标签:-- bootstra ext 多个 分享 plain 简介 选择 设置
最近接触到一个APP流量分析的项目,类似于友盟。涉及到几个C端(客户端)高并发的接口,这几个接口主要用于C端数据的提交。在没有任何缓冲的情况下,一个接口涉及到5张表的提交。压测的结果很不理想,主要瓶颈就在与RDS的交互。
一台双核,16G机子,单实例,jdbc最大连接数100,吞吐量竟然只有50TPS。
能想到的改造方案就是引入一层缓冲,让C端接口不与RDS直接交互,很自然就想到了rabbitmq,但是rabbitmq对分布式的支持比较一般,我们的数据体量也比较大,所以我们借鉴了友盟,引入了kafka,Kafka是一种高吞吐量的分布式发布订阅消息系统,起初在不做任何kafka优化的时候,简单地将C端提交的数据直接send到单节点kafka,就这样,我们的吞吐量达到了100TPS.还是有点小惊喜的。
最近一段时间研究了一下kafka,对一些参数进行调整,目前接口的吞吐量已经达到220TPS,写这篇文章主要想记录一下自己优化和部署经历。
这张图很好的诠释了kafka的结构,但是遗漏了一点,就是group的概念,我这里补充一下,一个组可以包含多个consumer对多个topic进行消费,但是不同组的消费都是独立的。
也就是说同一个topic的同一条消息可以被不同组的consumer消费。
集群化都很好理解,那什么是多partition?
partition是topic的一个概念,即对topic进行分组,不同partition之间的消费相互独立,且有序。并且任意Partition在某一个时刻只能被一个Consumer Group内的一个Consumer消费,所以咯,假如topic只有一个partition的话,那么在一个Consumer Group内有效的消费者实例最多也就1个,并发度就会受限于kafka的partition数目。
上面都是讲消费,其实send操作也是一样的,要保证有序必然要等上一个发送ack之后,下一个发送才能进行,如果只有一个partition,那send之后的ack的等待时间必然会阻塞下面一次send,设计多个partition之后,可以同时往多个partition发送消息,自然吞吐量也就上去。
准备两台机子,然后去官网(http://kafka.apache.org/downloads)下载一个包。通过scp到服务器上,解压进入config目录,编辑server.config.
第一台机子配置(172.18.240.36):
broker.id=0 每台服务器的broker.id都不能相同 #hostname host.name=172.18.240.36 #在log.retention.hours=168 下面新增下面三项 message.max.byte=5242880 default.replication.factor=2 replica.fetch.max.bytes=5242880 #设置zookeeper的连接端口 zookeeper.connect=172.18.240.36:4001
#默认partition数
num.partitions=2
第二台机子配置(172.18.240.62):
broker.id=1 每台服务器的broker.id都不能相同 #hostname host.name=172.18.240.62 #在log.retention.hours=168 下面新增下面三项 message.max.byte=5242880 default.replication.factor=2 replica.fetch.max.bytes=5242880 #设置zookeeper的连接端口 zookeeper.connect=172.18.240.36:4001 #默认partition数 num.partitions=2
新增或者修改成以上配置。
对了,在此之前请先安装zookeeper,如果你用的是zookeeper集群的话,zookeeper.connect可以填写多个,中间用逗号隔开。
然后启动
|
1
|
nohup ./kafka-server-start.sh ../config/server.properties 1>/dev/null 2>&1 & |
测试一下:
在第一台机子上开启一个producer
./kafka-console-producer.sh --broker-list 172.18.240.36:9092 --topic test-test
在第二台机子上开启一个consumer
./kafka-console-consumer.sh --bootstrap-server 172.18.240.62:9092 --topic test-test --from-beginning
第一台机子发送一条消息
第二台机子立马收到消息
这样kafka的集群部署就完成了。就下来我们来看看,java的客户端代码如何编写。
我这里的工程是建立在spring boot 之下的,仅供参考。
在 application.yml下添加如下配置:
kafka:
consumer:
default:
server: 172.18.240.36:9092,172.18.240.62:9092
enableAutoCommit: false
autoCommitIntervalMs: 100
sessionTimeoutMs: 15000
groupId: data_analysis_group
autoOffsetReset: latest
producer:
default:
server: 172.18.240.36:9092,172.18.240.62:9092
retries: 0
batchSize: 4096
lingerMs: 1
bufferMemory: 40960
添加两个配置类
package com.dtdream.analysis.config;
import org.apache.kafka.clients.consumer.ConsumerConfig;
import org.apache.kafka.clients.consumer.ConsumerRecord;
import org.apache.kafka.common.serialization.StringDeserializer;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
import org.springframework.boot.context.properties.ConfigurationProperties;
import org.springframework.context.annotation.Bean;
import org.springframework.context.annotation.Configuration;
import org.springframework.kafka.annotation.EnableKafka;
import org.springframework.kafka.config.ConcurrentKafkaListenerContainerFactory;
import org.springframework.kafka.config.KafkaListenerContainerFactory;
import org.springframework.kafka.core.ConsumerFactory;
import org.springframework.kafka.core.DefaultKafkaConsumerFactory;
import org.springframework.kafka.listener.ConcurrentMessageListenerContainer;
import org.springframework.kafka.listener.adapter.RecordFilterStrategy;
import java.util.HashMap;
import java.util.Map;
@ConfigurationProperties(
prefix = "kafka.consumer.default"
)
@EnableKafka
@Configuration
public class KafkaConsumerConfig {
private static final Logger log = LoggerFactory.getLogger(KafkaConsumerConfig.class);
private static String autoCommitIntervalMs;
private static String sessionTimeoutMs;
private static Class keyDeserializerClass = StringDeserializer.class;
private static Class valueDeserializerClass = StringDeserializer.class;
private static String groupId = "test-group";
private static String autoOffsetReset = "latest";
private static String server;
private static boolean enableAutoCommit;
public static String getServer() {
return server;
}
public static void setServer(String server) {
KafkaConsumerConfig.server = server;
}
public static boolean isEnableAutoCommit() {
return enableAutoCommit;
}
public static void setEnableAutoCommit(boolean enableAutoCommit) {
KafkaConsumerConfig.enableAutoCommit = enableAutoCommit;
}
public static String getAutoCommitIntervalMs() {
return autoCommitIntervalMs;
}
public static void setAutoCommitIntervalMs(String autoCommitIntervalMs) {
KafkaConsumerConfig.autoCommitIntervalMs = autoCommitIntervalMs;
}
public static String getSessionTimeoutMs() {
return sessionTimeoutMs;
}
public static void setSessionTimeoutMs(String sessionTimeoutMs) {
KafkaConsumerConfig.sessionTimeoutMs = sessionTimeoutMs;
}
public static Class getKeyDeserializerClass() {
return keyDeserializerClass;
}
public static void setKeyDeserializerClass(Class keyDeserializerClass) {
KafkaConsumerConfig.keyDeserializerClass = keyDeserializerClass;
}
public static Class getValueDeserializerClass() {
return valueDeserializerClass;
}
public static void setValueDeserializerClass(Class valueDeserializerClass) {
KafkaConsumerConfig.valueDeserializerClass = valueDeserializerClass;
}
public static String getGroupId() {
return groupId;
}
public static void setGroupId(String groupId) {
KafkaConsumerConfig.groupId = groupId;
}
public static String getAutoOffsetReset() {
return autoOffsetReset;
}
public static void setAutoOffsetReset(String autoOffsetReset) {
KafkaConsumerConfig.autoOffsetReset = autoOffsetReset;
}
@Bean
public KafkaListenerContainerFactory<ConcurrentMessageListenerContainer<String, String>> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<String, String> factory = new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(consumerFactory());
factory.setConcurrency(10);
factory.getContainerProperties().setPollTimeout(3000);
factory.setRecordFilterStrategy(new RecordFilterStrategy<String, String>() {
@Override
public boolean filter(ConsumerRecord<String, String> consumerRecord) {
log.debug("partition is {},key is {},topic is {}",
consumerRecord.partition(), consumerRecord.key(), consumerRecord.topic());
