推荐系统-05-Spark电影推荐、评估与部署

时间:2023-03-09 07:15:48
推荐系统-05-Spark电影推荐、评估与部署

一、新建scala项目

推荐系统-05-Spark电影推荐、评估与部署

二、构造程序

推荐系统-05-Spark电影推荐、评估与部署

代码如下

package xyz.pl8

import java.io.File

import org.apache.log4j.{Level, Logger}

import org.apache.spark.{SparkContext, SparkConf}

import org.apache.spark.mllib.evaluation.RegressionMetrics

import org.apache.spark.mllib.recommendation.{MatrixFactorizationModel, Rating, ALS}

import org.apache.spark.rdd.RDD

import scala.util.Random

object MovieLensALS {

  //1. Define a rating elicitation function

  // Seq[Rating]

  def elicitateRating(movies: Seq[(Int, String)])={

    val prompt="Please rate the following movie(1-5(best) or 0 if not seen: )"

    println(prompt)

    val ratings= movies.flatMap{x=>

      var rating: Option[Rating] = None  //  Rating(user: Int, product: Int, rating: Double)

      var valid = false

      while(!valid){

        println(x._2+" :")

        try{

          val r = Console.readInt()

          if (r>5 || r<0){

            println(prompt)

          } else {

            valid = true

            if (r>0){

              rating = Some(Rating(0, x._1, r))

            }

          }

        } catch{

          case e:Exception => println(prompt)

        }

      }

      rating match {

        case Some(r) => Iterator(r)  // FlatMap将结构解散成元素, 这里是Rating

        case None => Iterator.empty

      }

    }

    if (ratings.isEmpty){

      error("No ratings provided!")

    } else {

      ratings

    }

  }

  //2. Define a RMSE computation function

  def computeRmse(model: MatrixFactorizationModel, data: RDD[Rating]) = {

    val prediction = model.predict(data.map(x=>(x.user, x.product)))

    val predDataJoined = prediction.map(x=> ((x.user,x.product),x.rating)).join(data.map(x=> ((x.user,x.product),x.rating))).values

    new RegressionMetrics(predDataJoined).rootMeanSquaredError

  }

  //3. Main

  def main(args: Array[String]) {

  //3.1 Setup env

    Logger.getLogger("org.apache.spark").setLevel(Level.WARN)

    if (args.length !=1){

      print("Usage: movieLensHomeDir")

      sys.exit(1)

    }

    val conf = new SparkConf().setAppName("MovieLensALS")

    .set("spark.executor.memory","500m")

    val sc = new SparkContext(conf)

  //3.2 Load ratings data and know your data

  // ratings.dat 的格式 UserID::MovieID::Rating::Timestamp

    val movieLensHomeDir=args(0)

	// RDD[long, Rating]

    val ratings = sc.textFile(new File(movieLensHomeDir, "ratings.dat").toString).map {line =>

       val fields = line.split("::")

      //timestamp, user, product, rating

	  // 取模成分成10组

      (fields(3).toLong%10, Rating(fields(0).toInt, fields(1).toInt, fields(2).toDouble))

    }

	// movies.dat格式 MovieID::Title::Genres

	// Map[Int,String]

    val movies = sc.textFile(new File(movieLensHomeDir, "movies.dat").toString).map {line =>

      val fields = line.split("::")

      //movieId, movieName

      (fields(0).toInt, fields(1))

    }.collectAsMap()

    val numRatings = ratings.count()

    val numUser = ratings.map(x=>x._2.user).distinct().count()

    val numMovie = ratings.map(_._2.product).distinct().count()

    println("Got "+numRatings+" ratings from "+numUser+" users on "+numMovie+" movies.")

  //3.3 Elicitate personal rating

    // = RDD[(long,Rating) -> Array[int] -> Map[Int, long] -> Seq[(Int, long)] -> Seq[(Int,long)] ->  Seq[Int]

    val topMovies = ratings.map(_._2.product).countByValue().toSeq.sortBy(-_._2).take(50).map(_._1)

    val random = new Random(0)

	// Seq[(Int, String)]

    val selectMovies = topMovies.filter(x=>random.nextDouble() < 0.2).map(x=>(x, movies(x)))

    val myRatings = elicitateRating(selectMovies)

    val myRatingsRDD = sc.parallelize(myRatings, 1)

  //3.4 Split data into train(60%), validation(20%) and test(20%)

    val numPartitions = 10

		// 6组(即60%),并上手工输入评价

	    val trainSet = ratings.filter(x=>x._1<6).map(_._2).union(myRatingsRDD).repartition(numPartitions).persist()

    val validationSet = ratings.filter(x=>x._1>=6 && x._1<8).map(_._2).persist()

    val testSet = ratings.filter(x=>x._1>=8).map(_._2).persist()

    val numTrain = trainSet.count()

    val numValidation = validationSet.count()

    val numTest = testSet.count()

    println("Training data: "+numTrain+" Validation data: "+numValidation+" Test data: "+numTest)

