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首页精彩阅读python实现随机森林random forest的原理及方法
python实现随机森林random forest的原理及方法
2018-01-22
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python实现随机森林random forest的原理及方法

想通过随机森林来获取数据的主要特征
1、理论
随机森林是一个高度灵活的机器学习方法,拥有广泛的应用前景,从市场营销到医疗保健保险。 既可以用来做市场营销模拟的建模,统计客户来源,保留和流失。也可用来预测疾病的风险和病患者的易感性。
根据个体学习器的生成方式,目前的集成学习方法大致可分为两大类,即个体学习器之间存在强依赖关系,必须串行生成的序列化方法,以及个体学习器间不存在强依赖关系,可同时生成的并行化方法;
前者的代表是Boosting,后者的代表是Bagging和“随机森林”(Random
Forest)
随机森林在以决策树为基学习器构建Bagging集成的基础上,进一步在决策树的训练过程中引入了随机属性选择(即引入随机特征选择)。
简单来说,随机森林就是对决策树的集成,但有两点不同:
(2)特征选取的差异性:每个决策树的n个分类特征是在所有特征中随机选择的(n是一个需要我们自己调整的参数)
随机森林,简单理解, 比如预测salary,就是构建多个决策树job,age,house,然后根据要预测的量的各个特征(teacher,39,suburb)分别在对应决策树的目标值概率(salary<5000,salary>=5000),从而,确定预测量的发生概率(如,预测出P(salary<5000)=0.3).
随机森林是一个可做能够回归和分类。 它具备处理大数据的特性,而且它有助于估计或变量是非常重要的基础数据建模
参数说明:
最主要的两个参数是n_estimators和max_features。
n_estimators:表示森林里树的个数。理论上是越大越好。但是伴随着就是计算时间的增长。但是并不是取得越大就会越好,预测效果最好的将会出现在合理的树个数。
max_features:随机选择特征集合的子集合,并用来分割节点。子集合的个数越少,方差就会减少的越快,但同时偏差就会增加的越快。根据较好的实践经验。如果是回归问题则:

max_features=n_features,如果是分类问题则max_features=sqrt(n_features)。

如果想获取较好的结果,必须将max_depth=None,同时min_sample_split=1。
同时还要记得进行cross_validated(交叉验证),除此之外记得在random forest中,bootstrap=True。但在extra-trees中,bootstrap=False。

2、随机森林python实现

2.1Demo1

实现随机森林基本功能    
#随机森林
from sklearn.tree import DecisionTreeRegressor
from sklearn.ensemble import RandomForestRegressor
import numpy as np
 
from sklearn.datasets import load_iris
iris=load_iris()
#print iris#iris的4个属性是:萼片宽度 萼片长度 花瓣宽度 花瓣长度 标签是花的种类:setosa versicolour virginica
print(iris['target'].shape)
rf=RandomForestRegressor()#这里使用了默认的参数设置
rf.fit(iris.data[:150],iris.target[:150])#进行模型的训练
 
#随机挑选两个预测不相同的样本
instance=iris.data[[100,109]]
print(instance)
rf.predict(instance[[0]])
print('instance 0 prediction;',rf.predict(instance[[0]]))
print( 'instance 1 prediction;',rf.predict(instance[[1]]))
print(iris.target[100],iris.target[109])

运行结果

(150,)
[[ 6.3  3.3  6.   2.5]
 [ 7.2  3.6  6.1  2.5]]
instance 0 prediction; [ 2.]
instance 1 prediction; [ 2.]
2 2

2.2 Demo2

3种方法的比较    
#random forest test
from sklearn.model_selection import cross_val_score
from sklearn.datasets import make_blobs
from sklearn.ensemble import RandomForestClassifier
from sklearn.ensemble import ExtraTreesClassifier
from sklearn.tree import DecisionTreeClassifier
X, y = make_blobs(n_samples=10000, n_features=10, centers=100,random_state=0)
 
clf = DecisionTreeClassifier(max_depth=None, min_samples_split=2,random_state=0)
scores = cross_val_score(clf, X, y)
print(scores.mean())    
 
 
clf = RandomForestClassifier(n_estimators=10, max_depth=None,min_samples_split=2, random_state=0)
scores = cross_val_score(clf, X, y)
print(scores.mean())    
 
clf = ExtraTreesClassifier(n_estimators=10, max_depth=None,min_samples_split=2, random_state=0)
scores = cross_val_score(clf, X, y)
print(scores.mean())

