一、SparkStreaming概念
SparkStreaming是一个准实时的数据处理框架,支持对实时数据流进行可扩展、高吞吐量、容错的流处理,SparkStreaming可以从kafka、HDFS等中获取数据,经过SparkStreaming数据处理后保存到HDFS、数据库等。
sparkStreaming
spark streaming接收实时输入数据流,并将数据分为多个微批,然后由spark engine进行处理,批量生成最终结果流。
处理流程
二、基本操作
2.1初始化StreamingContext
Durations指定接收数据的延迟时间,多久触发一次job
SparkConf conf = new SparkConf().setMaster("local").setAppName("alarmCount"); JavaStreamingContext jssc = new JavaStreamingContext(conf, Durations.seconds(10));
2.2基本操作
1:streamingcontext.start() 开始接受数据
2:streamingContext.stop() 停止
2.3注意的点
1:上下文启动后,不能重新设置或添加新的流式计算
2:一个JVM进程中只能有一个StreamingContext 存活
2.4DStream
DStream是离散数据流,是由一系列RDD组成的序列
1:每个InputDStream对应一个接收器(文件流不需要接收器),一个接收器也只接受一个单一的数据流,但是SparkStreaming应用中可以创建多个输入流
2:每个接收器占用一个核,应用程序的核数要大于接收器数量,如果小于数据将无法全部梳理
三、从kafka中读取数据
通过KafkaUtils从kafka读取数据,读取数据有两种方式,createDstream和createDirectStream。
3.1:createDstream:基于Receiver的方式
1: kafka数据持续被运行在Spark workers/executors 中的Kafka Receiver接受,这种方式使用的是kafka的高阶用户API
2:接受到的数据存储在Spark workers/executors内存以及WAL(Write Ahead Logs), 在数据持久化到日志后,kafka接收器才会更新zookeeper中的offset
3:接受到的数据信息及WAL位置信息被可靠存储,失败时用于重新读取数据。
createDstream读取数流程
3.2:createDirectStream 直接读取方式
这种方式下需要自行管理offset,可以通过checkpoint或者数据库方式管理
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SparkStreaming
public class SparkStreaming { private static String CHECKPOINT_DIR = "/Users/dbq/Documents/checkpoint"; public static void main(String[] args) throws InterruptedException { //初始化StreamingContext SparkConf conf = new SparkConf().setMaster("local").setAppName("alarmCount"); JavaStreamingContext jssc = new JavaStreamingContext(conf, Durations.seconds(10)); jssc.checkpoint(CHECKPOINT_DIR); Map<String, Object> kafkaParams = new HashMap<>(); kafkaParams.put("metadata.broker.list", "172.*.*.6:9092,172.*.*.7:9092,172.*.*.8:9092"); kafkaParams.put("bootstrap.servers", "172.*.*.6:9092,172.*.*.7:9092,172.*.*.8:9092"); kafkaParams.put("key.deserializer", StringDeserializer.class); kafkaParams.put("value.deserializer", StringDeserializer.class); kafkaParams.put("group.id", "alarmGroup"); kafkaParams.put("auto.offset.reset", "latest"); kafkaParams.put("enable.auto.commit", true); Collection<String> topics = Arrays.asList("alarmTopic"); JavaInputDStream<ConsumerRecord<String, String>> messages = KafkaUtils.createDirectStream( jssc, LocationStrategies.PreferConsistent(), ConsumerStrategies.<String, String>Subscribe(topics, kafkaParams) ); JavaDStream<String> lines = messages.map((Function<ConsumerRecord<String, String>, String>) record -> record.value()); lines.foreachRDD((VoidFunction<JavaRDD<String>>) record -> { List<String> list = record.collect(); for (int i = 0; i < list.size(); i++) { writeToFile(list.get(i)); } }); lines.print(); jssc.start(); jssc.awaitTermination(); System.out.println("----------------end"); } //将结果写入到文件,也可以写入到MongoDB或者HDFS等 private synchronized static void writeToFile(String content) { String fileName = "/Users/dbq/Documents/result.txt"; FileWriter writer = null; try { writer = new FileWriter(fileName, true); writer.write(content + " \r\n"); } catch (IOException e) { e.printStackTrace(); } finally { try { if (writer != null) { writer.close(); } } catch (IOException e) { e.printStackTrace(); } } } }
Kafka的集成
生产者配置类
public class KafkaProducerConfig { @Value("${spring.kafka.bootstrap-servers}") private String broker; @Value("${spring.kafka.producer.acks}") private String acks; @Value("${spring.kafka.producer.retries}") private Integer retries; @Value("${spring.kafka.producer.batch-size}") private Integer batchSize; @Value("${spring.kafka.producer.buffer-memory}") private long bufferMemory; public Map<String, Object> getConfig() { Map<String, Object> props = new HashMap<>(); props.put(ProducerConfig.BOOTSTRAP_SERVERS_CONFIG, broker); props.put(ProducerConfig.ACKS_CONFIG, acks); props.put(ProducerConfig.RETRIES_CONFIG, retries); props.put(ProducerConfig.BATCH_SIZE_CONFIG, batchSize); props.put(ProducerConfig.BUFFER_MEMORY_CONFIG, bufferMemory); props.put(ProducerConfig.KEY_SERIALIZER_CLASS_CONFIG, StringSerializer.class); props.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, StringSerializer.class); return props; } }
Kafka生产者
@Component public class Producer { @Autowired private KafkaTemplate<String, String> kafkaTemplate; public void send(Message message) { kafkaTemplate.send("alarmTopic", JSONObject.toJSONString(message)); } }
配置kafkaTemplate
@Component public class PushMessageConfig { @Autowired private PushProducerListener producerListener; @Autowired private KafkaProducerConfig producerConfig; @Bean public KafkaTemplate<String, String> kafkaTemplate() { @SuppressWarnings({ "unchecked", "rawtypes" }) ProducerFactory<String, String> factory = new DefaultKafkaProducerFactory<>(producerConfig.getConfig()); KafkaTemplate<String, String> kafkaTemplate = new KafkaTemplate<>(factory, true); kafkaTemplate.setProducerListener(producerListener); kafkaTemplate.setDefaultTopic("alarmTopic"); return kafkaTemplate; } }
配置生产者监听
@Component public class PushProducerListener implements ProducerListener<String, String> { private Logger logger = LoggerFactory.getLogger(PushProducerListener.class); @Override public void onSuccess(String topic, Integer partition, String key, String value, RecordMetadata recordMetadata) { // 数据成功发送到消息队列 System.out.println("发送成功:" + value); logger.info("onSuccess. " + key + " : " + value); } @Override public void onError(String topic, Integer partition, String key, String value, Exception exception) { logger.error("onError. " + key + " : " + value); logger.error("catching an error when sending data to mq.", exception); // 发送到消息队列失败,直接在本地处理 } @Override public boolean isInterestedInSuccess() { // 发送成功后回调onSuccess,false则不回调 return true; } }
