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本篇概览
本文是《Flink的DataSource三部曲》系列的第二篇,上一篇[《Flink的DataSource三部曲之一:直接API》]学习了StreamExecutionEnvironment的API创建DataSource,今天要练习的是Flink内置的connector,即下图的红框位置,这些connector可以通过StreamExecutionEnvironment的addSource方法使用:
今天的实战选择Kafka作为数据源来操作,先尝试接收和处理String型的消息,再接收JSON类型的消息,将JSON反序列化成bean实例;
环境和版本
本次实战的环境和版本如下:
- JDK:1.8.0_211
- Flink:1.9.2
- Maven:3.6.0
- 操作系统:macOS Catalina 10.15.3 (MacBook Pro 13-inch, 2018)
- IDEA:2018.3.5 (Ultimate Edition)
- Kafka:2.4.0
- Zookeeper:3.5.5
请确保上述内容都已经准备就绪,才能继续后面的实战;
Flink与Kafka版本匹配
- Flink官方对匹配Kafka版本做了详细说明,地址是:https://ci.apache.org/projects/flink/flink-docs-stable/dev/connectors/kafka.html
- 要重点关注的是官方提到的通用版(universal Kafka connector ),这是从Flink1.7开始推出的,对于Kafka1.0.0或者更高版本都可以使用:
3. 下图红框中是我的工程中要依赖的库,蓝框中是连接Kafka用到的类,读者您可以根据自己的Kafka版本在表格中找到适合的库和类:
实战字符串消息处理
- 在kafka上创建名为test001的topic,参考命令:
./kafka-topics.sh \
--create \
--zookeeper 192.168.50.43:2181 \
--replication-factor 1 \
--partitions 2 \
--topic test001
- 继续使用上一章创建的flinkdatasourcedemo工程,打开pom.xml文件增加以下依赖:
org.apache.flinkflink-connector-kafka_2.111.10.0
- 新增类Kafka240String.java,作用是连接broker,对收到的字符串消息做WordCount操作:
package com.bolingcavalry.connector;
import com.bolingcavalry.Splitter;
import org.apache.flink.api.common.serialization.SimpleStringSchema;
import org.apache.flink.streaming.api.datastream.DataStream;
import org.apache.flink.streaming.api.environment.StreamExecutionEnvironment;
import org.apache.flink.streaming.api.windowing.time.Time;
import org.apache.flink.streaming.connectors.kafka.FlinkKafkaConsumer;
import java.util.Properties;
import static com.sun.tools.doclint.Entity.para;
public class Kafka240String {
public static void main(String[] args) throws Exception {
StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
//设置并行度
env.setParallelism(2);
Properties properties = new Properties();
//broker地址
properties.setProperty("bootstrap.servers", "192.168.50.43:9092");
//zookeeper地址
properties.setProperty("zookeeper.connect", "192.168.50.43:2181");
//消费者的groupId
properties.setProperty("group.id", "flink-connector");
//实例化Consumer类
FlinkKafkaConsumer flinkKafkaConsumer = new FlinkKafkaConsumer<>(
"test001",
new SimpleStringSchema(),
properties
);
//指定从最新位置开始消费,相当于放弃历史消息
flinkKafkaConsumer.setStartFromLatest();
//通过addSource方法得到DataSource
DataStream dataStream = env.addSource(flinkKafkaConsumer);
//从kafka取得字符串消息后,分割成单词,统计数量,窗口是5秒
dataStream
.flatMap(new Splitter())
.keyBy(0)
.timeWindow(Time.seconds(5))
.sum(1)
.print();
env.execute("Connector DataSource demo : kafka");
}
}
- 确保kafka的topic已经创建,将Kafka240运行起来,可见消费消息并进行单词统计的功能是正常的:
5. 接收kafka字符串消息的实战已经完成,接下来试试JSON格式的消息;
实战JSON消息处理
- 接下来要接受的JSON格式消息,可以被反序列化成bean实例,会用到JSON库,我选择的是gson;
- 在pom.xml增加gson依赖:
com.google.code.gsongson2.8.5
- 增加类Student.java,这是个普通的Bean,只有id和name两个字段:
package com.bolingcavalry;
public class Student {
private int id;
private String name;
public int getId() {
return id;
}
public void setId(int id) {
this.id = id;