运行结果:

0.979408793821
0.999607843137
0.999898989899

2.3 Demo3-实现特征选择
#随机森林2
from sklearn.tree import DecisionTreeRegressor
from sklearn.ensemble import RandomForestRegressor
import numpy as np
from sklearn.datasets import load_iris
iris=load_iris()
 
from sklearn.model_selection import cross_val_score, ShuffleSplit
X = iris["data"]
Y = iris["target"]
names = iris["feature_names"]
rf = RandomForestRegressor()
scores = []
for i in range(X.shape[1]):
 score = cross_val_score(rf, X[:, i:i+1], Y, scoring="r2",
    cv=ShuffleSplit(len(X), 3, .3))
 scores.append((round(np.mean(score), 3), names[i]))
print(sorted(scores, reverse=True))
运行结果:
[(0.89300000000000002, 'petal width (cm)'), (0.82099999999999995, 'petal length
(cm)'), (0.13, 'sepal length (cm)'), (-0.79100000000000004, 'sepal width (cm)')]
2.4 demo4-随机森林
本来想利用以下代码来构建随机随机森林决策树,但是,遇到的问题是,程序一直在运行,无法响应,还需要调试。    
#随机森林4
#coding:utf-8
import csv
from random import seed
from random import randrange
from math import sqrt
def loadCSV(filename):#加载数据,一行行的存入列表
 dataSet = []
 with open(filename, 'r') as file:
 csvReader = csv.reader(file)
 for line in csvReader:
  dataSet.append(line)
 return dataSet
 
# 除了标签列,其他列都转换为float类型
def column_to_float(dataSet):
 featLen = len(dataSet[0]) - 1
 for data in dataSet:
 for column in range(featLen):
  data[column] = float(data[column].strip())
 
# 将数据集随机分成N块,方便交叉验证,其中一块是测试集,其他四块是训练集
def spiltDataSet(dataSet, n_folds):
 fold_size = int(len(dataSet) / n_folds)
 dataSet_copy = list(dataSet)
 dataSet_spilt = []
 for i in range(n_folds):
 fold = []
 while len(fold) < fold_size: # 这里不能用if,if只是在第一次判断时起作用,while执行循环,直到条件不成立
  index = randrange(len(dataSet_copy))
  fold.append(dataSet_copy.pop(index)) # pop() 函数用于移除列表中的一个元素(默认最后一个元素),并且返回该元素的值。
 dataSet_spilt.append(fold)
 return dataSet_spilt
 
# 构造数据子集
def get_subsample(dataSet, ratio):
 subdataSet = []
 lenSubdata = round(len(dataSet) * ratio)#返回浮点数
 while len(subdataSet) < lenSubdata:
 index = randrange(len(dataSet) - 1)
 subdataSet.append(dataSet[index])
 # print len(subdataSet)
 return subdataSet
 
# 分割数据集
def data_spilt(dataSet, index, value):
 left = []
 right = []
 for row in dataSet:
 if row[index] < value:
  left.append(row)
 else:
  right.append(row)
 return left, right
 
# 计算分割代价
def spilt_loss(left, right, class_values):
 loss = 0.0
 for class_value in class_values:
 left_size = len(left)
 if left_size != 0: # 防止除数为零
  prop = [row[-1] for row in left].count(class_value) / float(left_size)
  loss += (prop * (1.0 - prop))
 right_size = len(right)
 if right_size != 0:
  prop = [row[-1] for row in right].count(class_value) / float(right_size)
  loss += (prop * (1.0 - prop))
 return loss
 
# 选取任意的n个特征,在这n个特征中,选取分割时的最优特征
def get_best_spilt(dataSet, n_features):
 features = []
 class_values = list(set(row[-1] for row in dataSet))
 b_index, b_value, b_loss, b_left, b_right = 999, 999, 999, None, None
 while len(features) < n_features:
 index = randrange(len(dataSet[0]) - 1)
 if index not in features:
  features.append(index)
 # print 'features:',features
 for index in features:#找到列的最适合做节点的索引,(损失最小)
 for row in dataSet:
  left, right = data_spilt(dataSet, index, row[index])#以它为节点的,左右分支
  loss = spilt_loss(left, right, class_values)
  if loss < b_loss:#寻找最小分割代价
  b_index, b_value, b_loss, b_left, b_right = index, row[index], loss, left, right
 # print b_loss
 # print type(b_index)
 return {'index': b_index, 'value': b_value, 'left': b_left, 'right': b_right}
 
