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本文是讲如何使用spark ml进行线性回归,不涉及线性回归的原理。
1.1.1 格式为:
标签,特征值1 特征值2 特征值3...
1,1.9 2,3.1 3,4 3.5,4.45 4,5.02 9,9.97 -2,-0.98
1.1.2 spark 读取
1、Rdd
旧版(mllib)的线性回归要求传入的参数类型为RDDLabeledPoint
import org.apache.spark.SparkConf import org.apache.spark.SparkContext import org.apache.spark.mllib.linalg.Vectors import org.apache.spark.mllib.regression.LabeledPoint val data_path = "files/ml/linear_regression_data1.txt" val data = sc.textFile(data_path) val training = data.map { line => val arr = line.split(',') LabeledPoint(arr(0).toDouble, Vectors.dense(arr(1).split(' ').map(_.toDouble))) }.cache() training.foreach(println)
结果:
(1.0,[1.9]) (2.0,[3.1]) (3.0,[4.0]) (3.5,[4.45]) (4.0,[5.02]) (9.0,[9.97]) (-2.0,[-0.98])
一共有两列,第一列可以通过.label获得(类型为Double),第二列可以通过.features获得(类型为VectorDouble)
2、 DataFrame
新版(ml)的线性回归要求传入的参数类型为Dataset_
import org.apache.spark.ml.linalg.Vectors import org.apache.spark.sql.Row import spark.implicits._ val data_path = "files/ml/linear_regression_data1.txt" val data = spark.read.text(data_path) val training = data.map { case Row(line: String) => var arr = line.split(',') (arr(0).toDouble, Vectors.dense(arr(1).split(' ').map(_.toDouble))) }.toDF("label", "features") training.show()
结果:
+-----+--------+ |label|features| +-----+--------+ | 1.0| [1.9]| | 2.0| [3.1]| | 3.0| [4.0]| | 3.5| [4.45]| | 4.0| [5.02]| | 9.0| [9.97]| | -2.0| [-0.98]| +-----+--------+
其中列名"label", "features"固定,不能改为其他列名。
1.2.1 格式为:
label index1:value1 index2:value2 ...
其中每一行的index必须为升序
为了便于理解,造几条多维数据:
1 1:1.9 2:2 4:2 100:3 101:6 2 1:3.1 2:2 4:2 100:3 101:6 3 1:4 2:2 4:2 100:3 101:6 3.5 1:4.45 2:2 4:2 100:3 101:6 4 1:5.02 2:2 4:2 100:3 101:6 9 1:9.97 4:2 100:3 101:6 -2 1:-0.98 2:2 4:2 100:3 201:6
1.2.2 spark 读取
1、Rdd
import org.apache.spark.SparkConf import org.apache.spark.SparkContext import org.apache.spark.mllib.util.MLUtils val data_path = "files/ml/linear_regression_data2.txt" val training = MLUtils.loadLibSVMFile(sc, data_path) training.foreach(println)
结果:
(1.0,(201,[0,1,3,99,100],[1.9,2.0,2.0,3.0,6.0])) (2.0,(201,[0,1,3,99,100],[3.1,2.0,2.0,3.0,6.0])) (3.0,(201,[0,1,3,99,100],[4.0,2.0,2.0,3.0,6.0])) (3.5,(201,[0,1,3,99,100],[4.45,2.0,2.0,3.0,6.0])) (4.0,(201,[0,1,3,99,100],[5.02,2.0,2.0,3.0,6.0])) (9.0,(201,[0,3,99,100],[9.97,2.0,3.0,6.0])) (-2.0,(201,[0,1,3,99,200],[-0.98,2.0,2.0,3.0,6.0]))
返回类型为RDDLabeledPoint,其中第一列为label,第二列vector的第一个值为max(index),第二个index-1组成的数组,第三个为value组成的数组。
2、DataFrame
val data_path = "files/ml/linear_regression_data2.txt" val data = spark.read.text(data_path) val training = spark.read.format("libsvm").load(data_path) training.show(false)
结果:
+-----+--------------------------------------------+ |label|features | +-----+--------------------------------------------+ |1.0 |(201,[0,1,3,99,100],[1.9,2.0,2.0,3.0,6.0]) | |2.0 |(201,[0,1,3,99,100],[3.1,2.0,2.0,3.0,6.0]) | |3.0 |(201,[0,1,3,99,100],[4.0,2.0,2.0,3.0,6.0]) | |3.5 |(201,[0,1,3,99,100],[4.45,2.0,2.0,3.0,6.0]) | |4.0 |(201,[0,1,3,99,100],[5.02,2.0,2.0,3.0,6.0]) | |9.0 |(201,[0,3,99,100],[9.97,2.0,3.0,6.0]) | |-2.0 |(201,[0,1,3,99,200],[-0.98,2.0,2.0,3.0,6.0])| +-----+--------------------------------------------+
用libsvm格式的数据:
1 1:1.9 2 1:3.1 3 1:4 3.5 1:4.45 4 1:5.02 9 1:9.97 -2 1:-0.98
