Spark MLlib快速入门(1)逻辑回归、Kmeans、决策树案例

除了scikit-learn外，在spark中也提供了机器学习库，即Spark MLlib。

在Spark MLlib机器学习库提供两套算法实现的API：基于RDD API和基于DataFrame API。今天，主要介绍下DataFrame API的使用，不涉及算法的原理。

主要提供的算法如下：

• 分类

  • 逻辑回归、贝叶斯支持向量机

• 聚类

  • K-均值

• 推荐

  • 交替最小二乘法

• 回归

  • 线性回归

• 树

  • 决策树、随机森林

1 Spark MLlib中逻辑回归在鸢尾花数据集上的应用

鸢尾花数据集，总共150条数据，分为三种类别的鸢尾花。

鸢尾花数据集属于分类算法，构建分类模型，此处使用逻辑回归分类算法构建分类模型，进行预测。

全部基于DataFrame API算法库和特征工程函数使用。

使用的spark版本为2.3。

1.1 读取数据

package com.yyds.tags.ml.classificationimport org.apache.spark.ml.classification.{LogisticRegression, LogisticRegressionModel}
import org.apache.spark.ml.feature.{Normalizer, StringIndexer, StringIndexerModel, VectorAssembler}
import org.apache.spark.ml.linalg.Vectors
import org.apache.spark.sql.{DataFrame, SparkSession}
import org.apache.spark.sql.types.{DoubleType, StringType, StructType}
import org.apache.spark.storage.StorageLevelobject IrisClassification {def main(args: Array[String]): Unit = {// 构建SparkSession实例对象val spark: SparkSession = SparkSession.builder().appName(this.getClass.getSimpleName.stripSuffix("$")).master("local[4]").config("spark.sql.shuffle.partitions",4).getOrCreate()import spark.implicits._// TODO step1 -> 读取数据val isrsSchema: StructType = new StructType().add("sepal_length",DoubleType,nullable = true).add("sepal_width",DoubleType,nullable = true).add("petal_length",DoubleType,nullable = true).add("petal_width",DoubleType,nullable = true).add("category",StringType, nullable = true)val rawIrisDF: DataFrame =  spark.read.option("sep",",")// 当首行不是列名称时候，需要自动设置schema.option("header","false").option("inferSchema","false").schema(isrsSchema).csv("datas/iris/iris.data")rawIrisDF.printSchema()rawIrisDF.show(10,truncate = false)}}

root|-- sepal_length: double (nullable = true)|-- sepal_width: double (nullable = true)|-- petal_length: double (nullable = true)|-- petal_width: double (nullable = true)|-- category: string (nullable = true)+------------+-----------+------------+-----------+-----------+
|sepal_length|sepal_width|petal_length|petal_width|category   |
+------------+-----------+------------+-----------+-----------+
|5.1         |3.5        |1.4         |0.2        |Iris-setosa|
|4.9         |3.0        |1.4         |0.2        |Iris-setosa|
|4.7         |3.2        |1.3         |0.2        |Iris-setosa|
|4.6         |3.1        |1.5         |0.2        |Iris-setosa|
|5.0         |3.6        |1.4         |0.2        |Iris-setosa|
|5.4         |3.9        |1.7         |0.4        |Iris-setosa|
|4.6         |3.4        |1.4         |0.3        |Iris-setosa|
|5.0         |3.4        |1.5         |0.2        |Iris-setosa|
|4.4         |2.9        |1.4         |0.2        |Iris-setosa|
|4.9         |3.1        |1.5         |0.1        |Iris-setosa|
+------------+-----------+------------+-----------+-----------+

1.2 特征工程

    // TODO step2 -> 特征工程/*1、类别转换数值类型类别特征索引化 -> label2、组合特征值features: Vector*/// 1、类别特征转换 StringIndexerval indexerModel: StringIndexerModel = new StringIndexer().setInputCol("category").setOutputCol("label").fit(rawIrisDF)val df1: DataFrame = indexerModel.transform(rawIrisDF)// 2、组合特征值 VectorAssemblerval assembler: VectorAssembler = new VectorAssembler()// 设置特征列名称.setInputCols(rawIrisDF.columns.dropRight(1)).setOutputCol("raw_features")val rawFeaturesDF: DataFrame = assembler.transform(df1)// 3、特征值正则化，使用L2正则val normalizer: Normalizer = new Normalizer().setInputCol("raw_features").setOutputCol("features").setP(2.0)val featuresDF: DataFrame = normalizer.transform(rawFeaturesDF)// 将数据集缓存，LR算法属于迭代算法，使用多次featuresDF.persist(StorageLevel.MEMORY_AND_DISK).count()featuresDF.printSchema()featuresDF.show(10, truncate = false)

