逻辑回归进行鸢尾花分类的案例
背景说明:
基于IDEA + Spark 3.4.1 + sbt 1.9.3 + Spark MLlib 构建逻辑回归鸢尾花分类预测模型,这是一个分类模型案例,通过该案例,可以快速了解Spark MLlib分类预测模型的使用方法。
依赖
ThisBuild / version := "0.1.0-SNAPSHOT"
ThisBuild / scalaVersion := "2.13.11"
lazy val root = (project in file("."))
.settings(
name := "SparkLearning",
idePackagePrefix := Some("cn.lh.spark"),
libraryDependencies += "org.apache.spark" %% "spark-sql" % "3.4.1",
libraryDependencies += "org.apache.spark" %% "spark-core" % "3.4.1",
libraryDependencies += "org.apache.hadoop" % "hadoop-auth" % "3.3.6", libraryDependencies += "org.apache.spark" %% "spark-streaming" % "3.4.1",
libraryDependencies += "org.apache.spark" %% "spark-streaming-kafka-0-10" % "3.4.1",
libraryDependencies += "org.apache.spark" %% "spark-mllib" % "3.4.1",
libraryDependencies += "mysql" % "mysql-connector-java" % "8.0.30"
)
代码如下:
package cn.lh.spark
import org.apache.spark.ml.{
Pipeline, PipelineModel}
import org.apache.spark.ml.classification.{
LogisticRegression, LogisticRegressionModel}
import org.apache.spark.ml.evaluation.MulticlassClassificationEvaluator
import org.apache.spark.ml.feature.{
IndexToString, StringIndexer, StringIndexerModel, VectorIndexer, VectorIndexerModel}
import org.apache.spark.ml.linalg.{
Vectors,Vector}
import org.apache.spark.rdd.RDD
import org.apache.spark.sql.{
DataFrame, Row, SparkSession}
case class Iris(features: org.apache.spark.ml.linalg.Vector, label: String)
/**
* 二项逻辑斯蒂回归来解决二分类问题
*/
object MLlibLogisticRegression {
def main(args: Array[String]): Unit = {
val spark: SparkSession = SparkSession.builder().master("local[2]")
.appName("Spark MLlib Demo List").getOrCreate()
val irisRDD: RDD[Iris] = spark.sparkContext.textFile("F:\\niit\\2023\\2023_2\\Spark\\codes\\data\\iris.txt")
.map(_.split(",")).map(p =>
Iris(Vectors.dense(p(0).toDouble, p(1).toDouble, p(2).toDouble, p(3).toDouble), p(4).toString()))
import spark.implicits._
val data: DataFrame = irisRDD.toDF()
data.show()
data.createOrReplaceTempView("iris")
val df: DataFrame = spark.sql("select * from iris where label != 'Iris-setosa'")
df.map(t => t(1)+":"+t(0)).collect().foreach(println)
// 构建ML的pipeline
val labelIndex: StringIndexerModel = new StringIndexer().setInputCol("label")
.setOutputCol("indexedLabel").fit(df)
val featureIndexer: VectorIndexerModel = new VectorIndexer().setInputCol("features")
.setOutputCol("indexedFeatures").fit(df)
// 划分数据集
val Array(trainingData, testData) = df.randomSplit(Array(0.7, 0.3))
// 设置逻辑回归模型参数
val lr: LogisticRegression = new LogisticRegression().setLabelCol("indexedLabel")
.setFeaturesCol("indexedFeatures").setMaxIter(10).setRegParam(0.3).setElasticNetParam(0.8)
// 设置一个labelConverter,目的是把预测的类别重新转化成字符型的
val labelConverter: IndexToString = new IndexToString().setInputCol("prediction")
.setOutputCol("predictedLabel").setLabels(labelIndex.labels)
// 构建pipeline,设置stage,然后调用fit()来训练模型
val lrPipeline: Pipeline = new Pipeline().setStages(Array(labelIndex, featureIndexer, lr, labelConverter))
val lrmodle: PipelineModel = lrPipeline.fit(trainingData)
val lrPredictions: DataFrame = lrmodle.transform(testData)
lrPredictions.select("predictedLabel", "label", "features", "probability")
.collect().foreach {
case Row(predictedLabel: String, label: String, features: Vector, prob: Vector) =>
println(s"($label, $features) --> prob=$prob, predicted Label=$predictedLabel")}
// 模型评估
val evaluator: MulticlassClassificationEvaluator = new MulticlassClassificationEvaluator()
.setLabelCol("indexedLabel").setPredictionCol("prediction")
val lrAccuracy: Double = evaluator.evaluate(lrPredictions)
println("Test Error = " + (1.0 - lrAccuracy))
val lrmodel2: LogisticRegressionModel = lrmodle.stages(2).asInstanceOf[LogisticRegressionModel]
println("Coefficients: " + lrmodel2.coefficients+"Intercept: " +
lrmodel2.intercept+"numClasses: "+lrmodel2.numClasses+"numFeatures: "+lrmodel2.numFeatures)
spark.stop()
}
}
运行结果如下:
