The Depth-First Search (DFS) approach is one of the most intuitive ways to solve the graph cloning problem. Here, we will recursively explore each node starting from the root (Node 1) and keep a map to store already cloned nodes, ensuring each node is cloned once.

For each node, we:

Check if the node is already cloned; if so, return the cloned instance to avoid cycles.
Create a new copy of the node.
Iteratively clone all its neighbors and add the clone references to the new node's neighbor list.
Return the cloned node.

Time Complexity: O(V+E), where V is the number of vertices and E is the number of edges. This is because we visit each node and edge once.

Space Complexity: O(V), for the recursion stack and the clone map.

C C++Java Python C#JavaScript

1#include <stdio.h>
2#include <stdlib.h>
3#include <string.h>
4
5#define MAX_NODES 101
6
7typedef struct Node {
8    int val;
9    struct Node** neighbors;
10    int numNeighbors;
11} Node;
12
13Node* cloneGraph(Node* node, Node** cloneMap);
14
15Node* cloneGraphUtil(Node* node, Node** cloneMap) {
16    if (node == NULL) return NULL;
17
18    if (cloneMap[node->val]) return cloneMap[node->val];
19
20    Node* cloneNode = (Node*)malloc(sizeof(Node));
21    cloneNode->val = node->val;
22    cloneNode->numNeighbors = node->numNeighbors;
23    cloneNode->neighbors = (Node**)malloc(sizeof(Node*) * node->numNeighbors);
24    cloneMap[node->val] = cloneNode;
25
26    for (int i = 0; i < node->numNeighbors; i++) {
27        cloneNode->neighbors[i] = cloneGraphUtil(node->neighbors[i], cloneMap);
28    }
29    
30    return cloneNode;
31}
32
33Node* cloneGraph(Node* node) {
34    Node* cloneMap[MAX_NODES] = {NULL};
35    return cloneGraphUtil(node, cloneMap);
36}

Explanation

The above C program defines a structure Node for graph nodes and uses a recursive function cloneGraphUtil to perform a DFS for cloning. We use an array of pointers cloneMap indexed by node values to track cloned nodes.

Breadth-First Search (BFS) for Graph Cloning

An alternative approach is to use Breadth-First Search (BFS), which is iterative in nature. Here, we utilize a queue to help explore each node level by level, preventing deep recursion and managing each node's clone in a breadth-wise manner.

In this BFS approach:

We initialize a queue with the starting node.
Use a map to store cloned nodes and a visited state.
Iteratively process nodes from the queue—cloning nodes, establishing clone-linking relationships, and enqueuing unvisited nodes.
Once the queue is empty, cloning and linking are complete.

Time Complexity: O(V+E).

Space Complexity: O(V).

C++Java Python C#JavaScript

1#include <unordered_map>
#include <queue>
using namespace std;

class Node {
public:
    int val;
    vector<Node*> neighbors;
    Node() {
        val = 0;
        neighbors = vector<Node*>();
    }
    Node(int _val) {
        val = _val;
        neighbors = vector<Node*>();
    }
    Node(int _val, vector<Node*> _neighbors) {
        val = _val;
        neighbors = _neighbors;
    }
};

class Solution {
public:
    Node* cloneGraph(Node* node) {
        if (!node) return NULL;
        unordered_map<Node*, Node*> visited;
        queue<Node*> q;
        q.push(node);
        visited[node] = new Node(node->val);

        while (!q.empty()) {
            auto n = q.front(); q.pop();
            for (auto neighbor : n->neighbors) {
                if (visited.find(neighbor) == visited.end()) {
                    visited[neighbor] = new Node(neighbor->val);
                    q.push(neighbor);
                }
                visited[n]->neighbors.push_back(visited[neighbor]);
            }
        }
        return visited[node];
    }
};

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133. Clone Graph

Depth-First Search (DFS) for Graph Cloning

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Breadth-First Search (BFS) for Graph Cloning

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