root|-- sepal_length: double (nullable = true)|-- sepal_width: double (nullable = true)|-- petal_length: double (nullable = true)|-- petal_width: double (nullable = true)|-- category: string (nullable = true)|-- label: double (nullable = true)|-- raw_features: vector (nullable = true)|-- features: vector (nullable = true)

1.3 训练模型

    // TODO step3 -> 模型训练val lr: LogisticRegression = new LogisticRegression()// 设置列名称.setLabelCol("label").setFeaturesCol("features").setPredictionCol("prediction")// 设置迭代次数.setMaxIter(10).setRegParam(0.3) // 正则化参数.setElasticNetParam(0.8) // 弹性网络参数：L1正则和L2正则联合使用val lrModel: LogisticRegressionModel = lr.fit(featuresDF)

1.4 模型预测

    // TODO step4 -> 使用模型预测val predictionDF: DataFrame = lrModel.transform(featuresDF)predictionDF// 获取真实标签类别和预测标签类别.select("label", "prediction").show(10)

1.5 模型评估

 // TODO step5 -> 模型评估：准确度 = 预测正确的样本数 / 所有的样本数import  org.apache.spark.ml.evaluation.MulticlassClassificationEvaluatorval evaluator = new MulticlassClassificationEvaluator().setLabelCol("label").setPredictionCol("prediction").setMetricName("accuracy")# accuracy = 0.9466666666666667println(s"accuracy = ${evaluator.evaluate(predictionDF)}")

1.6 模型的保存与加载

   // TODO step6 ->  模型调优，此处省略// TODO step7 ->  模型保存与加载val modelPath = s"datas/models/lrModel-${System.currentTimeMillis()}"// 保存模型lrModel.save(modelPath)// 加载模型val loadLrModel = LogisticRegressionModel.load(modelPath)// 模型预测loadLrModel.transform(Seq(Vectors.dense(Array(5.1,3.5,1.4,0.2))).map(x => Tuple1.apply(x)).toDF("features")).show(10, truncate = false)// 应用结束，关闭资源spark.stop()

