最近在生产环境刚好遇到了延时任务的场景,调研了一下目前主流的方案,分析了一下优劣并且敲定了最终的方案。这篇文章记录了调研的过程,以及初步方案的实现。
候选方案对比
下面是想到的几种实现延时任务的方案,总结了一下相应的优势和劣势。
方案
优势
劣势
选用场景
JDK
内置的延迟队列 DelayQueue
实现简单
数据内存态,不可靠
一致性相对低的场景
调度框架和 MySQL
进行短间隔轮询
实现简单,可靠性高
存在明显的性能瓶颈
数据量较少实时性相对低的场景
RabbitMQ
的 DLX
和 TTL
,一般称为 死信队列 方案
异步交互可以削峰
延时的时间长度不可控,如果数据需要持久化则性能会降低
-
调度框架和 Redis
进行短间隔轮询
数据持久化,高性能
实现难度大
常见于支付结果回调方案
时间轮
实时性高
实现难度大,内存消耗大
实时性高的场景
如果应用的数据量不高,实时性要求比较低,选用调度框架和 MySQL
进行短间隔轮询这个方案是最优的方案。但是笔者遇到的场景数据量相对比较大,实时性并不高,采用扫库的方案一定会对 MySQL
实例造成比较大的压力。记得很早之前,看过一个PPT叫《盒子科技聚合支付系统演进》,其中里面有一张图片给予笔者一点启发:
里面刚好用到了调度框架和 Redis
进行短间隔轮询实现延时任务的方案,不过为了分摊应用的压力,图中的方案还做了分片处理。鉴于笔者当前业务紧迫,所以在第一期的方案暂时不考虑分片,只做了一个简化版的实现。
由于PPT中没有任何的代码或者框架贴出,有些需要解决的技术点需要自行思考,下面会重现一次整个方案实现的详细过程。
场景设计
实际的生产场景是笔者负责的某个系统需要对接一个外部的资金方,每一笔资金下单后需要延时30分钟推送对应的附件。这里简化为一个订单信息数据延迟处理的场景,就是每一笔下单记录一条订单消息(暂时叫做 OrderMessage
),订单消息需要延迟5到15秒后进行异步处理。
否决的候选方案实现思路
下面介绍一下其它四个不选用的候选方案,结合一些伪代码和流程分析一下实现过程。
JDK内置延迟队列
DelayQueue
是一个阻塞队列的实现,它的队列元素必须是 Delayed
的子类,这里做个简单的例子:
public class DelayQueueMain { private static final Logger LOGGER = LoggerFactory.getLogger(DelayQueueMain.class); public static void main(String[] args) throws Exception { DelayQueue<OrderMessage> queue = new DelayQueue<>(); // 默认延迟5秒 OrderMessage message = new OrderMessage("ORDER_ID_10086"); queue.add(message); // 延迟6秒 message = new OrderMessage("ORDER_ID_10087", 6); queue.add(message); // 延迟10秒 message = new OrderMessage("ORDER_ID_10088", 10); queue.add(message); ExecutorService executorService = Executors.newSingleThreadExecutor(r -> { Thread thread = new Thread(r); thread.setName("DelayWorker"); thread.setDaemon(true); return thread; }); LOGGER.info("开始执行调度线程..."); executorService.execute(() -> { while (true) { try { OrderMessage task = queue.take(); LOGGER.info("延迟处理订单消息,{}", task.getDescription()); } catch (Exception e) { LOGGER.error(e.getMessage(), e); } } }); Thread.sleep(Integer.MAX_VALUE); } private static class OrderMessage implements Delayed { private static final DateTimeFormatter F = DateTimeFormatter.ofPattern("yyyy-MM-dd HH:mm:ss"); /** * 默认延迟5000毫秒 */ private static final long DELAY_MS = 1000L * 5; /** * 订单ID */ private final String orderId; /** * 创建时间戳 */ private final long timestamp; /** * 过期时间 */ private final long expire; /** * 描述 */ private final String description; public OrderMessage(String orderId, long expireSeconds) { this.orderId = orderId; this.timestamp = System.currentTimeMillis(); this.expire = this.timestamp + expireSeconds * 1000L; this.description = String.format("订单[%s]-创建时间为:%s,超时时间为:%s", orderId, LocalDateTime.ofInstant(Instant.ofEpochMilli(timestamp), ZoneId.systemDefault()).format(F), LocalDateTime.ofInstant(Instant.ofEpochMilli(expire), ZoneId.systemDefault()).format(F)); } public OrderMessage(String orderId) { this.orderId = orderId; this.timestamp = System.currentTimeMillis(); this.expire = this.timestamp + DELAY_MS; this.description = String.format("订单[%s]-创建时间为:%s,超时时间为:%s", orderId, LocalDateTime.ofInstant(Instant.ofEpochMilli(timestamp), ZoneId.systemDefault()).format(F), LocalDateTime.ofInstant(Instant.ofEpochMilli(expire), ZoneId.systemDefault()).format(F)); } public String getOrderId() { return orderId; } public long getTimestamp() { return timestamp; } public long getExpire() { return expire; } public String getDescription() { return description; } @Override public long getDelay(TimeUnit unit) { return unit.convert(this.expire - System.currentTimeMillis(), TimeUnit.MILLISECONDS); } @Override public int compareTo(Delayed o) { return (int) (this.getDelay(TimeUnit.MILLISECONDS) - o.getDelay(TimeUnit.MILLISECONDS)); } } }
注意一下, OrderMessage
实现 Delayed
接口,关键是需要实现 Delayed#getDelay()
和 Delayed#compareTo()
。运行一下 main()
方法:
10:16:08.240 [main] INFO club.throwable.delay.DelayQueueMain - 开始执行调度线程... 10:16:13.224 [DelayWorker] INFO club.throwable.delay.DelayQueueMain - 延迟处理订单消息,订单[ORDER_ID_10086]-创建时间为:2019-08-20 10:16:08,超时时间为:2019-08-20 10:16:13 10:16:14.237 [DelayWorker] INFO club.throwable.delay.DelayQueueMain - 延迟处理订单消息,订单[ORDER_ID_10087]-创建时间为:2019-08-20 10:16:08,超时时间为:2019-08-20 10:16:14 10:16:18.237 [DelayWorker] INFO club.throwable.delay.DelayQueueMain - 延迟处理订单消息,订单[ORDER_ID_10088]-创建时间为:2019-08-20 10:16:08,超时时间为:2019-08-20 10:16:18
调度框架 + MySQL
使用调度框架对 MySQL
表进行短间隔轮询是实现难度比较低的方案,通常服务刚上线,表数据不多并且实时性不高的情况下应该首选这个方案。不过要注意以下几点:
MySQL
引入 Quartz
、 MySQL
的Java驱动包和 spring-boot-starter-jdbc
(这里只是为了方便用相对轻量级的框架实现,生产中可以按场景按需选择其他更合理的框架):
<dependency> <groupId>mysql</groupId> <artifactId>mysql-connector-java</artifactId> <version>5.1.48</version> <scope>test</scope> </dependency> <dependency> <groupId>org.springframework.boot</groupId> <artifactId>spring-boot-starter-jdbc</artifactId> <version>2.1.7.RELEASE</version> <scope>test</scope> </dependency> <dependency> <groupId>org.quartz-scheduler</groupId> <artifactId>quartz</artifactId> <version>2.3.1</version> <scope>test</scope> </dependency>
假设表设计如下:
CREATE DATABASE `delayTask` CHARACTER SET utf8mb4 COLLATE utf8mb4_unicode_520_ci; USE `delayTask`; CREATE TABLE `t_order_message` ( id BIGINT UNSIGNED PRIMARY KEY AUTO_INCREMENT, order_id VARCHAR(50) NOT NULL COMMENT '订单ID', create_time DATETIME NOT NULL DEFAULT CURRENT_TIMESTAMP COMMENT '创建日期时间', edit_time DATETIME NOT NULL DEFAULT CURRENT_TIMESTAMP COMMENT '修改日期时间', retry_times TINYINT NOT NULL DEFAULT 0 COMMENT '重试次数', order_status TINYINT NOT NULL DEFAULT 0 COMMENT '订单状态', INDEX idx_order_id (order_id), INDEX idx_create_time (create_time) ) COMMENT '订单信息表'; # 写入两条测试数据 INSERT INTO t_order_message(order_id) VALUES ('10086'),('10087');
编写代码:
// 常量 public class OrderConstants { public static final int MAX_RETRY_TIMES = 5; public static final int PENDING = 0; public static final int SUCCESS = 1; public static final int FAIL = -1; public static final int LIMIT = 10; } // 实体 @Builder @Data public class OrderMessage { private Long id; private String orderId; private LocalDateTime createTime; private LocalDateTime editTime; private Integer retryTimes; private Integer orderStatus; } // DAO @RequiredArgsConstructor public class OrderMessageDao { private final JdbcTemplate jdbcTemplate; private static final ResultSetExtractor<List<OrderMessage M = r -> { List<OrderMessage> list = Lists.newArrayList(); while (r.next()) { list.add(OrderMessage.builder() .id(r.getLong("id")) .orderId(r.getString("order_id")) .createTime(r.getTimestamp("create_time").toLocalDateTime()) .editTime(r.getTimestamp("edit_time").toLocalDateTime()) .retryTimes(r.getInt("retry_times")) .orderStatus(r.getInt("order_status")) .build()); } return list; }; public List<OrderMessage> selectPendingRecords(LocalDateTime start, LocalDateTime end, List<Integer> statusList, int maxRetryTimes, int limit) { StringJoiner joiner = new StringJoiner(","); statusList.forEach(s -> joiner.add(String.valueOf(s))); return jdbcTemplate.query("SELECT * FROM t_order_message WHERE create_time >= " + "AND order_status IN (", p -> { p.setTimestamp(1, Timestamp.valueOf(start)); p.setTimestamp(2, Timestamp.valueOf(end)); p.setString(3, joiner.toString()); p.setInt(4, maxRetryTimes); p.setInt(5, limit); }, M); } public int updateOrderStatus(Long id, int status) { return jdbcTemplate.update("UPDATE t_order_message SET order_status = ", p -> { p.setInt(1, status); p.setTimestamp(2, Timestamp.valueOf(LocalDateTime.now())); p.setLong(3, id); }); } } // Service @RequiredArgsConstructor public class OrderMessageService { private static final Logger LOGGER = LoggerFactory.getLogger(OrderMessageService.class); private final OrderMessageDao orderMessageDao; private static final List<Integer> STATUS = Lists.newArrayList(); static { STATUS.add(OrderConstants.PENDING); STATUS.add(OrderConstants.FAIL); } public void executeDelayJob() { LOGGER.info("订单处理定时任务开始执行......"); LocalDateTime end = LocalDateTime.now(); // 一天前 LocalDateTime start = end.minusDays(1); List<OrderMessage> list = orderMessageDao.selectPendingRecords(start, end, STATUS, OrderConstants.MAX_RETRY_TIMES, OrderConstants.LIMIT); if (!list.isEmpty()) { for (OrderMessage m : list) { LOGGER.info("处理订单[{}],状态由{}更新为{}", m.getOrderId(), m.getOrderStatus(), OrderConstants.SUCCESS); // 这里其实可以优化为批量更新 orderMessageDao.updateOrderStatus(m.getId(), OrderConstants.SUCCESS); } } LOGGER.info("订单处理定时任务开始完毕......"); } } // Job @DisallowConcurrentExecution public class OrderMessageDelayJob implements Job { @Override public void execute(JobExecutionContext jobExecutionContext) throws JobExecutionException { OrderMessageService service = (OrderMessageService) jobExecutionContext.getMergedJobDataMap().get("orderMessageService"); service.executeDelayJob(); } public