# 决定输出标签
def decide_label(data):
 output = [row[-1] for row in data]
 return max(set(output), key=output.count)
 
# 子分割,不断地构建叶节点的过程对对对
def sub_spilt(root, n_features, max_depth, min_size, depth):
 left = root['left']
 # print left
 right = root['right']
 del (root['left'])
 del (root['right'])
 # print depth
 if not left or not right:
 root['left'] = root['right'] = decide_label(left + right)
 # print 'testing'
 return
 if depth > max_depth:
 root['left'] = decide_label(left)
 root['right'] = decide_label(right)
 return
 if len(left) < min_size:
 root['left'] = decide_label(left)
 else:
 root['left'] = get_best_spilt(left, n_features)
 # print 'testing_left'
 sub_spilt(root['left'], n_features, max_depth, min_size, depth + 1)
 if len(right) < min_size:
 root['right'] = decide_label(right)
 else:
 root['right'] = get_best_spilt(right, n_features)
 # print 'testing_right'
 sub_spilt(root['right'], n_features, max_depth, min_size, depth + 1)
 
 # 构造决策树
def build_tree(dataSet, n_features, max_depth, min_size):
 root = get_best_spilt(dataSet, n_features)
 sub_spilt(root, n_features, max_depth, min_size, 1)
 return root
# 预测测试集结果
def predict(tree, row):
 predictions = []
 if row[tree['index']] < tree['value']:
 if isinstance(tree['left'], dict):
  return predict(tree['left'], row)
 else:
  return tree['left']
 else:
 if isinstance(tree['right'], dict):
  return predict(tree['right'], row)
 else:
  return tree['right']
  # predictions=set(predictions)
def bagging_predict(trees, row):
 predictions = [predict(tree, row) for tree in trees]
 return max(set(predictions), key=predictions.count)
# 创建随机森林
def random_forest(train, test, ratio, n_feature, max_depth, min_size, n_trees):
 trees = []
 for i in range(n_trees):
 train = get_subsample(train, ratio)#从切割的数据集中选取子集
 tree = build_tree(train, n_features, max_depth, min_size)
 # print 'tree %d: '%i,tree
 trees.append(tree)
 # predict_values = [predict(trees,row) for row in test]
 predict_values = [bagging_predict(trees, row) for row in test]
 return predict_values
# 计算准确率
def accuracy(predict_values, actual):
 correct = 0
 for i in range(len(actual)):
 if actual[i] == predict_values[i]:
  correct += 1
 return correct / float(len(actual))
if __name__ == '__main__':
 seed(1)
 dataSet = loadCSV(r'G:\0研究生\tianchiCompetition\训练小样本2.csv')
 column_to_float(dataSet)
 n_folds = 5
 max_depth = 15
 min_size = 1
 ratio = 1.0
 # n_features=sqrt(len(dataSet)-1)
 n_features = 15
 n_trees = 10
 folds = spiltDataSet(dataSet, n_folds)#先是切割数据集
 scores = []
 for fold in folds:
 train_set = folds[
   :] # 此处不能简单地用train_set=folds,这样用属于引用,那么当train_set的值改变的时候,folds的值也会改变,所以要用复制的形式。(L[:])能够复制序列,D.copy() 能够复制字典,list能够生成拷贝 list(L)
 train_set.remove(fold)#选好训练集
 # print len(folds)
 train_set = sum(train_set, []) # 将多个fold列表组合成一个train_set列表
 # print len(train_set)
 test_set = []
 for row in fold:
  row_copy = list(row)
  row_copy[-1] = None
  test_set.append(row_copy)
  # for row in test_set:
  # print row[-1]
 actual = [row[-1] for row in fold]
 predict_values = random_forest(train_set, test_set, ratio, n_features, max_depth, min_size, n_trees)
 accur = accuracy(predict_values, actual)
 scores.append(accur)
 print ('Trees is %d' % n_trees)
 print ('scores:%s' % scores)
 print ('mean score:%s' % (sum(scores) / float(len(scores))))