2 Spark MLlib中KMeans在鸢尾花数据集上的应用

2.1 读取数据集

iris_kmeans.txt数据如下

1 1:5.1 2:3.5 3:1.4 4:0.2
1 1:4.9 2:3.0 3:1.4 4:0.2
1 1:4.7 2:3.2 3:1.3 4:0.2
1 1:4.6 2:3.1 3:1.5 4:0.2
1 1:5.0 2:3.6 3:1.4 4:0.2
1 1:5.4 2:3.9 3:1.7 4:0.4
1 1:4.6 2:3.4 3:1.4 4:0.3
1 1:5.0 2:3.4 3:1.5 4:0.2
1 1:4.4 2:2.9 3:1.4 4:0.2
1 1:4.9 2:3.1 3:1.5 4:0.1
1 1:5.4 2:3.7 3:1.5 4:0.2
1 1:4.8 2:3.4 3:1.6 4:0.2
1 1:4.8 2:3.0 3:1.4 4:0.1
1 1:4.3 2:3.0 3:1.1 4:0.1
1 1:5.8 2:4.0 3:1.2 4:0.2
1 1:5.7 2:4.4 3:1.5 4:0.4
1 1:5.4 2:3.9 3:1.3 4:0.4
1 1:5.1 2:3.5 3:1.4 4:0.3
1 1:5.7 2:3.8 3:1.7 4:0.3
1 1:5.1 2:3.8 3:1.5 4:0.3
1 1:5.4 2:3.4 3:1.7 4:0.2
1 1:5.1 2:3.7 3:1.5 4:0.4
1 1:4.6 2:3.6 3:1.0 4:0.2
1 1:5.1 2:3.3 3:1.7 4:0.5
1 1:4.8 2:3.4 3:1.9 4:0.2
1 1:5.0 2:3.0 3:1.6 4:0.2
1 1:5.0 2:3.4 3:1.6 4:0.4
1 1:5.2 2:3.5 3:1.5 4:0.2
1 1:5.2 2:3.4 3:1.4 4:0.2
1 1:4.7 2:3.2 3:1.6 4:0.2
1 1:4.8 2:3.1 3:1.6 4:0.2
1 1:5.4 2:3.4 3:1.5 4:0.4
1 1:5.2 2:4.1 3:1.5 4:0.1
1 1:5.5 2:4.2 3:1.4 4:0.2
1 1:4.9 2:3.1 3:1.5 4:0.1
1 1:5.0 2:3.2 3:1.2 4:0.2
1 1:5.5 2:3.5 3:1.3 4:0.2
1 1:4.9 2:3.1 3:1.5 4:0.1
1 1:4.4 2:3.0 3:1.3 4:0.2
1 1:5.1 2:3.4 3:1.5 4:0.2
1 1:5.0 2:3.5 3:1.3 4:0.3
1 1:4.5 2:2.3 3:1.3 4:0.3
1 1:4.4 2:3.2 3:1.3 4:0.2
1 1:5.0 2:3.5 3:1.6 4:0.6
1 1:5.1 2:3.8 3:1.9 4:0.4
1 1:4.8 2:3.0 3:1.4 4:0.3
1 1:5.1 2:3.8 3:1.6 4:0.2
1 1:4.6 2:3.2 3:1.4 4:0.2
1 1:5.3 2:3.7 3:1.5 4:0.2
1 1:5.0 2:3.3 3:1.4 4:0.2
2 1:7.0 2:3.2 3:4.7 4:1.4
2 1:6.4 2:3.2 3:4.5 4:1.5
2 1:6.9 2:3.1 3:4.9 4:1.5
2 1:5.5 2:2.3 3:4.0 4:1.3
2 1:6.5 2:2.8 3:4.6 4:1.5
2 1:5.7 2:2.8 3:4.5 4:1.3
2 1:6.3 2:3.3 3:4.7 4:1.6
2 1:4.9 2:2.4 3:3.3 4:1.0
2 1:6.6 2:2.9 3:4.6 4:1.3
2 1:5.2 2:2.7 3:3.9 4:1.4
2 1:5.0 2:2.0 3:3.5 4:1.0
2 1:5.9 2:3.0 3:4.2 4:1.5
2 1:6.0 2:2.2 3:4.0 4:1.0
2 1:6.1 2:2.9 3:4.7 4:1.4
2 1:5.6 2:2.9 3:3.6 4:1.3
2 1:6.7 2:3.1 3:4.4 4:1.4
2 1:5.6 2:3.0 3:4.5 4:1.5
2 1:5.8 2:2.7 3:4.1 4:1.0
2 1:6.2 2:2.2 3:4.5 4:1.5
2 1:5.6 2:2.5 3:3.9 4:1.1
2 1:5.9 2:3.2 3:4.8 4:1.8
2 1:6.1 2:2.8 3:4.0 4:1.3
2 1:6.3 2:2.5 3:4.9 4:1.5
2 1:6.1 2:2.8 3:4.7 4:1.2