static void main(String[] args) throws Exception { HikariConfig config = new HikariConfig(); config.setJdbcUrl("jdbc:mysql://localhost:3306/delayTask"); config.setDriverClassName(Driver.class.getName()); config.setUsername("root"); config.setPassword("root"); HikariDataSource dataSource = new HikariDataSource(config); OrderMessageDao orderMessageDao = new OrderMessageDao(new JdbcTemplate(dataSource)); OrderMessageService service = new OrderMessageService(orderMessageDao); // 内存模式的调度器 StdSchedulerFactory factory = new StdSchedulerFactory(); Scheduler scheduler = factory.getScheduler(); // 这里没有用到IOC容器,直接用Quartz数据集合传递服务引用 JobDataMap jobDataMap = new JobDataMap(); jobDataMap.put("orderMessageService", service); // 新建Job JobDetail job = JobBuilder.newJob(OrderMessageDelayJob.class) .withIdentity("orderMessageDelayJob", "delayJob") .usingJobData(jobDataMap) .build(); // 新建触发器,10秒执行一次 Trigger trigger = TriggerBuilder.newTrigger() .withIdentity("orderMessageDelayTrigger", "delayJob") .withSchedule(SimpleScheduleBuilder.simpleSchedule().withIntervalInSeconds(10).repeatForever()) .build(); scheduler.scheduleJob(job, trigger); // 启动调度器 scheduler.start(); Thread.sleep(Integer.MAX_VALUE); } }
这个例子里面用了 create_time
做轮询,实际上可以添加一个调度时间 schedule_time
列做轮询,这样子才能更容易定制空闲时和忙碌时候的调度策略。上面的示例的运行效果如下:
11:58:27.202 [main] INFO org.quartz.core.QuartzScheduler - Scheduler meta-data: Quartz Scheduler (v2.3.1) 'DefaultQuartzScheduler' with instanceId 'NON_CLUSTERED' Scheduler class: 'org.quartz.core.QuartzScheduler' - running locally. NOT STARTED. Currently in standby mode. Number of jobs executed: 0 Using thread pool 'org.quartz.simpl.SimpleThreadPool' - with 10 threads. Using job-store 'org.quartz.simpl.RAMJobStore' - which does not support persistence. and is not clustered. 11:58:27.202 [main] INFO org.quartz.impl.StdSchedulerFactory - Quartz scheduler 'DefaultQuartzScheduler' initialized from default resource file in Quartz package: 'quartz.properties' 11:58:27.202 [main] INFO org.quartz.impl.StdSchedulerFactory - Quartz scheduler version: 2.3.1 11:58:27.209 [main] INFO org.quartz.core.QuartzScheduler - Scheduler DefaultQuartzScheduler_$_NON_CLUSTERED started. 11:58:27.212 [DefaultQuartzScheduler_QuartzSchedulerThread] DEBUG org.quartz.core.QuartzSchedulerThread - batch acquisition of 1 triggers 11:58:27.217 [DefaultQuartzScheduler_QuartzSchedulerThread] DEBUG org.quartz.simpl.PropertySettingJobFactory - Producing instance of Job 'delayJob.orderMessageDelayJob', class=club.throwable.jdbc.OrderMessageDelayJob 11:58:27.219 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - Added connection com.mysql.jdbc.JDBC4Connection@10eb8c53 11:58:27.220 [DefaultQuartzScheduler_QuartzSchedulerThread] DEBUG org.quartz.core.QuartzSchedulerThread - batch acquisition of 0 triggers 11:58:27.221 [DefaultQuartzScheduler_Worker-1] DEBUG org.quartz.core.JobRunShell - Calling execute on job delayJob.orderMessageDelayJob 11:58:34.440 [DefaultQuartzScheduler_Worker-1] INFO club.throwable.jdbc.OrderMessageService - 订单处理定时任务开始执行...... 