Clone an undirected graph. Each node in the graph contains a label and a list of its neighbors.
OJ's undirected graph serialization:
Nodes are labeled uniquely.
We use # as a separator for each node, and , as a separator for node label and each neighbor of the node.
As an example, consider the serialized graph {0,1,2#1,2#2,2}.
The graph has a total of three nodes, and therefore contains three parts as separated by #.
- First node is labeled as
0. Connect node0to both nodes1and2. - Second node is labeled as
1. Connect node1to node2. - Third node is labeled as
2. Connect node2to node2(itself), thus forming a self-cycle.
Visually, the graph looks like the following:
1
/ \
/ \
0 --- 2
/ \
\_/
思路:对neughbors的每个节点,如果还没创建,DFS
所以需要一个map标示节点是否已创建
每次递归内容为创建该节点,并递归创建邻节点。
struct UndirectedGraphNode {
int label;
vector<UndirectedGraphNode *> neighbors;
UndirectedGraphNode(int x) : label(x) {};
};
class Solution {
public:
UndirectedGraphNode *cloneGraph(UndirectedGraphNode *node) {
if(!node) return NULL;
UndirectedGraphNode *current;
map<UndirectedGraphNode*,UndirectedGraphNode*> flag; //前一个元素是节点在原Graph中的地址,后一个元素是节点在新拷贝的图中的位置
UndirectedGraphNode *root = cloneNode(node,flag);
return root;
}
UndirectedGraphNode * cloneNode(UndirectedGraphNode *source, map<UndirectedGraphNode*,UndirectedGraphNode*> &flag)
{
if(flag.find(source)!= flag.end()) return flag[source];
//如果map中没有该节点,那么创建该节点
UndirectedGraphNode *target = new UndirectedGraphNode(source->label);
flag[source] = target;
for(vector<UndirectedGraphNode *>::iterator it = source->neighbors.begin(); it < source->neighbors.end(); it++ )
{
UndirectedGraphNode *newRoot = cloneNode(*it, flag); //深度优先,先递归处理它的某一个邻居,再处理其他邻居
target->neighbors.push_back(newRoot);
}
return target; //返回已经处理好的节点
}
};