  //3.5 Train model and optimize model with validation set

    val numRanks = List(8, 12)

    val numIters = List(10, 20)

    val numLambdas = List(0.1, 10.0)

    var bestRmse = Double.MaxValue

    var bestModel: Option[MatrixFactorizationModel] = None

    var bestRanks = -1

    var bestIters = 0

    var bestLambdas = -1.0

	// 寻找优化参数的模型

    for(rank <- numRanks; iter <- numIters; lambda <- numLambdas){

      val model = ALS.train(trainSet, rank, iter, lambda)

      val validationRmse = computeRmse(model, validationSet)

      println("RMSE(validation) = "+validationRmse+" with ranks="+rank+", iter="+iter+", Lambda="+lambda)

      if (validationRmse < bestRmse) {

        bestModel = Some(model)

        bestRmse = validationRmse

        bestIters = iter

        bestLambdas = lambda

        bestRanks = rank

      }

    }

    //3.6 Evaluate model on test set

	// 用测试集来评估模型

	// 测试集均方根差

    val testRmse = computeRmse(bestModel.get, testSet)

    println("The best model was trained with rank="+bestRanks+", Iter="+bestIters+", Lambda="+bestLambdas+

      " and compute RMSE on test is "+testRmse)

    //3.7 Create a baseline and compare it with best model

	// 创建基线 并与模型进行比较

    val meanRating = trainSet.union(validationSet).map(_.rating).mean() // 训练集与验证集和的均数

	// 最佳根均方错误线(基线)

    val bestlineRmse = new RegressionMetrics(testSet.map(x=>(x.rating, meanRating))).rootMeanSquaredError  // 测试集与均数的均方根差

	// testRmse(这个数应该更优,值更小)

    val improvement = (bestlineRmse - testRmse)/bestlineRmse*100

    println("The best model improves the baseline by "+"%1.2f".format(improvement)+"%.")

    //3.8 Make a personal recommendation

	// 进行个人推荐, 排除自己已经评分内容

    val moviesId = myRatings.map(_.product)

    val candidates = sc.parallelize(movies.keys.filter(!moviesId.contains(_)).toSeq)

    val recommendations = bestModel.get

    .predict(candidates.map(x=>(0, x)))

    .sortBy(-_.rating)

    .take(50)

    var i = 0

    println("Movies recommended for you:")

    recommendations.foreach{ line=>

      println("%2d".format(i)+" :"+movies(line.product))

      i += 1

    }

  sc.stop()

  }

}

导入引用库

推荐系统-05-Spark电影推荐、评估与部署

三、打包部署

程序运行时,需要指定输入数据路径,数据包含了ratings.dat和movies.dat,数据都包含在了一个数据包。点击下载, 然后解压。

配置运行参数

  • 点击edit configuration,在左侧点击该项目。在右侧在右侧VM options中输入“-Dspark.master=local”,指示本程序本地单线程运行

  • 在Program argguemnts指定,上面解压的路径。

    然后,在IDEA上选择MovieLensALS右键选择运行,即可运行了。

    按照引导,输入自己的评价后,最后输出形式如下:

    The best model was trained with rank=12, Iter=20, Lambda=0.1 and compute RMSE on test is 0.868464888081759

    The best model improves the baseline by 22.01%.

    Movies recommended for you:

    0 :Julien Donkey-Boy (1999)

    1 :Love Serenade (1996)

    2 :Catwalk (1995)

四、HADOOP集群部署

导出jar包设置

推荐系统-05-Spark电影推荐、评估与部署

选main类对后,点击OK确定, 这个时候配置已经完成了, 我们就可以进行编译 jar文件了, 选择菜单Build->Build Artifacts..., 生成的文件路径为/out/artifacts/MovieLensALS_jar/MovieLensALS.jar

准备HADOOP环境

假设我们的HADOOP环境已经搭建成功。 接下来我们要把需要计算的数据文件上传到hadoop; 首先,在hadoop上面创建文件夹,命令如下:

hdfs dfs -mkdir -p /recommendation/data

上传数据文件命令如下:

hdfs dfs -put *.dat /recommendation/data

这时时候我们可以通过命令查看,上传是否成功

hdfs dfs -cat /recommendation/data/users.dat

运行

推荐系统-05-Spark电影推荐、评估与部署

在上面红框中,指定了生成的jar文件名, 所在路径, 以及MainClass。这面就是通过spark执行:

/usr/local/spark/spark-2.3.0-bin-hadoop2.7/bin/spark-submit --master local  --class "xyz.pl8.MovieLensALS" /home/hartifacts/movielensals_jar/movielensals.jar /recommendation/data

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