return false;
}
});
return factory;
}
private ConsumerFactory<String, String> consumerFactory() {
return new DefaultKafkaConsumerFactory<>(consumerConfigs());
}
private Map<String, Object> consumerConfigs() {
Map<String, Object> propsMap = new HashMap<>();
propsMap.put(ConsumerConfig.BOOTSTRAP_SERVERS_CONFIG, server);
propsMap.put(ConsumerConfig.ENABLE_AUTO_COMMIT_CONFIG, enableAutoCommit);
propsMap.put(ConsumerConfig.AUTO_COMMIT_INTERVAL_MS_CONFIG, autoCommitIntervalMs);
propsMap.put(ConsumerConfig.SESSION_TIMEOUT_MS_CONFIG, sessionTimeoutMs);
propsMap.put(ConsumerConfig.KEY_DESERIALIZER_CLASS_CONFIG, keyDeserializerClass);
propsMap.put(ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG, valueDeserializerClass);
propsMap.put(ConsumerConfig.GROUP_ID_CONFIG, groupId);
propsMap.put(ConsumerConfig.AUTO_OFFSET_RESET_CONFIG, autoOffsetReset);
return propsMap;
}
/* @Bean
public Listener listener() {
return new Listener();
}*/
}
package com.dtdream.analysis.config;
import org.apache.kafka.clients.producer.ProducerConfig;
import org.apache.kafka.common.serialization.StringSerializer;
import org.springframework.boot.context.properties.ConfigurationProperties;
import org.springframework.context.annotation.Bean;
import org.springframework.context.annotation.Configuration;
import org.springframework.kafka.annotation.EnableKafka;
import org.springframework.kafka.core.DefaultKafkaProducerFactory;
import org.springframework.kafka.core.KafkaTemplate;
import org.springframework.kafka.core.ProducerFactory;
import java.util.HashMap;
import java.util.Map;
/**
* Created with IntelliJ IDEA.
* User: chenqimiao
* Date: 2017/7/24
* Time: 9:43
* To change this template use File | Settings | File Templates.
*/
@ConfigurationProperties(
prefix = "kafka.producer.default",
ignoreInvalidFields = true
)//注入一些属性域
@EnableKafka
@Configuration//使得@Bean注解生效
public class KafkaProducerConfig {
private static String server;
private static Integer retries;
private static Integer batchSize;
private static Integer lingerMs;
private static Integer bufferMemory;
private static Class keySerializerClass = StringSerializer.class;
private static Class valueSerializerClass = StringSerializer.class;
private Map<String, Object> producerConfigs() {
Map<String, Object> props = new HashMap<>();
props.put(ProducerConfig.BOOTSTRAP_SERVERS_CONFIG, server);
props.put(ProducerConfig.RETRIES_CONFIG, retries);
props.put(ProducerConfig.BATCH_SIZE_CONFIG, batchSize);
props.put(ProducerConfig.LINGER_MS_CONFIG, lingerMs);
props.put(ProducerConfig.BUFFER_MEMORY_CONFIG, bufferMemory);
props.put(ProducerConfig.KEY_SERIALIZER_CLASS_CONFIG, keySerializerClass);
props.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, valueSerializerClass);
return props;
}
private ProducerFactory<String, String> producerFactory() {
return new DefaultKafkaProducerFactory<>(producerConfigs());
}
public static String getServer() {
return server;
}
public static void setServer(String server) {
KafkaProducerConfig.server = server;
}
public static Integer getRetries() {
return retries;
}
public static void setRetries(Integer retries) {
