欢迎您访问程序员文章站本站旨在为大家提供分享程序员计算机编程知识!
您现在的位置是: 首页  >  IT编程

Python图算法实例分析

程序员文章站 2024-02-11 22:02:22
本文实例讲述了Python图算法。分享给大家供大家参考,具体如下: #encoding=utf-8 import networkx,heapq,sys fro...

本文实例讲述了Python图算法。分享给大家供大家参考,具体如下:

#encoding=utf-8
import networkx,heapq,sys
from matplotlib import pyplot
from collections import defaultdict,OrderedDict
from numpy import array
# Data in graphdata.txt:
# a b  4
# a h  8
# b c  8
# b h  11
# h i  7
# h g  1
# g i  6
# g f  2
# c f  4
# c i  2
# c d  7
# d f  14
# d e  9
# f e  10
def Edge(): return defaultdict(Edge)
class Graph:
  def __init__(self):
    self.Link = Edge()
    self.FileName = ''
    self.Separator = ''
  def MakeLink(self,filename,separator):
    self.FileName = filename
    self.Separator = separator
    graphfile = open(filename,'r')
    for line in graphfile:
      items = line.split(separator)
      self.Link[items[0]][items[1]] = int(items[2])
      self.Link[items[1]][items[0]] = int(items[2])
    graphfile.close()
  def LocalClusteringCoefficient(self,node):
    neighbors = self.Link[node]
    if len(neighbors) <= 1: return 0
    links = 0
    for j in neighbors:
      for k in neighbors:
        if j in self.Link[k]:
          links += 0.5
    return 2.0*links/(len(neighbors)*(len(neighbors)-1))
  def AverageClusteringCoefficient(self):
    total = 0.0
    for node in self.Link.keys():
      total += self.LocalClusteringCoefficient(node)
    return total/len(self.Link.keys())
  def DeepFirstSearch(self,start):
    visitedNodes = []
    todoList = [start]
    while todoList:
      visit = todoList.pop(0)
      if visit not in visitedNodes:
        visitedNodes.append(visit)
        todoList = self.Link[visit].keys() + todoList
    return visitedNodes
  def BreadthFirstSearch(self,start):
    visitedNodes = []
    todoList = [start]
    while todoList:
      visit = todoList.pop(0)
      if visit not in visitedNodes:
        visitedNodes.append(visit)
        todoList = todoList + self.Link[visit].keys()
    return visitedNodes
  def ListAllComponent(self):
    allComponent = []
    visited = {}
    for node in self.Link.iterkeys():
      if node not in visited:
        oneComponent = self.MakeComponent(node,visited)
        allComponent.append(oneComponent)
    return allComponent
  def CheckConnection(self,node1,node2):
    return True if node2 in self.MakeComponent(node1,{}) else False
  def MakeComponent(self,node,visited):
    visited[node] = True
    component = [node]
    for neighbor in self.Link[node]:
      if neighbor not in visited:
        component += self.MakeComponent(neighbor,visited)
    return component
  def MinimumSpanningTree_Kruskal(self,start):
    graphEdges = [line.strip('\n').split(self.Separator) for line in open(self.FileName,'r')]
    nodeSet = {}
    for idx,node in enumerate(self.MakeComponent(start,{})):
      nodeSet[node] = idx
    edgeNumber = 0; totalEdgeNumber = len(nodeSet)-1
    for oneEdge in sorted(graphEdges,key=lambda x:int(x[2]),reverse=False):
      if edgeNumber == totalEdgeNumber: break
      nodeA,nodeB,cost = oneEdge
      if nodeA in nodeSet and nodeSet[nodeA] != nodeSet[nodeB]:
        nodeBSet = nodeSet[nodeB]
        for node in nodeSet.keys():
          if nodeSet[node] == nodeBSet:
            nodeSet[node] = nodeSet[nodeA]
        print nodeA,nodeB,cost
        edgeNumber += 1
  def MinimumSpanningTree_Prim(self,start):
    expandNode = set(self.MakeComponent(start,{}))
    distFromTreeSoFar = {}.fromkeys(expandNode,sys.maxint); distFromTreeSoFar[start] = 0
    linkToNode = {}.fromkeys(expandNode,'');linkToNode[start] = start
    while expandNode:
      # Find the closest dist node
      closestNode = ''; shortestdistance = sys.maxint;
      for node,dist in distFromTreeSoFar.iteritems():
        if node in expandNode and dist < shortestdistance:
          closestNode,shortestdistance = node,dist
      expandNode.remove(closestNode)
      print linkToNode[closestNode],closestNode,shortestdistance
      for neighbor in self.Link[closestNode].iterkeys():
        recomputedist = self.Link[closestNode][neighbor]
        if recomputedist < distFromTreeSoFar[neighbor]:
          distFromTreeSoFar[neighbor] = recomputedist
          linkToNode[neighbor] = closestNode
  def ShortestPathOne2One(self,start,end):
    pathFromStart = {}
    pathFromStart[start] = [start]
    todoList = [start]
    while todoList:
      current = todoList.pop(0)
      for neighbor in self.Link[current]:
        if neighbor not in pathFromStart:
          pathFromStart[neighbor] = pathFromStart[current] + [neighbor]
          if neighbor == end:
            return pathFromStart[end]
          todoList.append(neighbor)
    return []
  def Centrality(self,node):
    path2All = self.ShortestPathOne2All(node)