2.5 随机森林分类sonic data    
# CART on the Bank Note dataset
from random import seed
from random import randrange
from csv import reader
 
# Load a CSV file
def load_csv(filename):
 file = open(filename, "r")
 lines = reader(file)
 dataset = list(lines)
 return dataset
 
# Convert string column to float
def str_column_to_float(dataset, column):
 for row in dataset:
 row[column] = float(row[column].strip())
 
# Split a dataset into k folds
def cross_validation_split(dataset, n_folds):
 dataset_split = list()
 dataset_copy = list(dataset)
 fold_size = int(len(dataset) / n_folds)
 for i in range(n_folds):
 fold = list()
 while len(fold) < fold_size:
  index = randrange(len(dataset_copy))
  fold.append(dataset_copy.pop(index))
 dataset_split.append(fold)
 return dataset_split
 
# Calculate accuracy percentage
def accuracy_metric(actual, predicted):
 correct = 0
 for i in range(len(actual)):
 if actual[i] == predicted[i]:
  correct += 1
 return correct / float(len(actual)) * 100.0
 
# Evaluate an algorithm using a cross validation split
def evaluate_algorithm(dataset, algorithm, n_folds, *args):
 folds = cross_validation_split(dataset, n_folds)
 scores = list()
 for fold in folds:
 train_set = list(folds)
 train_set.remove(fold)
 train_set = sum(train_set, [])
 test_set = list()
 for row in fold:
  row_copy = list(row)
  test_set.append(row_copy)
  row_copy[-1] = None
 predicted = algorithm(train_set, test_set, *args)
 actual = [row[-1] for row in fold]
 accuracy = accuracy_metric(actual, predicted)
 scores.append(accuracy)
 return scores
 
# Split a data set based on an attribute and an attribute value
def test_split(index, value, dataset):
 left, right = list(), list()
 for row in dataset:
 if row[index] < value:
  left.append(row)
 else:
  right.append(row)
 return left, right
 
# Calculate the Gini index for a split dataset
def gini_index(groups, class_values):
 gini = 0.0
 for class_value in class_values:
 for group in groups:
  size = len(group)
  if size == 0:
  continue
  proportion = [row[-1] for row in group].count(class_value) / float(size)
  gini += (proportion * (1.0 - proportion))
 return gini
 
# Select the best split point for a dataset
def get_split(dataset):
 class_values = list(set(row[-1] for row in dataset))
 b_index, b_value, b_score, b_groups = 999, 999, 999, None
 for index in range(len(dataset[0])-1):
 for row in dataset:
  groups = test_split(index, row[index], dataset)
  gini = gini_index(groups, class_values)
  if gini < b_score:
  b_index, b_value, b_score, b_groups = index, row[index], gini, groups
 print ({'index':b_index, 'value':b_value})
 return {'index':b_index, 'value':b_value, 'groups':b_groups}
 
# Create a terminal node value
def to_terminal(group):
 outcomes = [row[-1] for row in group]
 return max(set(outcomes), key=outcomes.count)
 
# Create child splits for a node or make terminal
def split(node, max_depth, min_size, depth):
 left, right = node['groups']
 del(node['groups'])
 # check for a no split
 if not left or not right:
 node['left'] = node['right'] = to_terminal(left + right)
 return
 # check for max depth
 if depth >= max_depth:
 node['left'], node['right'] = to_terminal(left), to_terminal(right)
 return
 # process left child
 if len(left) <= min_size:
 node['left'] = to_terminal(left)
 else:
 node['left'] = get_split(left)
 split(node['left'], max_depth, min_size, depth+1)
 # process right child
 if len(right) <= min_size:
 node['right'] = to_terminal(right)
 else:
 node['right'] = get_split(right)
 split(node['right'], max_depth, min_size, depth+1)
 
# Build a decision tree
def build_tree(train, max_depth, min_size):
 root = get_split(train)
 split(root, max_depth, min_size, 1)
 return root
 
# Make a prediction with a decision tree
def predict(node, row):
 if row[node['index']] < node['value']:
 if isinstance(node['left'], dict):
  return predict(node['left'], row)
 else:
  return node['left']
 else:
 if isinstance(node['right'], dict):
  return predict(node['right'], row)
 else:
  return node['right']
 
