python编写分类决策树的代码

明立 2017-12-21

决策树通常在机器学习中用于分类。

优点:计算复杂度不高,输出结果易于理解,对中间值缺失不敏感,可以处理不相关特征数据。
缺点:可能会产生过度匹配问题。
适用数据类型:数值型和标称型。

1.信息增益

划分数据集的目的是:将无序的数据变得更加有序。组织杂乱无章数据的一种方法就是使用信息论度量信息。通常采用信息增益,信息增益是指数据划分前后信息熵的减少值。信息越无序信息熵越大,获得信息增益最高的特征就是最好的选择。
熵定义为信息的期望,符号xi的信息定义为:

python编写分类决策树的代码

其中p(xi)为该分类的概率。
熵,即信息的期望值为:

python编写分类决策树的代码

计算信息熵的代码如下:

def calcShannonEnt(dataSet):
  numEntries = len(dataSet)
  labelCounts = {}
  for featVec in dataSet:
    currentLabel = featVec[-1]
    if currentLabel not in labelCounts:
      labelCounts[currentLabel] = 0
    labelCounts[currentLabel] += 1
  shannonEnt = 0
  for key in labelCounts:
    shannonEnt = shannonEnt - (labelCounts[key]/numEntries)*math.log2(labelCounts[key]/numEntries)
  return shannonEnt

可以根据信息熵,按照获取最大信息增益的方法划分数据集。

2.划分数据集

划分数据集就是将所有符合要求的元素抽出来。

def splitDataSet(dataSet,axis,value):
  retDataset = []
  for featVec in dataSet:
    if featVec[axis] == value:
      newVec = featVec[:axis]
      newVec.extend(featVec[axis+1:])
      retDataset.append(newVec)
  return retDataset

3.选择最好的数据集划分方式

信息增益是熵的减少或者是信息无序度的减少。

def chooseBestFeatureToSplit(dataSet):
  numFeatures = len(dataSet[0]) - 1
  bestInfoGain = 0
  bestFeature = -1
  baseEntropy = calcShannonEnt(dataSet)
  for i in range(numFeatures):
    allValue = [example[i] for example in dataSet]#列表推倒,创建新的列表
    allValue = set(allValue)#最快得到列表中唯一元素值的方法
    newEntropy = 0
    for value in allValue:
      splitset = splitDataSet(dataSet,i,value)
      newEntropy = newEntropy + len(splitset)/len(dataSet)*calcShannonEnt(splitset)
    infoGain = baseEntropy - newEntropy
    if infoGain > bestInfoGain:
      bestInfoGain = infoGain
      bestFeature = i
  return bestFeature

4.递归创建决策树

结束条件为:程序遍历完所有划分数据集的属性,或每个分支下的所有实例都具有相同的分类。
当数据集已经处理了所有属性,但是类标签还不唯一时,采用多数表决的方式决定叶子节点的类型。

def majorityCnt(classList):
 classCount = {}
 for value in classList:
  if value not in classCount: classCount[value] = 0
  classCount[value] += 1
 classCount = sorted(classCount.items(),key=operator.itemgetter(1),reverse=True)
 return classCount[0][0]

生成决策树:

def createTree(dataSet,labels):
 classList = [example[-1] for example in dataSet]
 labelsCopy = labels[:]
 if classList.count(classList[0]) == len(classList):
  return classList[0]
 if len(dataSet[0]) == 1:
  return majorityCnt(classList)
 bestFeature = chooseBestFeatureToSplit(dataSet)
 bestLabel = labelsCopy[bestFeature]
 myTree = {bestLabel:{}}
 featureValues = [example[bestFeature] for example in dataSet]
 featureValues = set(featureValues)
 del(labelsCopy[bestFeature])
 for value in featureValues:
  subLabels = labelsCopy[:]
  myTree[bestLabel][value] = createTree(splitDataSet(dataSet,bestFeature,value),subLabels)
 return myTree

5.测试算法――使用决策树分类

同样采用递归的方式得到分类结果。

def classify(inputTree,featLabels,testVec):
 currentFeat = list(inputTree.keys())[0]
 secondTree = inputTree[currentFeat]
 try:
  featureIndex = featLabels.index(currentFeat)
 except ValueError as err:
  print('yes')
 try:
  for value in secondTree.keys():
   if value == testVec[featureIndex]:
    if type(secondTree[value]).__name__ == 'dict':
     classLabel = classify(secondTree[value],featLabels,testVec)
    else:
     classLabel = secondTree[value]
  return classLabel
 except AttributeError:
  print(secondTree)