package com.dkl.leanring.spark.ml import org.apache.log4j.{ Level, Logger } import org.apache.spark.{ SparkConf, SparkContext } import org.apache.spark.mllib.regression.LinearRegressionWithSGD import org.apache.spark.mllib.util.MLUtils import org.apache.spark.mllib.regression.LabeledPoint import org.apache.spark.mllib.linalg.Vectors import org.apache.spark.mllib.regression.LinearRegressionModel object OldLinearRegression { def main(args: Array[String]) { // 构建Spark对象 val conf = new SparkConf().setAppName("OldLinearRegression").setMaster("local") val sc = new SparkContext(conf) Logger.getRootLogger.setLevel(Level.WARN) //读取样本数据 val data_path = "files/ml/linear_regression_data3.txt" val training = MLUtils.loadLibSVMFile(sc, data_path) val numTraing = training.count() // 新建线性回归模型,并设置训练参数 val numIterations = 10000 val stepSize = 0.5 val miniBatchFraction = 1.0 //书上的代码 intercept 永远为0 //val model = LinearRegressionWithSGD.train(examples, numIterations, stepSize, miniBatchFraction) var lr = new LinearRegressionWithSGD().setIntercept(true) lr.optimizer.setNumIterations(numIterations).setStepSize(stepSize).setMiniBatchFraction(miniBatchFraction) val model = lr.run(training) println(model.weights) println(model.intercept) // 对样本进行测试 val prediction = model.predict(training.map(_.features)) val predictionAndLabel = prediction.zip(training.map(_.label)) val print_predict = predictionAndLabel.take(20) println("prediction" + "\t" + "label") for (i <- 0 to print_predict.length - 1) { println(print_predict(i)._1 + "\t" + print_predict(i)._2) } // 计算测试误差 val loss = predictionAndLabel.map { case (p, l) => val err = p - l err * err }.reduce(_ + _) val rmse = math.sqrt(loss / numTraing) println(s"Test RMSE = $rmse.") } }
其中注释的第30行代码为书上的写法,但这样写intercept一直为0,也就是只适用于y=a*x的形式,不适用于y=ax+b,改为31、32替代即可。
结果:
[0.992894785953067] -0.9446037936869749 prediction label 0.9418962996238525 1.0 2.133370042767533 2.0 3.0269753501252934 3.0 3.473778003804174 3.5 4.039728031797421 4.0 8.954557222265104 9.0 -1.9176406839209805 -2.0 Test RMSE = 0.06866615969192089.
即a=0.992894785953067,b=-0.9446037936869749,y=0.992894785953067*x-0.9446037936869749
package com.dkl.leanring.spark.ml import org.apache.spark.ml.regression.LinearRegression import org.apache.spark.sql.SparkSession object NewLinearRegression { def main(args: Array[String]): Unit = { val spark = SparkSession .builder .appName("NewLinearRegression") .master("local") .getOrCreate() val data_path = "files/ml/linear_regression_data3.txt" import spark.implicits._ import org.apache.spark.ml.linalg.Vectors import org.apache.spark.sql.Row val training = spark.read.format("libsvm").load(data_path) val lr = new LinearRegression() .setMaxIter(10000) .setRegParam(0.3) .setElasticNetParam(0.8) val lrModel = lr.fit(training) println(s"Coefficients: ${lrModel.coefficients} Intercept: ${lrModel.intercept}") val trainingSummary = lrModel.summary println(s"numIterations: ${trainingSummary.totalIterations}") println(s"objectiveHistory: [${trainingSummary.objectiveHistory.mkString(",")}]") trainingSummary.residuals.show() println(s"RMSE: ${trainingSummary.rootMeanSquaredError}") println(s"r2: ${trainingSummary.r2}") trainingSummary.predictions.show() spark.stop() } }
结果:
Coefficients: [0.9072296333951224] Intercept: -0.630360819004294 numIterations: 3 objectiveHistory: [0.5,0.41543560544030766,0.08269406021049913] +--------------------+ | residuals| +--------------------+ | -0.0933754844464385| |-0.18205104452058585| |0.001442285423804...| | 0.09318895039599973| | 0.07606805936077965| | 0.5852813740549223| | -0.4805541402684861| +--------------------+ RMSE: 0.2999573166705823 r2: 0.9906296595124621 +-----+---------------+------------------+ |label| features| prediction| +-----+---------------+------------------+ | 1.0| (1,[0],[1.9])|1.0933754844464385| | 2.0| (1,[0],[3.1])| 2.182051044520586| | 3.0| (1,[0],[4.0])|2.9985577145761955| | 3.5| (1,[0],[4.45])|3.4068110496040003| | 4.0| (1,[0],[5.02])|3.9239319406392204| | 9.0| (1,[0],[9.97])| 8.414718625945078| | -2.0|(1,[0],[-0.98])|-1.519445859731514| +-----+---------------+------------------+
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