2 1:6.4 2:2.9 3:4.3 4:1.3
2 1:6.6 2:3.0 3:4.4 4:1.4
2 1:6.8 2:2.8 3:4.8 4:1.4
2 1:6.7 2:3.0 3:5.0 4:1.7
2 1:6.0 2:2.9 3:4.5 4:1.5
2 1:5.7 2:2.6 3:3.5 4:1.0
2 1:5.5 2:2.4 3:3.8 4:1.1
2 1:5.5 2:2.4 3:3.7 4:1.0
2 1:5.8 2:2.7 3:3.9 4:1.2
2 1:6.0 2:2.7 3:5.1 4:1.6
2 1:5.4 2:3.0 3:4.5 4:1.5
2 1:6.0 2:3.4 3:4.5 4:1.6
2 1:6.7 2:3.1 3:4.7 4:1.5
2 1:6.3 2:2.3 3:4.4 4:1.3
2 1:5.6 2:3.0 3:4.1 4:1.3
2 1:5.5 2:2.5 3:4.0 4:1.3
2 1:5.5 2:2.6 3:4.4 4:1.2
2 1:6.1 2:3.0 3:4.6 4:1.4
2 1:5.8 2:2.6 3:4.0 4:1.2
2 1:5.0 2:2.3 3:3.3 4:1.0
2 1:5.6 2:2.7 3:4.2 4:1.3
2 1:5.7 2:3.0 3:4.2 4:1.2
2 1:5.7 2:2.9 3:4.2 4:1.3
2 1:6.2 2:2.9 3:4.3 4:1.3
2 1:5.1 2:2.5 3:3.0 4:1.1
2 1:5.7 2:2.8 3:4.1 4:1.3
3 1:6.3 2:3.3 3:6.0 4:2.5
3 1:5.8 2:2.7 3:5.1 4:1.9
3 1:7.1 2:3.0 3:5.9 4:2.1
3 1:6.3 2:2.9 3:5.6 4:1.8
3 1:6.5 2:3.0 3:5.8 4:2.2
3 1:7.6 2:3.0 3:6.6 4:2.1
3 1:4.9 2:2.5 3:4.5 4:1.7
3 1:7.3 2:2.9 3:6.3 4:1.8
3 1:6.7 2:2.5 3:5.8 4:1.8
3 1:7.2 2:3.6 3:6.1 4:2.5
3 1:6.5 2:3.2 3:5.1 4:2.0
3 1:6.4 2:2.7 3:5.3 4:1.9
3 1:6.8 2:3.0 3:5.5 4:2.1
3 1:5.7 2:2.5 3:5.0 4:2.0
3 1:5.8 2:2.8 3:5.1 4:2.4
3 1:6.4 2:3.2 3:5.3 4:2.3
3 1:6.5 2:3.0 3:5.5 4:1.8
3 1:7.7 2:3.8 3:6.7 4:2.2
3 1:7.7 2:2.6 3:6.9 4:2.3
3 1:6.0 2:2.2 3:5.0 4:1.5
3 1:6.9 2:3.2 3:5.7 4:2.3
3 1:5.6 2:2.8 3:4.9 4:2.0
3 1:7.7 2:2.8 3:6.7 4:2.0
3 1:6.3 2:2.7 3:4.9 4:1.8
3 1:6.7 2:3.3 3:5.7 4:2.1
3 1:7.2 2:3.2 3:6.0 4:1.8
3 1:6.2 2:2.8 3:4.8 4:1.8
3 1:6.1 2:3.0 3:4.9 4:1.8
3 1:6.4 2:2.8 3:5.6 4:2.1
3 1:7.2 2:3.0 3:5.8 4:1.6
3 1:7.4 2:2.8 3:6.1 4:1.9
3 1:7.9 2:3.8 3:6.4 4:2.0
3 1:6.4 2:2.8 3:5.6 4:2.2
3 1:6.3 2:2.8 3:5.1 4:1.5
3 1:6.1 2:2.6 3:5.6 4:1.4
3 1:7.7 2:3.0 3:6.1 4:2.3
3 1:6.3 2:3.4 3:5.6 4:2.4
3 1:6.4 2:3.1 3:5.5 4:1.8
3 1:6.0 2:3.0 3:4.8 4:1.8
3 1:6.9 2:3.1 3:5.4 4:2.1
3 1:6.7 2:3.1 3:5.6 4:2.4
3 1:6.9 2:3.1 3:5.1 4:2.3
3 1:5.8 2:2.7 3:5.1 4:1.9
3 1:6.8 2:3.2 3:5.9 4:2.3
3 1:6.7 2:3.3 3:5.7 4:2.5
3 1:6.7 2:3.0 3:5.2 4:2.3
3 1:6.3 2:2.5 3:5.0 4:1.9
3 1:6.5 2:3.0 3:5.2 4:2.0
3 1:6.2 2:3.4 3:5.4 4:2.3
3 1:5.9 2:3.0 3:5.1 4:1.8