11:58:34.451 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - Added connection com.mysql.jdbc.JDBC4Connection@3d27ece4 11:58:34.459 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - Added connection com.mysql.jdbc.JDBC4Connection@64e808af 11:58:34.470 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - Added connection com.mysql.jdbc.JDBC4Connection@79c8c2b7 11:58:34.477 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - Added connection com.mysql.jdbc.JDBC4Connection@19a62369 11:58:34.485 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - Added connection com.mysql.jdbc.JDBC4Connection@1673d017 11:58:34.485 [HikariPool-1 connection adder] DEBUG com.zaxxer.hikari.pool.HikariPool - HikariPool-1 - After adding stats (total=10, active=0, idle=10, waiting=0) 11:58:34.559 [DefaultQuartzScheduler_Worker-1] DEBUG org.springframework.jdbc.core.JdbcTemplate - Executing prepared SQL query 11:58:34.565 [DefaultQuartzScheduler_Worker-1] DEBUG org.springframework.jdbc.core.JdbcTemplate - Executing prepared SQL statement [SELECT * FROM t_order_message WHERE create_time >= "color: #ff0000">RabbitMQ死信队列使用
RabbitMQ
死信队列依赖于RabbitMQ
的两个特性:TTL
和DLX
。
TTL
:Time To Live
,消息存活时间,包括两个维度:队列消息存活时间和消息本身的存活时间。
DLX
:Dead Letter Exchange
,死信交换器。画个图描述一下这两个特性:
下面为了简单起见,
TTL
使用了针对队列的维度。引入RabbitMQ
的Java驱动:<dependency> <groupId>com.rabbitmq</groupId> <artifactId>amqp-client</artifactId> <version>5.7.3</version> <scope>test</scope> </dependency>代码如下:
public class DlxMain { private static final DateTimeFormatter F = DateTimeFormatter.ofPattern("yyyy-MM-dd HH:mm:ss"); private static final Logger LOGGER = LoggerFactory.getLogger(DlxMain.class); public static void main(String[] args) throws Exception { ConnectionFactory factory = new ConnectionFactory(); Connection connection = factory.newConnection(); Channel producerChannel = connection.createChannel(); Channel consumerChannel = connection.createChannel(); // dlx交换器名称为dlx.exchange,类型是direct,绑定键为dlx.key,队列名为dlx.queue producerChannel.exchangeDeclare("dlx.exchange", "direct"); producerChannel.queueDeclare("dlx.queue", false, false, false, null); producerChannel.queueBind("dlx.queue", "dlx.exchange", "dlx.key"); Map<String, Object> queueArgs = new HashMap<>(); // 设置队列消息过期时间,5秒 queueArgs.put("x-message-ttl", 5000); // 指定DLX相关参数 queueArgs.put("x-dead-letter-exchange", "dlx.exchange"); queueArgs.put("x-dead-letter-routing-key", "dlx.key"); // 声明业务队列 producerChannel.queueDeclare("business.queue", false, false, false, queueArgs); ExecutorService executorService = Executors.newSingleThreadExecutor(r -> { Thread thread = new Thread(r); thread.setDaemon(true); thread.setName("DlxConsumer"); return