Apache Spark 1.3.0引入了Direct API,利用Kafka的低层次API从Kafka集群中读取数据,并且在Spark Streaming系统里面维护偏移量相关的信息,并且通过这种方式去实现零数据丢失(zero data loss)相比使用基于Receiver的方法要高效。但是因为是Spark Streaming系统自己维护Kafka的读偏移量,而Spark Streaming系统并没有将这个消费的偏移量发送到Zookeeper中,这将导致那些基于偏移量的Kafka集群监控软件(比如:Apache Kafka监控之Kafka Web Console、Apache Kafka监控之KafkaOffsetMonitor等)失效。本文就是基于为了解决这个问题,使得我们编写的Spark Streaming程序能够在每次接收到数据之后自动地更新Zookeeper中Kafka的偏移量。
我们从Spark的官方文档可以知道,维护Spark内部维护Kafka便宜了信息是存储在HasOffsetRanges类的offsetRanges中,我们可以在Spark Streaming程序里面获取这些信息:
val offsetsList = rdd.asInstanceOf[HasOffsetRanges].offsetRanges
这样我们就可以获取所以分区消费信息,只需要遍历offsetsList,然后将这些信息发送到Zookeeper即可更新Kafka消费的偏移量。完整的代码片段如下:
val messages = KafkaUtils.createDirectStream[String, String, StringDecoder, StringDecoder](ssc, kafkaParams, topicsSet)
messages.foreachRDD(rdd => {
val offsetsList = rdd.asInstanceOf[HasOffsetRanges].offsetRanges
val kc = new KafkaCluster(kafkaParams)
for (offsets < - offsetsList) {
val topicAndPartition = TopicAndPartition("test-topic", offsets.partition)
val o = kc.setConsumerOffsets(args(0), Map((topicAndPartition, offsets.untilOffset)))
if (o.isLeft) {
println(s"Error updating the offset to Kafka cluster: ${o.left.get}")
}
}
})
KafkaCluster类用于建立和Kafka集群的链接相关的操作工具类,我们可以对Kafka中Topic的每个分区设置其相应的偏移量Map((topicAndPartition, offsets.untilOffset)),然后调用KafkaCluster类的setConsumerOffsets方法去更新Zookeeper里面的信息,这样我们就可以更新Kafka的偏移量,最后我们就可以通过KafkaOffsetMonitor之类软件去监控Kafka中相应Topic的消费信息,下图是KafkaOffsetMonitor的监控情况:
从图中我们可以看到KafkaOffsetMonitor监控软件已经可以监控到Kafka相关分区的消费情况,这对监控我们整个Spark Streaming程序来非常重要,因为我们可以任意时刻了解Spark读取速度。另外,KafkaCluster工具类的完整代码如下:
package org.apache.spark.streaming.kafka
import kafka.api.OffsetCommitRequest
import kafka.common.{ErrorMapping, OffsetMetadataAndError, TopicAndPartition}
import kafka.consumer.SimpleConsumer
import org.apache.spark.SparkException
import org.apache.spark.streaming.kafka.KafkaCluster.SimpleConsumerConfig
import scala.collection.mutable.ArrayBuffer
import scala.util.Random
import scala.util.control.NonFatal
class KafkaCluster(val kafkaParams: Map[String, String]) extends Serializable {
type Err = ArrayBuffer[Throwable]
@transient private var _config: SimpleConsumerConfig = null
def config: SimpleConsumerConfig = this.synchronized {
if (_config == null) {
_config = SimpleConsumerConfig(kafkaParams)
}
_config
}
def setConsumerOffsets(groupId: String,
offsets: Map[TopicAndPartition, Long]
): Either[Err, Map[TopicAndPartition, Short]] = {
setConsumerOffsetMetadata(groupId, offsets.map { kv =>
kv._1 -> OffsetMetadataAndError(kv._2)
})
}
def setConsumerOffsetMetadata(groupId: String,
metadata: Map[TopicAndPartition, OffsetMetadataAndError]
): Either[Err, Map[TopicAndPartition, Short]] = {
var result = Map[TopicAndPartition, Short]()
val req = OffsetCommitRequest(groupId, metadata)
val errs = new Err
val topicAndPartitions = metadata.keySet
withBrokers(Random.shuffle(config.seedBrokers), errs) { consumer =>
val resp = consumer.commitOffsets(req)
val respMap = resp.requestInfo
val needed = topicAndPartitions.diff(result.keySet)
needed.foreach { tp: TopicAndPartition =>
respMap.get(tp).foreach { err: Short =>
if (err == ErrorMapping.NoError) {
result += tp -> err
} else {
errs.append(ErrorMapping.exceptionFor(err))
}
}
}
if (result.keys.size == topicAndPartitions.size) {
return Right(result)
}
}
val missing = topicAndPartitions.diff(result.keySet)
errs.append(new SparkException(s"Couldn't set offsets for ${missing}"))
Left(errs)
}
private def withBrokers(brokers: Iterable[(String, Int)], errs: Err)
(fn: SimpleConsumer => Any): Unit = {
brokers.foreach { hp =>
var consumer: SimpleConsumer = null
try {
consumer = connect(hp._1, hp._2)
fn(consumer)
} catch {
case NonFatal(e) =>
errs.append(e)
} finally {
if (consumer != null) {
consumer.close()
}
}
}
}
def connect(host: String, port: Int): SimpleConsumer =
new SimpleConsumer(host, port, config.socketTimeoutMs,
config.socketReceiveBufferBytes, config.clientId)
}