    # The average of the distances of all the reachable nodes
    return float(sum([len(path)-1 for path in path2All.itervalues()]))/len(path2All)
  def SingleSourceShortestPath_Dijkstra(self,start):
    expandNode = set(self.MakeComponent(start,{}))
    distFromSourceSoFar = {}.fromkeys(expandNode,sys.maxint); distFromSourceSoFar[start] = 0
    while expandNode:
      # Find the closest dist node
      closestNode = ''; shortestdistance = sys.maxint;
      for node,dist in distFromSourceSoFar.iteritems():
        if node in expandNode and dist < shortestdistance:
          closestNode,shortestdistance = node,dist
      expandNode.remove(closestNode)
      for neighbor in self.Link[closestNode].iterkeys():
        recomputedist = distFromSourceSoFar[closestNode] + self.Link[closestNode][neighbor]
        if recomputedist < distFromSourceSoFar[neighbor]:
          distFromSourceSoFar[neighbor] = recomputedist
    for node in distFromSourceSoFar:
      print start,node,distFromSourceSoFar[node]
  def AllpairsShortestPaths_MatrixMultiplication(self,start):
    nodeIdx = {}; idxNode = {}; 
    for idx,node in enumerate(self.MakeComponent(start,{})):
      nodeIdx[node] = idx; idxNode[idx] = node
    matrixSize = len(nodeIdx)
    MaxInt = 1000
    nodeMatrix = array([[MaxInt]*matrixSize]*matrixSize)
    for node in nodeIdx.iterkeys():
      nodeMatrix[nodeIdx[node]][nodeIdx[node]] = 0
    for line in open(self.FileName,'r'):
      nodeA,nodeB,cost = line.strip('\n').split(self.Separator)
      if nodeA in nodeIdx:
        nodeMatrix[nodeIdx[nodeA]][nodeIdx[nodeB]] = int(cost)
        nodeMatrix[nodeIdx[nodeB]][nodeIdx[nodeA]] = int(cost)
    result = array([[0]*matrixSize]*matrixSize)
    for i in xrange(matrixSize):
      for j in xrange(matrixSize):
        result[i][j] = nodeMatrix[i][j]
    for itertime in xrange(2,matrixSize):
      for i in xrange(matrixSize):
        for j in xrange(matrixSize):
          if i==j:
            result[i][j] = 0
            continue
          result[i][j] = MaxInt
          for k in xrange(matrixSize):
            result[i][j] = min(result[i][j],result[i][k]+nodeMatrix[k][j])
    for i in xrange(matrixSize):
      for j in xrange(matrixSize):
        if result[i][j] != MaxInt:
          print idxNode[i],idxNode[j],result[i][j]
  def ShortestPathOne2All(self,start):
    pathFromStart = {}
    pathFromStart[start] = [start]
    todoList = [start]
    while todoList:
      current = todoList.pop(0)
      for neighbor in self.Link[current]:
        if neighbor not in pathFromStart:
          pathFromStart[neighbor] = pathFromStart[current] + [neighbor]
          todoList.append(neighbor)
    return pathFromStart
  def NDegreeNode(self,start,n):
    pathFromStart = {}
    pathFromStart[start] = [start]
    pathLenFromStart = {}
    pathLenFromStart[start] = 0
    todoList = [start]
    while todoList:
      current = todoList.pop(0)
      for neighbor in self.Link[current]:
        if neighbor not in pathFromStart:
          pathFromStart[neighbor] = pathFromStart[current] + [neighbor]
          pathLenFromStart[neighbor] = pathLenFromStart[current] + 1
          if pathLenFromStart[neighbor] <= n+1:
            todoList.append(neighbor)
    for node in pathFromStart.keys():
      if len(pathFromStart[node]) != n+1:
        del pathFromStart[node]
    return pathFromStart
  def Draw(self):
    G = networkx.Graph()
    nodes = self.Link.keys()
    edges = [(node,neighbor) for node in nodes for neighbor in self.Link[node]]
    G.add_edges_from(edges)
    networkx.draw(G)
    pyplot.show()
if __name__=='__main__':
  separator = '\t'
  filename = 'C:\\Users\\Administrator\\Desktop\\graphdata.txt'
  resultfilename = 'C:\\Users\\Administrator\\Desktop\\result.txt'
  myGraph = Graph()
  myGraph.MakeLink(filename,separator)
  print 'LocalClusteringCoefficient',myGraph.LocalClusteringCoefficient('a')
  print 'AverageClusteringCoefficient',myGraph.AverageClusteringCoefficient()
  print 'DeepFirstSearch',myGraph.DeepFirstSearch('a')
  print 'BreadthFirstSearch',myGraph.BreadthFirstSearch('a')
  print 'ShortestPathOne2One',myGraph.ShortestPathOne2One('a','d')
  print 'ShortestPathOne2All',myGraph.ShortestPathOne2All('a')
  print 'NDegreeNode',myGraph.NDegreeNode('a',3).keys()
  print 'ListAllComponent',myGraph.ListAllComponent()
  print 'CheckConnection',myGraph.CheckConnection('a','f')
  print 'Centrality',myGraph.Centrality('c')
  myGraph.MinimumSpanningTree_Kruskal('a')
  myGraph.AllpairsShortestPaths_MatrixMultiplication('a')
  myGraph.MinimumSpanningTree_Prim('a')
  myGraph.SingleSourceShortestPath_Dijkstra('a')
  # myGraph.Draw()

更多关于Python相关内容可查看本站专题:《Python正则表达式用法总结》、《Python数据结构与算法教程》、《Python Socket编程技巧总结》、《Python函数使用技巧总结》、《Python字符串操作技巧汇总》、《Python入门与进阶经典教程》及《Python文件与目录操作技巧汇总

希望本文所述对大家Python程序设计有所帮助。