thread; }); // 启动消费者 executorService.execute(() -> { try { consumerChannel.basicConsume("dlx.queue", true, new DlxConsumer(consumerChannel)); } catch (IOException e) { LOGGER.error(e.getMessage(), e); } }); OrderMessage message = new OrderMessage("10086"); producerChannel.basicPublish("", "business.queue", MessageProperties.TEXT_PLAIN, message.getDescription().getBytes(StandardCharsets.UTF_8)); LOGGER.info("发送消息成功,订单ID:{}", message.getOrderId()); message = new OrderMessage("10087"); producerChannel.basicPublish("", "business.queue", MessageProperties.TEXT_PLAIN, message.getDescription().getBytes(StandardCharsets.UTF_8)); LOGGER.info("发送消息成功,订单ID:{}", message.getOrderId()); message = new OrderMessage("10088"); producerChannel.basicPublish("", "business.queue", MessageProperties.TEXT_PLAIN, message.getDescription().getBytes(StandardCharsets.UTF_8)); LOGGER.info("发送消息成功,订单ID:{}", message.getOrderId()); Thread.sleep(Integer.MAX_VALUE); } private static class DlxConsumer extends DefaultConsumer { DlxConsumer(Channel channel) { super(channel); } @Override public void handleDelivery(String consumerTag, Envelope envelope, AMQP.BasicProperties properties, byte[] body) throws IOException { LOGGER.info("处理消息成功:{}", new String(body, StandardCharsets.UTF_8)); } } private static class OrderMessage { private final String orderId; private final long timestamp; private final String description; OrderMessage(String orderId) { this.orderId = orderId; this.timestamp = System.currentTimeMillis(); this.description = String.format("订单[%s],订单创建时间为:%s", orderId, LocalDateTime.ofInstant(Instant.ofEpochMilli(timestamp), ZoneId.systemDefault()).format(F)); } public String getOrderId() { return orderId; } public long getTimestamp() { return timestamp; } public String getDescription() { return description; } } }运行
main()
方法结果如下:16:35:58.638 [main] INFO club.throwable.dlx.DlxMain - 发送消息成功,订单ID:10086 16:35:58.641 [main] INFO club.throwable.dlx.DlxMain - 发送消息成功,订单ID:10087 16:35:58.641 [main] INFO club.throwable.dlx.DlxMain - 发送消息成功,订单ID:10088 16:36:03.646 [pool-1-thread-4] INFO club.throwable.dlx.DlxMain - 处理消息成功:订单[10086],订单创建时间为:2019-08-20 16:35:58 16:36:03.670 [pool-1-thread-5] INFO club.throwable.dlx.DlxMain - 处理消息成功:订单[10087],订单创建时间为:2019-08-20 16:35:58 16:36:03.670 [pool-1-thread-6] INFO club.throwable.dlx.DlxMain - 处理消息成功:订单[10088],订单创建时间为:2019-08-20 16:35:58时间轮
时间轮
TimingWheel
是一种高效、低延迟的调度数据结构,底层采用数组实现存储任务列表的环形队列,示意图如下:这里暂时不对时间轮和其实现作分析,只简单举例说明怎么使用时间轮实现延时任务。这里使用
Netty
提供的HashedWheelTimer
,引入依赖:<dependency> <groupId>io.netty</groupId> <artifactId>netty-common</artifactId> <version>4.1.39.Final</version> </dependency>代码如下:
public class HashedWheelTimerMain { private static final DateTimeFormatter F = DateTimeFormatter.ofPattern("yyyy-MM-dd HH:mm:ss.SSS"); public static void main(String[] args) throws Exception { AtomicInteger counter = new AtomicInteger(); ThreadFactory factory = r -> { Thread thread = new Thread(r); thread.setDaemon(true); thread.setName("HashedWheelTimerWorker-" + counter.getAndIncrement()); return thread; }; // tickDuration - 每tick一次的时间间隔, 每tick一次就会到达下一个槽位 // unit - tickDuration的时间单位 // ticksPerWhee - 时间轮中的槽位数 Timer timer = new HashedWheelTimer(factory, 1, TimeUnit.SECONDS, 60); TimerTask timerTask = new DefaultTimerTask("10086"); timer.newTimeout(timerTask, 5, TimeUnit.SECONDS); timerTask = new DefaultTimerTask("10087"); timer.newTimeout(timerTask, 10, TimeUnit.SECONDS); timerTask = new DefaultTimerTask("10088"); timer.newTimeout(timerTask, 15, TimeUnit.SECONDS); Thread.sleep(Integer.MAX_VALUE); } private static class DefaultTimerTask implements TimerTask { private final String orderId; private final long timestamp; public DefaultTimerTask(String orderId) { this.orderId = orderId; this.timestamp = System.currentTimeMillis(); } @Override public void run(Timeout timeout) throws Exception { System.out.println(String.format("任务执行时间:%s,订单创建时间:%s,订单ID:%s", LocalDateTime.now().format(F), LocalDateTime.ofInstant(Instant.ofEpochMilli(timestamp), ZoneId.systemDefault()).format(F), orderId)); } } }运行结果:
任务执行时间:2019-08-20 17:19:49.310,订单创建时间:2019-08-20 17:19:43.294,订单ID:10086
任务执行时间:2019-08-20 17:19:54.297,订单创建时间:2019-08-20 17:19:43.301,订单ID:10087
任务执行时间:2019-08-20 17:19:59.297,订单创建时间:2019-08-20 17:19:43.301,订单ID:10088一般来说,任务执行的时候应该使用另外的业务线程池,以免阻塞时间轮本身的运动。
选用的方案实现过程
最终选用了基于
Redis
的有序集合Sorted Set
和Quartz
短轮询进行实现。具体方案是:
- 订单创建的时候,订单ID和当前时间戳分别作为
Sorted Set
的member和score添加到订单队列Sorted Set
中。 - 订单创建的时候,订单ID和推送内容
JSON
字符串分别作为field和value添加到订单队列内容Hash
中。 - 第1步和第2步操作的时候用
Lua
脚本保证原子性。 - 使用一个异步线程通过
Sorted Set
的命令ZREVRANGEBYSCORE
弹出指定数量的订单ID对应的订单队列内容Hash
中的订单推送内容数据进行处理。
对于第4点处理有两种方案:
- 方案一:弹出订单内容数据的同时进行数据删除,也就是
ZREVRANGEBYSCORE
、ZREM
和HDEL
命令要在同一个Lua
脚本中执行,这样的话Lua
脚本的编写难度大,并且由于弹出数据已经在Redis
中删除,如果数据处理失败则可能需要从数据库重新查询补偿。 - 方案二:弹出订单内容数据之后,在数据处理完成的时候再主动删除订单队列
Sorted Set
和订单队列内容Hash
中对应的数据,这样的话需要控制并发,有重复执行的可能性。
最终暂时选用了方案一,也就是从 Sorted Set
弹出订单ID并且从 Hash
中获取完推送数据之后马上删除这两个集合中对应的数据。方案的流程图大概是这样:
这里先详细说明一下用到的 Redis
命令。
Sorted Set相关命令
ZADD
命令 - 将一个或多个成员元素及其分数值加入到有序集当中。
ZADD KEY SCORE1 VALUE1.. SCOREN VALUEN
ZREVRANGEBYSCORE
命令 - 返回有序集中指定分数区间内的所有的成员。有序集成员按分数值递减(从大到小)的次序排列。
ZREVRANGEBYSCORE key max min [WITHSCORES] [LIMIT offset count]
max:分数区间 - 最大分数。 min:分数区间 - 最小分数。 WITHSCORES:可选参数,是否返回分数值,指定则会返回得分值。 LIMIT:可选参数,offset和count原理和 MySQL
的 LIMIT offset,size
一致,如果不指定此参数则返回整个集合的数据。 ZREM
命令 - 用于移除有序集中的一个或多个成员,不存在的成员将被忽略。
ZREM key member [member ...]
Hash相关命令 HMSET
命令 - 同时将多个field-value(字段-值)对设置到哈希表中。
HMSET KEY_NAME FIELD1 VALUE1 ...FIELDN VALUEN
HDEL
命令 - 删除哈希表key中的一个或多个指定字段,不存在的字段将被忽略。
HDEL KEY_NAME FIELD1.. FIELDN
Lua相关 加载 Lua
脚本并且返回脚本的 SHA-1
字符串: SCRIPT LOAD script
。 执行已经加载的 Lua
脚本: EVALSHA sha1 numkeys key [key ...] arg [arg ...]
