Package g0901_1000.s0928_minimize_malware_spread_ii

Class Solution

java.lang.Object
g0901_1000.s0928_minimize_malware_spread_ii.Solution
public class Solution extends Object
928 - Minimize Malware Spread II\. Hard You are given a network of `n` nodes represented as an `n x n` adjacency matrix `graph`, where the ith node is directly connected to the jth node if `graph[i][j] == 1`. Some nodes `initial` are initially infected by malware. Whenever two nodes are directly connected, and at least one of those two nodes is infected by malware, both nodes will be infected by malware. This spread of malware will continue until no more nodes can be infected in this manner. Suppose `M(initial)` is the final number of nodes infected with malware in the entire network after the spread of malware stops. We will remove **exactly one node** from `initial`, **completely removing it and any connections from this node to any other node**. Return the node that, if removed, would minimize `M(initial)`. If multiple nodes could be removed to minimize `M(initial)`, return such a node with **the smallest index**. **Example 1:** **Input:** graph = \[\[1,1,0],[1,1,0],[0,0,1]], initial = [0,1] **Output:** 0 **Example 2:** **Input:** graph = \[\[1,1,0],[1,1,1],[0,1,1]], initial = [0,1] **Output:** 1 **Example 3:** **Input:** graph = \[\[1,1,0,0],[1,1,1,0],[0,1,1,1],[0,0,1,1]], initial = [0,1] **Output:** 1 **Constraints:** * `n == graph.length` * `n == graph[i].length` * `2 <= n <= 300` * `graph[i][j]` is `0` or `1`. * `graph[i][j] == graph[j][i]` * `graph[i][i] == 1` * `1 <= initial.length < n` * `0 <= initial[i] <= n - 1` * All the integers in `initial` are **unique**.

  • Constructor Details

    • Solution

      public Solution()

  • Method Details

    • minMalwareSpread

      public int minMalwareSpread(int[][] graph, int[] initial)