# Classification and Regression Tree Algorithm
def decision_tree(train, test, max_depth, min_size):
 tree = build_tree(train, max_depth, min_size)
 predictions = list()
 for row in test:
 prediction = predict(tree, row)
 predictions.append(prediction)
 return(predictions)
 
# Test CART on Bank Note dataset
seed(1)
# load and prepare data
filename = r'G:\0pythonstudy\决策树\sonar.all-data.csv'
dataset = load_csv(filename)
# convert string attributes to integers
for i in range(len(dataset[0])-1):
 str_column_to_float(dataset, i)
# evaluate algorithm
n_folds = 5
max_depth = 5
min_size = 10
scores = evaluate_algorithm(dataset, decision_tree, n_folds, max_depth, min_size)
print('Scores: %s' % scores)
print('Mean Accuracy: %.3f%%' % (sum(scores)/float(len(scores))))

运行结果:

{'index': 38, 'value': 0.0894}
{'index': 36, 'value': 0.8459}
{'index': 50, 'value': 0.0024}
{'index': 15, 'value': 0.0906}
{'index': 16, 'value': 0.9819}
{'index': 10, 'value': 0.0785}
{'index': 16, 'value': 0.0886}
{'index': 38, 'value': 0.0621}
{'index': 5, 'value': 0.0226}
{'index': 8, 'value': 0.0368}
{'index': 11, 'value': 0.0754}
{'index': 0, 'value': 0.0239}
{'index': 8, 'value': 0.0368}
{'index': 29, 'value': 0.1671}
{'index': 46, 'value': 0.0237}
{'index': 38, 'value': 0.0621}
{'index': 14, 'value': 0.0668}
{'index': 4, 'value': 0.0167}
{'index': 37, 'value': 0.0836}
{'index': 12, 'value': 0.0616}
{'index': 7, 'value': 0.0333}
{'index': 33, 'value': 0.8741}
{'index': 16, 'value': 0.0886}
{'index': 8, 'value': 0.0368}
{'index': 33, 'value': 0.0798}
{'index': 44, 'value': 0.0298}
Scores: [48.78048780487805, 70.73170731707317, 58.536585365853654, 51.2195121951
2195, 39.02439024390244]
Mean Accuracy: 53.659%
请按任意键继续. . .

知识点:
1.load CSV file    
from csv import reader
# Load a CSV file
def load_csv(filename):
 file = open(filename, "r")
 lines = reader(file)
 dataset = list(lines)
 return dataset
filename = r'G:\0pythonstudy\决策树\sonar.all-data.csv'
dataset=load_csv(filename)
print(dataset)

2.把数据转化成float格式    
# Convert string column to float
def str_column_to_float(dataset, column):
 for row in dataset:
 row[column] = float(row[column].strip())
 # print(row[column])
# convert string attributes to integers
for i in range(len(dataset[0])-1):
 str_column_to_float(dataset, i)

3.把最后一列的分类字符串转化成0、1整数    
def str_column_to_int(dataset, column):
 class_values = [row[column] for row in dataset]#生成一个class label的list
 # print(class_values)
 unique = set(class_values)#set 获得list的不同元素
 print(unique)
 lookup = dict()#定义一个字典
 # print(enumerate(unique))
 for i, value in enumerate(unique):
 lookup[value] = i
 # print(lookup)
 for row in dataset:
 row[column] = lookup[row[column]]
 print(lookup['M'])

4、把数据集分割成K份    
# Split a dataset into k folds
def cross_validation_split(dataset, n_folds):
 dataset_split = list()#生成空列表
 dataset_copy = list(dataset)
 print(len(dataset_copy))
 print(len(dataset))
 #print(dataset_copy)
 fold_size = int(len(dataset) / n_folds)
 for i in range(n_folds):
 fold = list()
 while len(fold) < fold_size:
  index = randrange(len(dataset_copy))
  # print(index)
  fold.append(dataset_copy.pop(index))#使用.pop()把里边的元素都删除(相当于转移),这k份元素各不相同。
 dataset_split.append(fold)
 return dataset_split
n_folds=5
folds = cross_validation_split(dataset, n_folds)#k份元素各不相同的训练集

5.计算正确率    
# Calculate accuracy percentage
def accuracy_metric(actual, predicted):
 correct = 0
 for i in range(len(actual)):
 if actual[i] == predicted[i]:
  correct += 1
 return correct / float(len(actual)) * 100.0#这个是二值分类正确性的表达式