package com.yyds.tags.ml.clusteringimport org.apache.spark.ml.clustering.{KMeans, KMeansModel}
import org.apache.spark.sql.{DataFrame, SparkSession}/*** 使用KMeans算法对鸢尾花数据进行聚类操作*/
object IrisClusterTest {def main(args: Array[String]): Unit = {val spark = SparkSession.builder().appName(this.getClass.getSimpleName.stripSuffix("$")).master("local[2]").config("spark.sql.shuffle.partitions", "2").getOrCreate()import org.apache.spark.sql.functions._import spark.implicits._// 1. 读取鸢尾花数据集val irisDF: DataFrame = spark.read.format("libsvm").load("datas/iris/iris_kmeans.txt")irisDF.printSchema()irisDF.show(10, truncate = false)}}

root|-- label: double (nullable = true)|-- features: vector (nullable = true)+-----+-------------------------------+
|label|features                       |
+-----+-------------------------------+
|1.0  |(4,[0,1,2,3],[5.1,3.5,1.4,0.2])|
|1.0  |(4,[0,1,2,3],[4.9,3.0,1.4,0.2])|
|1.0  |(4,[0,1,2,3],[4.7,3.2,1.3,0.2])|
|1.0  |(4,[0,1,2,3],[4.6,3.1,1.5,0.2])|
|1.0  |(4,[0,1,2,3],[5.0,3.6,1.4,0.2])|
|1.0  |(4,[0,1,2,3],[5.4,3.9,1.7,0.4])|
|1.0  |(4,[0,1,2,3],[4.6,3.4,1.4,0.3])|
|1.0  |(4,[0,1,2,3],[5.0,3.4,1.5,0.2])|
|1.0  |(4,[0,1,2,3],[4.4,2.9,1.4,0.2])|
|1.0  |(4,[0,1,2,3],[4.9,3.1,1.5,0.1])|
+-----+-------------------------------+
only showing top 10 rows

2.2 模型训练

// 2. 构建KMeans算法val kmeans: KMeans = new KMeans()// 设置输入特征列名称和输出列的名名称.setFeaturesCol("features").setPredictionCol("prediction")// 设置K值为3.setK(3)// 设置最大的迭代次数.setMaxIter(20)// 3. 应用数据集训练模型, 获取转换器val kMeansModel: KMeansModel = kmeans.fit(irisDF)// 获取聚类的簇中心点kMeansModel.clusterCenters.foreach(println)

[5.88360655737705,2.7409836065573776,4.388524590163936,1.4344262295081969]
[5.005999999999999,3.4180000000000006,1.4640000000000002,0.2439999999999999]
[6.853846153846153,3.0769230769230766,5.715384615384615,2.053846153846153]

2.3 模型评估和预测

   // 4. 模型评估val wssse: Double = kMeansModel.computeCost(irisDF)println(s"WSSSE = ${wssse}")// 5. 使用模型预测val predictionDF: DataFrame = kMeansModel.transform(irisDF)predictionDF.show(10, truncate = false)// 应用结束，关闭资源spark.stop()

+-----+-------------------------------+----------+
|label|features                       |prediction|
+-----+-------------------------------+----------+
|1.0  |(4,[0,1,2,3],[5.1,3.5,1.4,0.2])|1         |
|1.0  |(4,[0,1,2,3],[4.9,3.0,1.4,0.2])|1         |
|1.0  |(4,[0,1,2,3],[4.7,3.2,1.3,0.2])|1         |
|1.0  |(4,[0,1,2,3],[4.6,3.1,1.5,0.2])|1         |
|1.0  |(4,[0,1,2,3],[5.0,3.6,1.4,0.2])|1         |
|1.0  |(4,[0,1,2,3],[5.4,3.9,1.7,0.4])|1         |
|1.0  |(4,[0,1,2,3],[4.6,3.4,1.4,0.3])|1         |
|1.0  |(4,[0,1,2,3],[5.0,3.4,1.5,0.2])|1         |
|1.0  |(4,[0,1,2,3],[4.4,2.9,1.4,0.2])|1         |
|1.0  |(4,[0,1,2,3],[4.9,3.1,1.5,0.1])|1         |
+-----+-------------------------------+----------+

3 Spark MLlib中决策树入门案例

决策树学习采用的是 自顶向下 的递归方法 ，其基本思想是以信息熵为度量构造一颗熵值下降最快的树，到叶子节点处，熵值为0。其具有可读性、分类速度快的优点，是一种有监督学习。

