怎么理解spark的自定义分区和排序及spark与jdbc-创新互联
这篇文章将为大家详细讲解有关怎么理解spark的自定义分区和排序及spark与jdbc,文章内容质量较高,因此小编分享给大家做个参考,希望大家阅读完这篇文章后对相关知识有一定的了解。
创新互联坚持“要么做到,要么别承诺”的工作理念,服务领域包括:成都网站建设、成都网站设计、企业官网、英文网站、手机端网站、网站推广等服务,满足客户于互联网时代的儋州网站设计、移动媒体设计的需求,帮助企业找到有效的互联网解决方案。努力成为您成熟可靠的网络建设合作伙伴!//自定义分区 import org.apache.spark.SparkConf import org.apache.spark.SparkConf import org.apache.spark.SparkContext import org.apache.spark.Partitioner object PrimitivePartitionTest { def main(args: Array[String]): Unit = { val conf = new SparkConf conf.setMaster("local[2]").setAppName("Partitioner") val context = new SparkContext(conf) val rdd = context.parallelize(List(("hgs",2),("wd",44),("cm",99),("zz",100),("xzhh",67)), 2) //实例化类,并设置分区类 val partitioner = new CustomPartitioner(2) val rdd1 = rdd.partitionBy(partitioner) rdd1.saveAsTextFile("c:\\partitioner") context.stop() } } //自定义分区类继承spark的Partitioner class CustomPartitioner(val partitions:Int ) extends Partitioner{ def numPartitions: Int= this.partitions def getPartition(key: Any): Int={ if(key.toString().length()<=2) 0 else 1 } }
//自定义排序 package hgs.spark.othertest import org.apache.spark.SparkConf import org.apache.spark.SparkContext import scala.math.Ordered //自定义排序第一种实现方式,通过继承ordered class Student(val name:String,var age:Int) extends Ordered[Student] with Serializable{ def compare(that: Student): Int={ return this.age-that.age } } class Boy(val name:String,var age:Int) extends Serializable{ } //第二种方式通过实现隐式转换实现 object MyPredef{ implicit def toOrderBoy = new Ordering[Boy]{ def compare(x: Boy, y: Boy): Int={ x.age - y.age } } } //引入隐式转换 import MyPredef._ object CutstomOrder { def main(args: Array[String]): Unit = { val conf = new SparkConf() conf.setMaster("local[2]").setAppName("CutstomOrder") val context = new SparkContext(conf) val rdd = context.parallelize(List(("hgs",2),("wd",44),("cm",99),("zz",100),("xzhh",67)), 2) //下面的第二个参数false为降序排列 //val rdd_sorted = rdd.sortBy(f=>new Student(f._1,f._2), false, 1) val rdd_sorted = rdd.sortBy(f=>new Boy(f._1,f._2), false, 1) rdd_sorted.saveAsTextFile("d:\\ordered") context.stop() } }
//JDBC import org.apache.spark.SparkConf import org.apache.spark.SparkContext import org.apache.spark.rdd.JdbcRDD import java.sql.Connection import java.sql.DriverManager import java.sql.ResultSet import scala.collection.mutable.ListBuffer object DataFromJdbcToSpark { def main(args: Array[String]): Unit = { val conf = new SparkConf() conf.setMaster("local[2]").setAppName("BroadCastTest") val context = new SparkContext(conf) val sql = "select name,age from test where id>=? and id <=?" var list = new ListBuffer[(String,Int)]() //第七个参数是一个自定义的函数,spark会调用该函数,完成自定义的逻辑,y的数据类型是ResultSet,该函数不可以想自己定义的数组添加数据, //应为应用的函数会将结果保存在JdbcRDD中 val jdbcRDD = new JdbcRDD(context,getConnection,sql,1,8,2,y=>{ (y.getString(1),y.getInt(2)) }) println(jdbcRDD.collect().toBuffer) context.stop() } def getConnection():Connection={ Class.forName("com.mysql.jdbc.Driver") val conn = DriverManager.getConnection("jdbc:mysql://192.168.6.133:3306/hgs","root","123456"); conn } } //---------------------------------------------------------------------- package hgs.spark.othertest import java.sql.Connection import java.sql.DriverManager import org.apache.commons.dbutils.QueryRunner import org.apache.spark.SparkConf import org.apache.spark.SparkContext //将spark计算后的结果录入数据库 object DataFromSparktoJdbc { def main(args: Array[String]): Unit = { val conf = new SparkConf conf.setMaster("local[2]").setAppName("DataFromSparktoJdbc") val context = new SparkContext(conf) val addressrdd= context.textFile("d:\\words") val words = addressrdd.flatMap(_.split(" ")).map(x=>(x,1)).reduceByKey(_+_) //println(words.partitions.size) var p:Int =0 words.foreachPartition(iter=>{ //每个分区一个链接 val qr = new QueryRunner() val conn = getConnection println(conn) val sql = s"insert into words values(?,?)" //可以修改为批量插入效率更高 while(iter.hasNext){ val tpm = iter.next() val obj1 :Object = tpm._1 val obj2 :Object = new Integer(tpm._2) //obj1+conn.toString()可以看到数据库的插入数据作用有三个不同的链接 qr.update(conn, sql,obj1+conn.toString(),obj2) } //println(conn) //println(p) conn.close() }) words.saveAsTextFile("d:\\wordresult") } def getConnection():Connection={ Class.forName("com.mysql.jdbc.Driver") val conn = DriverManager.getConnection("jdbc:mysql://192.168.6.133:3306/hgs","root","123456"); conn } }
//广播变量 package hgs.spark.othertest import org.apache.spark.SparkConf import org.apache.spark.SparkContext object BroadCastTest{ def main(args: Array[String]): Unit = { val conf = new SparkConf() conf.setMaster("local[2]").setAppName("BroadCastTest") val context = new SparkContext(conf) val addressrdd= context.textFile("d:\\address") val splitaddrdd = addressrdd.map(x=>{ val cs = x.split(",") (cs(0),cs(1)) }).collect().toMap //广播变量,数据被缓存在每个节点,减少了节点之间的数据传送,可以有效的增加效率,广播出去的可以是任意的数据类型 val maprdd = context.broadcast(splitaddrdd) val namerdd = context.textFile("d:\\name") val result = namerdd.map(x=>{ //该出使用了广播的出去的数组 maprdd.value.getOrElse(x, "UnKnown") }) println(result.collect().toBuffer) context.stop() } }
其他一些知识点 1.spark 广播变量 rdd.brodcastz(rdd),广播变量的用处是将数据汇聚传输到各个excutor上面 ,这样在做数据处理的时候减少了数据的传输 2.wordcount程序 context.textFile(args(0),1).flatMap(_.split(" ")).map((_,1)).reduceByKey(_+_) wordcount程序代码,一个wordcount会产生5个RDD sc.textFile() 会产生两个RDD 1.HadoopRDD-> MapPartitionsRDD flatMap() 会产生MapPartitionsRDD map 会产生MapPartitionsRDD reduceByKey 产生ShuuledRDD saveAsTextFile 3.缓存数据到内存 rdd.cache 清理缓存 rdd.unpersist(true),rdd.persist存储及级别 cache方法调用的是persist方法 4.spark 远程debug,需要设置sparkcontext.setMaster("spark://xx.xx.xx.xx:7077").setJar("d:/jars/xx.jar")
关于怎么理解spark的自定义分区和排序及spark与jdbc就分享到这里了,希望以上内容可以对大家有一定的帮助,可以学到更多知识。如果觉得文章不错,可以把它分享出去让更多的人看到。
名称栏目:怎么理解spark的自定义分区和排序及spark与jdbc-创新互联
当前URL:http://pwwzsj.com/article/cshipe.html