KafkaProducerConfig.retries = retries;
}
public static Integer getBatchSize() {
return batchSize;
}
public static void setBatchSize(Integer batchSize) {
KafkaProducerConfig.batchSize = batchSize;
}
public static Integer getLingerMs() {
return lingerMs;
}
public static void setLingerMs(Integer lingerMs) {
KafkaProducerConfig.lingerMs = lingerMs;
}
public static Integer getBufferMemory() {
return bufferMemory;
}
public static void setBufferMemory(Integer bufferMemory) {
KafkaProducerConfig.bufferMemory = bufferMemory;
}
public static Class getKeySerializerClass() {
return keySerializerClass;
}
public static void setKeySerializerClass(Class keySerializerClass) {
KafkaProducerConfig.keySerializerClass = keySerializerClass;
}
public static Class getValueSerializerClass() {
return valueSerializerClass;
}
public static void setValueSerializerClass(Class valueSerializerClass) {
KafkaProducerConfig.valueSerializerClass = valueSerializerClass;
}
@Bean(name = "kafkaTemplate")
public KafkaTemplate<String, String> kafkaTemplate() {
return new KafkaTemplate<>(producerFactory());
}
}
利用kafkaTemplate即可完成发送。
@Autowired
private KafkaTemplate<String,String> kafkaTemplate;
@RequestMapping(
value = "/openApp",
method = RequestMethod.POST,
produces = MediaType.APPLICATION_JSON_UTF8_VALUE,
consumes = MediaType.APPLICATION_JSON_UTF8_VALUE
)
@ResponseBody
public ResultDTO openApp(@RequestBody ActiveLogPushBo activeLogPushBo, HttpServletRequest request) {
logger.info("openApp: activeLogPushBo {}, dateTime {}", JSONObject.toJSONString(activeLogPushBo),new DateTime().toString("yyyy-MM-dd HH:mm:ss.SSS"));
String ip = (String) request.getAttribute("ip");
activeLogPushBo.setIp(ip);
activeLogPushBo.setDate(new Date());
//ResultDTO resultDTO = dataCollectionService.collectOpenInfo(activeLogPushBo);
kafkaTemplate.send("data_collection_open",JSONObject.toJSONString(activeLogPushBo));
// logger.info("openApp: resultDTO {} ,dateTime {}", resultDTO.toJSONString(),new DateTime().toString("yyyy-MM-dd HH:mm:ss.SSS"));
return new ResultDTO().success();
}
kafkaTemplate的send方法会更根据你指定的key进行hash,再对partition数进行去模,最后决定发送到那一个分区,假如没有指定key,那send方法对分区的选择是随机。具体怎么随机的话,这里就不展开讲了,有兴趣的同学可以自己看源码,我们可以交流交流。
接着配置一个监听器
package com.dtdream.analysis.listener;
import org.apache.kafka.clients.consumer.ConsumerRecord;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
import org.springframework.kafka.annotation.KafkaListener;
import java.util.Optional;
@Component
public class Listener {
private Logger logger = LoggerFactory.getLogger(this.getClass());
@KafkaListener(topics = {"test-topic"})
public void listen(ConsumerRecord<?, ?> record) {
Optional<?> kafkaMessage = Optional.ofNullable(record.value());
if (kafkaMessage.isPresent()) {
Object message = kafkaMessage.get();
logger.info("message is {} ", message);
}
}
}
@KafkaListener其实可以具体指定消费哪个分区,如果不指定的话,并且只有一个消费者实例,那么这个实例会消费所有的分区的消息。
消费者的数量是一定要少于partition的数量的,不然没有任何意义。会出现消费者过剩的情况。
消费者数量和partition数量的多与少,会动态影响消费节点所消费的partition数目,最终会在整个集群中达到一种动态平衡。
具体的关系可以参考http://www.jianshu.com/p/6233d5341dfe
标签:-- bootstra ext 多个 分享 plain 简介 选择 设置
原文地址:http://www.cnblogs.com/Leo_wl/p/7276993.html