最早提及决策树思想的是Quinlan在1986年提出的ID3算法和1993年提出的C4.5算法，以及Breiman等人在1984年提出的CART算法。

决策树算法是机器学习算法中非常重要的算法之一，既可以分类又可以回归，其中还可以构建出集成学习算法。

由于决策树分类模型 DecisionTreeClassificationModel 属于概率分类模型ProbabilisticClassificationModel ，所以构建模型时要求数据集中标签label必须从0开始。

上述数据集中特征：退款和婚姻状态，都是类别类型特征，需要将其转换为数值特征，数值从0开始计算。

针对 特征：退款 来说，将其转换为【0,1】两个值，不能是【1,2】数值。

3.1 读取数据

package com.yyds.tags.ml.classificationimport org.apache.spark.ml.classification.{DecisionTreeClassificationModel, DecisionTreeClassifier}
import org.apache.spark.ml.evaluation.MulticlassClassificationEvaluator
import org.apache.spark.ml.feature.{StringIndexer, StringIndexerModel, VectorIndexer, VectorIndexerModel}
import org.apache.spark.sql.{DataFrame, SparkSession}object DecisionTreeTest {def main(args: Array[String]): Unit = {val spark = SparkSession.builder().appName(this.getClass.getSimpleName.stripSuffix("$")).master("local[4]").getOrCreate()import org.apache.spark.sql.functions._import spark.implicits._// 1. 加载数据val dataframe: DataFrame = spark.read.format("libsvm").load("datas/iris/sample_libsvm_data.txt")dataframe.printSchema()dataframe.show(10, truncate = false)spark.stop()}}

3.2 特征工程

    // 2. 特征工程：特征提取、特征转换及特征选择// a. 将标签值label，转换为索引，从0开始，到 K-1val labelIndexer: StringIndexerModel = new StringIndexer().setInputCol("label").setOutputCol("index_label").fit(dataframe)val df1: DataFrame = labelIndexer.transform(dataframe)// b. 对类别特征数据进行特殊处理, 当每列的值的个数小于设置K，那么此列数据被当做类别特征，自动进行索引转换val featureIndexer: VectorIndexerModel = new VectorIndexer().setInputCol("features").setOutputCol("index_features").setMaxCategories(4).fit(df1)val df2: DataFrame = featureIndexer.transform(df1)df2.printSchema()df2.show(10, truncate = false)

root|-- label: double (nullable = true)|-- features: vector (nullable = true)|-- index_label: double (nullable = true)|-- index_features: vector (nullable = true)

3.3 训练模型

    // 3. 划分数据集：训练数据和测试数据val Array(trainingDF, testingDF) = df2.randomSplit(Array(0.8, 0.2))// 4. 使用决策树算法构建分类模型val dtc: DecisionTreeClassifier = new DecisionTreeClassifier().setLabelCol("index_label").setFeaturesCol("index_features")// 设置决策树算法相关超参数.setMaxDepth(5).setMaxBins(32)       // 此值必须大于等于类别特征类别个数.setImpurity("gini")  // 也可以是香农熵：entropyval dtcModel: DecisionTreeClassificationModel = dtc.fit(trainingDF)println(dtcModel.toDebugString)

DecisionTreeClassificationModel (uid=dtc_338073100075) of depth 1 with 3 nodesIf (feature 406 <= 72.0)Predict: 1.0Else (feature 406 > 72.0)Predict: 0.0

3.4 模型评估

    // 5. 模型评估，计算准确度val predictionDF: DataFrame = dtcModel.transform(testingDF)predictionDF.printSchema()predictionDF.select($"label", $"index_label", $"probability", $"prediction").show(10, truncate = false)val evaluator = new MulticlassClassificationEvaluator().setLabelCol("index_label").setPredictionCol("prediction").setMetricName("accuracy")val accuracy: Double = evaluator.evaluate(predictionDF)println(s"Accuracy = $accuracy")

Accuracy = 0.8823529411764706

4、ML Pipeline

管道 Pipeline 概念：将多个Transformer转换器和Estimators模型学习器按照 依赖顺序 组工作流WorkFlow形式，方面数据集的特征转换和模型训练及预测。

