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RedundantConnection.java
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RedundantConnection.java
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package Leetcode;
import java.util.Arrays;
/**
* @author kalpak
*
* In this problem, a tree is an undirected graph that is connected and has no cycles.
*
* The given input is a graph that started as a tree with N nodes (with distinct values 1, 2, ..., N), with one additional edge added.
* The added edge has two different vertices chosen from 1 to N, and was not an edge that already existed.
*
* The resulting graph is given as a 2D-array of edges. Each element of edges is a pair [u, v] with u < v,
* that represents an undirected edge connecting nodes u and v.
*
* Return an edge that can be removed so that the resulting graph is a tree of N nodes.
* If there are multiple answers, return the answer that occurs last in the given 2D-array.
* The answer edge [u, v] should be in the same format, with u < v.
*
* Example 1:
* Input: [[1,2], [1,3], [2,3]]
* Output: [2,3]
*
* Explanation: The given undirected graph will be like this:
* 1
* / \
* 2 - 3
*
* Example 2:
* Input: [[1,2], [2,3], [3,4], [1,4], [1,5]]
* Output: [1,4]
*
* Explanation: The given undirected graph will be like this:
* 5 - 1 - 2
* | |
* 4 - 3
*
* Note:
* The size of the input 2D-array will be between 3 and 1000.
* Every integer represented in the 2D-array will be between 1 and N, where N is the size of the input array.
*
*/
public class RedundantConnection {
public static int[] findRedundantConnection(int[][] edges) {
DisjointSet dsu = new DisjointSet(edges.length + 1);
for(int[] edge : edges) {
if(!dsu.union(edge[0], edge[1]))
return edge;
}
return new int[0];
}
static public class DisjointSet {
private int numberOfElements; // number of elements in union find
private int[] size; // track size of each component
private int[] id; // id[i] points to the parent of i, if id[i] = i, then i is the root node.
private int numOfComponents;
public DisjointSet(int size) {
if(size <= 0)
throw new IllegalArgumentException("Size <= 0 is not allowed.");
this.numberOfElements = numOfComponents = size;
this.size = new int[size];
this.id = new int[size];
// Initialize the arrays as individual components
for(int i = 0; i < size; i++) {
id[i] = i; // self root
this.size[i] = 1;
}
}
public int find(int p) {
// find the root of the component
int root = p;
while(root != id[root])
root = id[root];
// Path Compression : Gives amortized time complexity
while(p != root) {
int next = id[p]; // Store the id of p and make p point to the root
id[p] = root; // Compress
p = next; // do the same for the rest.
}
return root;
}
public boolean union(int p, int q) {
int root1 = find(p);
int root2 = find(q);
if(root1 == root2)
return false;
// Merge component with smaller size to the component with larger size.
if(size[root1] < size[root2]) {
size[root2] += size[root1];
id[root1] = root2; // Merge
} else {
size[root1] += size[root2];
id[root2] = root1;
}
numOfComponents--;
return true;
}
};
public static void main(String[] args) {
int[][] edges = new int[][]{{1,2},{1,3},{2,3}};
System.out.println(Arrays.toString(findRedundantConnection(edges)));
}
}