6.二分类每列    
# Split a data set based on an attribute and an attribute value
def test_split(index, value, dataset):
 left, right = list(), list()#初始化两个空列表
 for row in dataset:
 if row[index] < value:
  left.append(row)
 else:
  right.append(row)
 return left, right #返回两个列表,每个列表以value为界限对指定行(index)进行二分类

7.使用gini系数来获得最佳分割点    
# Calculate the Gini index for a split dataset
def gini_index(groups, class_values):
 gini = 0.0
 for class_value in class_values:
 for group in groups:
  size = len(group)
  if size == 0:
  continue
  proportion = [row[-1] for row in group].count(class_value) / float(size)
  gini += (proportion * (1.0 - proportion))
 return gini
 
# Select the best split point for a dataset
def get_split(dataset):
 class_values = list(set(row[-1] for row in dataset))
 b_index, b_value, b_score, b_groups = 999, 999, 999, None
 for index in range(len(dataset[0])-1):
 for row in dataset:
  groups = test_split(index, row[index], dataset)
  gini = gini_index(groups, class_values)
  if gini < b_score:
  b_index, b_value, b_score, b_groups = index, row[index], gini, groups
 # print(groups)
 print ({'index':b_index, 'value':b_value,'score':gini})
 return {'index':b_index, 'value':b_value, 'groups':b_groups}

这段代码,在求gini指数,直接应用定义式,不难理解。获得最佳分割点可能比较难看懂,这里用了两层迭代,一层是对不同列的迭代,一层是对不同行的迭代。并且,每次迭代,都对gini系数进行更新。

8、决策树生成    
# Create child splits for a node or make terminal
def split(node, max_depth, min_size, depth):
 left, right = node['groups']
 del(node['groups'])
 # check for a no split
 if not left or not right:
 node['left'] = node['right'] = to_terminal(left + right)
 return
 # check for max depth
 if depth >= max_depth:
 node['left'], node['right'] = to_terminal(left), to_terminal(right)
 return
 # process left child
 if len(left) <= min_size:
 node['left'] = to_terminal(left)
 else:
 node['left'] = get_split(left)
 split(node['left'], max_depth, min_size, depth+1)
 # process right child
 if len(right) <= min_size:
 node['right'] = to_terminal(right)
 else:
 node['right'] = get_split(right)
 split(node['right'], max_depth, min_size, depth+1)

这里使用了递归编程,不断生成左叉树和右叉树。

9.构建决策树    
# Build a decision tree
def build_tree(train, max_depth, min_size):
 root = get_split(train)
 split(root, max_depth, min_size, 1)
 return root
tree=build_tree(train_set, max_depth, min_size)
print(tree)

10、预测test集    
# Build a decision tree
def build_tree(train, max_depth, min_size):
 root = get_split(train)#获得最好的分割点,下标值,groups
 split(root, max_depth, min_size, 1)
 return root
# tree=build_tree(train_set, max_depth, min_size)
# print(tree)
 
# Make a prediction with a decision tree
def predict(node, row):
 print(row[node['index']])
 print(node['value'])
 if row[node['index']] < node['value']:#用测试集来代入训练的最好分割点,分割点有偏差时,通过搜索左右叉树来进一步比较。
 if isinstance(node['left'], dict):#如果是字典类型,执行操作
  return predict(node['left'], row)
 else:
  return node['left']
 else:
 if isinstance(node['right'], dict):
  return predict(node['right'], row)
 else:
  return node['right']
tree = build_tree(train_set, max_depth, min_size)
predictions = list()
for row in test_set:
 prediction = predict(tree, row)
 predictions.append(prediction)

11.评价决策树    
# Evaluate an algorithm using a cross validation split
def evaluate_algorithm(dataset, algorithm, n_folds, *args):
 folds = cross_validation_split(dataset, n_folds)
 scores = list()
 for fold in folds:
 train_set = list(folds)
 train_set.remove(fold)
 train_set = sum(train_set, [])
 test_set = list()
 for row in fold:
  row_copy = list(row)
  test_set.append(row_copy)
  row_copy[-1] = None
 predicted = algorithm(train_set, test_set, *args)
 actual = [row[-1] for row in fold]
 accuracy = accuracy_metric(actual, predicted)
 scores.append(accuracy)
 return scores
以上就是本文的全部内容,希望对大家的学习有所帮助

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