python机器学习理论与实战（二）决策树

Check if every item in the dataset is in the same class:    If so return the class label    Else       find the best feature to split the data       split the dataset        create a branch node       for each split          call create Branch and add the result to the branch node      return branch node

def calcShannonEnt(dataSet):   numEntries = len(dataSet)   labelCounts = {}   for featVec in dataSet: #the the number of unique elements and their occurance     currentLabel = featVec[-1]     if currentLabel not in labelCounts.keys(): labelCounts[currentLabel] = 0     labelCounts[currentLabel] += 1 #收集所有类别的数目，创建字典   shannonEnt = 0.0   for key in labelCounts:     prob = float(labelCounts[key])/numEntries     shannonEnt -= prob * log(prob,2) #log base 2 计算熵   return shannonEnt 

def splitDataSet(dataSet, axis, value):   retDataSet = []   for featVec in dataSet:     if featVec[axis] == value:       reducedFeatVec = featVec[:axis]   #chop out axis used for splitting       reducedFeatVec.extend(featVec[axis+1:])       retDataSet.append(reducedFeatVec)   return retDataSet    def chooseBestFeatureToSplit(dataSet):   numFeatures = len(dataSet[0]) - 1   #the last column is used for the labels   baseEntropy = calcShannonEnt(dataSet)   bestInfoGain = 0.0; bestFeature = -1   for i in range(numFeatures):    #iterate over all the features     featList = [example[i] for example in dataSet]#create a list of all the examples of this feature     uniqueVals = set(featList)    #get a set of unique values     newEntropy = 0.0     for value in uniqueVals:       subDataSet = splitDataSet(dataSet, i, value)       prob = len(subDataSet)/float(len(dataSet))       newEntropy += prob * calcShannonEnt(subDataSet)        infoGain = baseEntropy - newEntropy   #calculate the info gain; ie reduction in entropy     if (infoGain > bestInfoGain):    #compare this to the best gain so far  #选择信息增益最大的代码在此       bestInfoGain = infoGain     #if better than current best, set to best       bestFeature = i   return bestFeature           #returns an integer 

def majorityCnt(classList):   classCount={}   for vote in classList:     if vote not in classCount.keys(): classCount[vote] = 0     classCount[vote] += 1   sortedClassCount = sorted(classCount.iteritems(), key=operator.itemgetter(1), reverse=True)   return sortedClassCount[0][0]  def createTree(dataSet,labels):   classList = [example[-1] for example in dataSet]   if classList.count(classList[0]) == len(classList):      return classList[0]#stop splitting when all of the classes are equal   if len(dataSet[0]) == 1: #stop splitting when there are no more features in dataSet     return majorityCnt(classList)   bestFeat = chooseBestFeatureToSplit(dataSet)   bestFeatLabel = labels[bestFeat]   myTree = {bestFeatLabel:{}}   del(labels[bestFeat])   featValues = [example[bestFeat] for example in dataSet]   uniqueVals = set(featValues)   for value in uniqueVals:     subLabels = labels[:]    #copy all of labels, so trees don't mess up existing labels     myTree[bestFeatLabel][value] = createTree(splitDataSet(dataSet, bestFeat, value),subLabels)   return myTree   

def classify(inputTree,featLabels,testVec):   firstStr = inputTree.keys()[0]   secondDict = inputTree[firstStr]   featIndex = featLabels.index(firstStr)   key = testVec[featIndex]   valueOfFeat = secondDict[key]   if isinstance(valueOfFeat, dict):      classLabel = classify(valueOfFeat, featLabels, testVec)   else: classLabel = valueOfFeat   return classLabel 

def storeTree(inputTree,filename):   import pickle   fw = open(filename,'w')   pickle.dump(inputTree,fw)   fw.close()    def grabTree(filename):   import pickle   fr = open(filename)   return pickle.load(fr)