将上面的决策树分类代码，改为使用 Pipeline 构建模型与预测。

package com.yyds.tags.ml.classificationimport org.apache.spark.ml.{Pipeline, PipelineModel}
import org.apache.spark.ml.classification.{DecisionTreeClassificationModel, DecisionTreeClassifier}
import org.apache.spark.ml.evaluation.MulticlassClassificationEvaluator
import org.apache.spark.ml.feature.{StringIndexer, StringIndexerModel, VectorIndexer, VectorIndexerModel}
import org.apache.spark.sql.{DataFrame, SparkSession}object PipelineTest {def main(args: Array[String]): Unit = {val spark = SparkSession.builder().appName(this.getClass.getSimpleName.stripSuffix("$")).master("local[4]").getOrCreate()import org.apache.spark.sql.functions._import spark.implicits._// 1. 加载数据val dataframe: DataFrame = spark.read.format("libsvm").load("datas/iris/sample_libsvm_data.txt")//dataframe.printSchema()//dataframe.show(10, truncate = false)// 划分数据集：训练集和测试集val Array(trainingDF, testingDF) = dataframe.randomSplit(Array(0.8, 0.2))// 2. 构建管道Pipeline// a. 将标签值label，转换为索引，从0开始，到 K-1val labelIndexer = new StringIndexer().setInputCol("label").setOutputCol("index_label").fit(dataframe)// b. 对类别特征数据进行特殊处理, 当每列的值的个数小于设置K，那么此列数据被当做类别特征，自动进行索引转换val featureIndexer = new VectorIndexer().setInputCol("features").setOutputCol("index_features").setMaxCategories(4).fit(dataframe)// c. 使用决策树算法构建分类模型val dtc: DecisionTreeClassifier = new DecisionTreeClassifier().setLabelCol("index_label").setFeaturesCol("index_features")// 设置决策树算法相关超参数.setMaxDepth(5).setMaxBins(32) // 此值必须大于等于类别特征类别个数.setImpurity("gini")// d. 创建Pipeline，设置Stage（转换器和模型学习器）val pipeline: Pipeline = new Pipeline().setStages(Array(labelIndexer, featureIndexer, dtc))// 3. 训练模型val pipelineModel: PipelineModel = pipeline.fit(trainingDF)// 获取决策树分类模型val dtcModel: DecisionTreeClassificationModel =pipelineModel.stages(2).asInstanceOf[DecisionTreeClassificationModel]println(dtcModel.toDebugString)// 4. 模型评估val predictionDF: DataFrame = pipelineModel.transform(testingDF)predictionDF.printSchema()predictionDF.select($"label", $"index_label", $"probability", $"prediction").show(20, truncate = false)val evaluator = new MulticlassClassificationEvaluator().setLabelCol("index_label").setPredictionCol("prediction").setMetricName("accuracy")val accuracy: Double = evaluator.evaluate(predictionDF)println(s"Accuracy = $accuracy")// 应用结束，关闭资源spark.stop()}}

5、模型调优

使用决策树算法训练模型时，可以调整相关超参数，结合训练验证（Train-Validation Split）或交叉验证（Cross-Validation），获取最佳模型。

5.1 训练验证

将数据集划分为两个部分 ，静态的划分，一个用于训练模型，一个用于验证模型

通过评估指标，获取最佳模型，超参数设置比较好。

// 无论使用何种验证方式通过调整算法超参数来进行模型调优，需要使用工具类ParamGridBuilder 将 超参数封装到Map集合中
import org.apache.spark.ml.tuning.ParamGridBuilderval paramGrid: Array[ParamMap] = new ParamGridBuilder().addGrid(lr.regParam, Array(0.1, 0.01)).addGrid(lr.elasticNetParam, Array(0.0, 0.5, 1.0)).build()// 使用训练验证 TrainValidationSplit 方式获取最佳模型
val trainValidationSplit = new TrainValidationSplit().setEstimator(lr)                      // 也可以是pipeline.setEvaluator(new RegressionEvaluator) // 评估器.setEstimatorParamMaps(paramGrid)      // 超参数// 80% of the data will be used for training and the remaining 20% for validation..setTrainRatio(0.8)

