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clone_graph.py
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clone_graph.py
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"""
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 node 0 to both nodes 1 and 2.
Second node is labeled as 1. Connect node 1 to node 2.
Third node is labeled as 2. Connect node 2 to node 2 (itself), thus forming a
self-cycle.
Visually, the graph looks like the following:
1
/ \
/ \
0 --- 2
/ \
\_/
"""
# Definition for a undirected graph node
# class UndirectedGraphNode:
# def __init__(self, x):
# self.label = x
# self.neighbors = []
# BFS
def cloneGraph1(self, node):
if not node:
return
nodeCopy = UndirectedGraphNode(node.label)
dic = {node: nodeCopy}
queue = collections.deque([node])
while queue:
node = queue.popleft()
for neighbor in node.neighbors:
if neighbor not in dic: # neighbor is not visited
neighborCopy = UndirectedGraphNode(neighbor.label)
dic[neighbor] = neighborCopy
dic[node].neighbors.append(neighborCopy)
queue.append(neighbor)
else:
dic[node].neighbors.append(dic[neighbor])
return nodeCopy
# DFS iteratively
def cloneGraph2(self, node):
if not node:
return
nodeCopy = UndirectedGraphNode(node.label)
dic = {node: nodeCopy}
stack = [node]
while stack:
node = stack.pop()
for neighbor in node.neighbors:
if neighbor not in dic:
neighborCopy = UndirectedGraphNode(neighbor.label)
dic[neighbor] = neighborCopy
dic[node].neighbors.append(neighborCopy)
stack.append(neighbor)
else:
dic[node].neighbors.append(dic[neighbor])
return nodeCopy
# DFS recursively
def cloneGraph(self, node):
if not node:
return
nodeCopy = UndirectedGraphNode(node.label)
dic = {node: nodeCopy}
self.dfs(node, dic)
return nodeCopy
def dfs(self, node, dic):
for neighbor in node.neighbors:
if neighbor not in dic:
neighborCopy = UndirectedGraphNode(neighbor.label)
dic[neighbor] = neighborCopy
dic[node].neighbors.append(neighborCopy)
self.dfs(neighbor, dic)
else:
dic[node].neighbors.append(dic[neighbor])