

- Node 1 has only one ancestor, node 0. Their values are coprime (gcd(2,3) == 1). - Node 2 has two ancestors, nodes 1 and 0. Node 1's value is not coprime (gcd(3,3) == 3), but node 0's value is (gcd(2,3) == 1), so node 0 is the closest valid ancestor. 

- Node 3 has two ancestors, nodes 1 and 0. It is coprime with node 1 (gcd(3,2) == 1), so node 1 is its closest valid ancestor.

**Example 2:**

![](https://assets.leetcode.com/uploads/2021/01/06/untitled-diagram1.png)

**Input:** nums = [5,6,10,2,3,6,15], edges = [[0,1],[0,2],[1,3],[1,4],[2,5],[2,6]]

**Output:** [-1,0,-1,0,0,0,-1]

**Constraints:**

*   `nums.length == n`
*   `1 <= nums[i] <= 50`
*   1 <= n <= 105
*   `edges.length == n - 1`
*   `edges[j].length == 2`
*   0 <= uj, vj < n
*   uj != vj




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