}
public String getName() {
return name;
}
public void setName(String name) {
this.name = name;
}
}
- 增加类StudentSchema.java,该类是DeserializationSchema接口的实现,将JSON反序列化成Student实例时用到:
ackage com.bolingcavalry.connector;
import com.bolingcavalry.Student;
import com.google.gson.Gson;
import org.apache.flink.api.common.serialization.DeserializationSchema;
import org.apache.flink.api.common.serialization.SerializationSchema;
import org.apache.flink.api.common.typeinfo.TypeInformation;
import java.io.IOException;
public class StudentSchema implements DeserializationSchema, SerializationSchema {
private static final Gson gson = new Gson();
/**
* 反序列化,将byte数组转成Student实例
* @param bytes
* @return
* @throws IOException
*/
@Override
public Student deserialize(byte[] bytes) throws IOException {
return gson.fromJson(new String(bytes), Student.class);
}
@Override
public boolean isEndOfStream(Student student) {
return false;
}
/**
* 序列化,将Student实例转成byte数组
* @param student
* @return
*/
@Override
public byte[] serialize(Student student) {
return new byte[0];
}
@Override
public TypeInformation getProducedType() {
return TypeInformation.of(Student.class);
}
}
- 新增类Kafka240Bean.java,作用是连接broker,对收到的JSON消息转成Student实例,统计每个名字出现的数量,窗口依旧是5秒:
package com.bolingcavalry.connector;
import com.bolingcavalry.Splitter;
import com.bolingcavalry.Student;
import org.apache.flink.api.common.functions.MapFunction;
import org.apache.flink.api.common.serialization.SimpleStringSchema;
import org.apache.flink.api.java.tuple.Tuple2;
import org.apache.flink.streaming.api.datastream.DataStream;
import org.apache.flink.streaming.api.environment.StreamExecutionEnvironment;
import org.apache.flink.streaming.api.windowing.time.Time;
import org.apache.flink.streaming.connectors.kafka.FlinkKafkaConsumer;
import java.util.Properties;
public class Kafka240Bean {
public static void main(String[] args) throws Exception {
StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
//设置并行度
env.setParallelism(2);
Properties properties = new Properties();
//broker地址
properties.setProperty("bootstrap.servers", "192.168.50.43:9092");
//zookeeper地址
properties.setProperty("zookeeper.connect", "192.168.50.43:2181");
//消费者的groupId
properties.setProperty("group.id", "flink-connector");
//实例化Consumer类
FlinkKafkaConsumer flinkKafkaConsumer = new FlinkKafkaConsumer<>(
"test001",
new StudentSchema(),
properties
);
//指定从最新位置开始消费,相当于放弃历史消息
flinkKafkaConsumer.setStartFromLatest();
//通过addSource方法得到DataSource
DataStream dataStream = env.addSource(flinkKafkaConsumer);
//从kafka取得的JSON被反序列化成Student实例,统计每个name的数量,窗口是5秒
dataStream.map(new MapFunction>() {
@Override
public Tuple2 map(Student student) throws Exception {
return new Tuple2<>(student.getName(), 1);
}
})
.keyBy(0)
.timeWindow(Time.seconds(5))
.sum(1)
.print();
env.execute("Connector DataSource demo : kafka bean");
}
}
- 在测试的时候,要向kafka发送JSON格式字符串,flink这边就会给统计出每个name的数量:
至此,内置connector的实战就完成了,接下来的章节,我们将要一起实战自定义DataSource;
随时随地看视频