6.完整代码如下

import numpy as np
import math
import operator
def createDataSet():
 dataSet = [[1,1,'yes'],
    [1,1,'yes'],
    [1,0,'no'],
    [0,1,'no'],
    [0,1,'no'],]
 label = ['no surfacing','flippers']
 return dataSet,label

def calcShannonEnt(dataSet):
 numEntries = len(dataSet)
 labelCounts = {}
 for featVec in dataSet:
  currentLabel = featVec[-1]
  if currentLabel not in labelCounts:
   labelCounts[currentLabel] = 0
  labelCounts[currentLabel] += 1
 shannonEnt = 0
 for key in labelCounts:
  shannonEnt = shannonEnt - (labelCounts[key]/numEntries)*math.log2(labelCounts[key]/numEntries)
 return shannonEnt


def splitDataSet(dataSet,axis,value):
 retDataset = []
 for featVec in dataSet:
  if featVec[axis] == value:
   newVec = featVec[:axis]
   newVec.extend(featVec[axis+1:])
   retDataset.append(newVec)
 return retDataset

def chooseBestFeatureToSplit(dataSet):
 numFeatures = len(dataSet[0]) - 1
 bestInfoGain = 0
 bestFeature = -1
 baseEntropy = calcShannonEnt(dataSet)
 for i in range(numFeatures):
  allValue = [example[i] for example in dataSet]
  allValue = set(allValue)
  newEntropy = 0
  for value in allValue:
   splitset = splitDataSet(dataSet,i,value)
   newEntropy = newEntropy + len(splitset)/len(dataSet)*calcShannonEnt(splitset)
  infoGain = baseEntropy - newEntropy
  if infoGain > bestInfoGain:
   bestInfoGain = infoGain
   bestFeature = i
 return bestFeature

def majorityCnt(classList):
 classCount = {}
 for value in classList:
  if value not in classCount: classCount[value] = 0
  classCount[value] += 1
 classCount = sorted(classCount.items(),key=operator.itemgetter(1),reverse=True)
 return classCount[0][0]   

def createTree(dataSet,labels):
 classList = [example[-1] for example in dataSet]
 labelsCopy = labels[:]
 if classList.count(classList[0]) == len(classList):
  return classList[0]
 if len(dataSet[0]) == 1:
  return majorityCnt(classList)
 bestFeature = chooseBestFeatureToSplit(dataSet)
 bestLabel = labelsCopy[bestFeature]
 myTree = {bestLabel:{}}
 featureValues = [example[bestFeature] for example in dataSet]
 featureValues = set(featureValues)
 del(labelsCopy[bestFeature])
 for value in featureValues:
  subLabels = labelsCopy[:]
  myTree[bestLabel][value] = createTree(splitDataSet(dataSet,bestFeature,value),subLabels)
 return myTree


def classify(inputTree,featLabels,testVec):
 currentFeat = list(inputTree.keys())[0]
 secondTree = inputTree[currentFeat]
 try:
  featureIndex = featLabels.index(currentFeat)
 except ValueError as err:
  print('yes')
 try:
  for value in secondTree.keys():
   if value == testVec[featureIndex]:
    if type(secondTree[value]).__name__ == 'dict':
     classLabel = classify(secondTree[value],featLabels,testVec)
    else:
     classLabel = secondTree[value]
  return classLabel
 except AttributeError:
  print(secondTree)

if __name__ == "__main__":
 dataset,label = createDataSet()
 myTree = createTree(dataset,label)
 a = [1,1]
 print(classify(myTree,label,a))

7.编程技巧

extend与append的区别

newVec.extend(featVec[axis+1:])
 retDataset.append(newVec)

extend([]),是将列表中的每个元素依次加入新列表中
append()是将括号中的内容当做一项加入到新列表中

列表推到

创建新列表的方式

allValue = [example[i] for example in dataSet]

提取列表中唯一的元素

allValue = set(allValue)

列表/元组排序,sorted()函数

classCount = sorted(classCount.items(),key=operator.itemgetter(1),reverse=True)

列表的复制

labelsCopy = labels[:]

代码及数据集下载:决策树

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