训练验证的使用

package com.yyds.tags.ml.classificationimport org.apache.spark.ml.{Pipeline, PipelineModel}
import org.apache.spark.ml.classification.{DecisionTreeClassificationModel, DecisionTreeClassifier}
import org.apache.spark.ml.evaluation.MulticlassClassificationEvaluator
import org.apache.spark.ml.feature.{VectorAssembler, VectorIndexer}
import org.apache.spark.ml.param.ParamMap
import org.apache.spark.ml.tuning.{ParamGridBuilder, TrainValidationSplit, TrainValidationSplitModel}
import org.apache.spark.sql.{DataFrame, SparkSession}object HPO {/*** 调整算法超参数，找出最优模型* @param dataframe 数据集* @return*/def trainBestModel(dataframe: DataFrame): PipelineModel = {// a. 特征向量化val assembler: VectorAssembler = new VectorAssembler().setInputCols(Array("color", "product")).setOutputCol("raw_features")// b. 类别特征进行索引val indexer: VectorIndexer = new VectorIndexer().setInputCol("raw_features").setOutputCol("features").setMaxCategories(30)// .fit(dataframe)// c. 构建决策树分类器val dtc: DecisionTreeClassifier = new DecisionTreeClassifier().setFeaturesCol("features").setLabelCol("label").setPredictionCol("prediction")// d. 构建Pipeline管道流实例对象val pipeline: Pipeline = new Pipeline().setStages(Array(assembler, indexer, dtc))// e. 构建参数网格，设置超参数的值val paramGrid: Array[ParamMap] = new ParamGridBuilder().addGrid(dtc.maxDepth, Array(5, 10)).addGrid(dtc.impurity, Array("gini", "entropy")).addGrid(dtc.maxBins, Array(32, 64)).build()// f. 多分类评估器val evaluator = new MulticlassClassificationEvaluator().setLabelCol("label").setPredictionCol("prediction")// 指标名称，支持：f1、weightedPrecision、weightedRecall、accuracy.setMetricName("accuracy")// g. 训练验证val trainValidationSplit = new TrainValidationSplit().setEstimator(pipeline).setEvaluator(evaluator).setEstimatorParamMaps(paramGrid)// 80% of the data will be used for training and the remaining 20% for validation..setTrainRatio(0.8)// h. 训练模型val model: TrainValidationSplitModel =trainValidationSplit.fit(dataframe)// i. 获取最佳模型返回model.bestModel.asInstanceOf[PipelineModel]}}

5.2 交叉验证(K折)

将数据集划分为两个部分 ，动态的划分为K个部分数据集，其中1份数据集为验证数据集，其他K-1分数据为训练数据集，调整参数训练模型。

/*** 采用K-Fold交叉验证方式，调整超参数获取最佳PipelineModel模型* @param dataframe 数据集* @return*/def trainBestPipelineModel(dataframe: DataFrame): PipelineModel = {// a. 特征向量化val assembler: VectorAssembler = new VectorAssembler().setInputCols(Array("color", "product")).setOutputCol("raw_features")// b. 类别特征进行索引val indexer: VectorIndexer = new VectorIndexer().setInputCol("raw_features").setOutputCol("features").setMaxCategories(30)// .fit(dataframe)// c. 构建决策树分类器val dtc: DecisionTreeClassifier = new DecisionTreeClassifier().setFeaturesCol("features").setLabelCol("label").setPredictionCol("prediction")// d. 构建Pipeline管道流实例对象val pipeline: Pipeline = new Pipeline().setStages(Array(assembler, indexer, dtc))// e. 构建参数网格，设置超参数的值val paramGrid: Array[ParamMap] = new ParamGridBuilder().addGrid(dtc.maxDepth, Array(5, 10)).addGrid(dtc.impurity, Array("gini", "entropy")).addGrid(dtc.maxBins, Array(32, 64)).build()// f. 多分类评估器val evaluator = new MulticlassClassificationEvaluator().setLabelCol("label").setPredictionCol("prediction")// 指标名称，支持：f1、weightedPrecision、weightedRecall、accuracy.setMetricName("accuracy")// g. 构建交叉验证实例对象val crossValidator: CrossValidator = new CrossValidator().setEstimator(pipeline).setEvaluator(evaluator).setEstimatorParamMaps(paramGrid).setNumFolds(3)// h. 训练模式val crossValidatorModel: CrossValidatorModel =  crossValidator.fit(dataframe)// i. 获取最佳模型val pipelineModel: PipelineModel = crossValidatorModel.bestModel.asInstanceOf[PipelineModel]// j. 返回模型pipelineModel}