。 unpack
函数可以把 table
类型的参数转化为可变参数,不过需要注意的是 unpack
函数必须使用在非变量定义的函数调用的最后一个参数,否则会失效,详细见 Stackoverflow
的提问 table.unpack() only returns the first element 。
PS:如果不熟悉Lua语言,建议系统学习一下,因为想用好Redis,一定离不开Lua。
引入依赖:
<dependencyManagement> <dependencies> <dependency> <groupId>org.springframework.boot</groupId> <artifactId>spring-boot-dependencies</artifactId> <version>2.1.7.RELEASE</version> <type>pom</type> <scope>import</scope> </dependency> </dependencies> </dependencyManagement> <dependencies> <dependency> <groupId>org.quartz-scheduler</groupId> <artifactId>quartz</artifactId> <version>2.3.1</version> </dependency> <dependency> <groupId>redis.clients</groupId> <artifactId>jedis</artifactId> <version>3.1.0</version> </dependency> <dependency> <groupId>org.springframework.boot</groupId> <artifactId>spring-boot-starter-web</artifactId> </dependency> <dependency> <groupId>org.springframework.boot</groupId> <artifactId>spring-boot-starter-jdbc</artifactId> </dependency> <dependency> <groupId>org.springframework</groupId> <artifactId>spring-context-support</artifactId> <version>5.1.9.RELEASE</version> </dependency> <dependency> <groupId>org.projectlombok</groupId> <artifactId>lombok</artifactId> <version>1.18.8</version> <scope>provided</scope> </dependency> <dependency> <groupId>com.alibaba</groupId> <artifactId>fastjson</artifactId> <version>1.2.59</version> </dependency> </dependencies>
编写 Lua
脚本 /lua/enqueue.lua
和 /lua/dequeue.lua
:
-- /lua/enqueue.lua local zset_key = KEYS[1] local hash_key = KEYS[2] local zset_value = ARGV[1] local zset_score = ARGV[2] local hash_field = ARGV[3] local hash_value = ARGV[4] redis.call('ZADD', zset_key, zset_score, zset_value) redis.call('HSET', hash_key, hash_field, hash_value) return nil -- /lua/dequeue.lua -- 参考jesque的部分Lua脚本实现 local zset_key = KEYS[1] local hash_key = KEYS[2] local min_score = ARGV[1] local max_score = ARGV[2] local offset = ARGV[3] local limit = ARGV[4] -- TYPE命令的返回结果是{'ok':'zset'}这样子,这里利用next做一轮迭代 local status, type = next(redis.call('TYPE', zset_key)) if status ~= nil and status == 'ok' then if type == 'zset' then local list = redis.call('ZREVRANGEBYSCORE', zset_key, max_score, min_score, 'LIMIT', offset, limit) if list ~= nil and #list > 0 then -- unpack函数能把table转化为可变参数 redis.call('ZREM', zset_key, unpack(list)) local result = redis.call('HMGET', hash_key, unpack(list)) redis.call('HDEL', hash_key, unpack(list)) return result end end end return nil
编写核心API代码:
// Jedis提供者 @Component public class JedisProvider implements InitializingBean { private JedisPool jedisPool; @Override public void afterPropertiesSet() throws Exception { jedisPool = new JedisPool(); } public Jedis provide(){ return jedisPool.getResource(); } } // OrderMessage @Data public class OrderMessage { private String orderId; private BigDecimal amount; private Long userId; } // 延迟队列接口 public interface OrderDelayQueue { void enqueue(OrderMessage message); List<OrderMessage> dequeue(String min, String max, String offset, String limit); List<OrderMessage> dequeue(); String enqueueSha(); String dequeueSha(); } // 延迟队列实现类 @RequiredArgsConstructor @Component public class RedisOrderDelayQueue implements OrderDelayQueue, InitializingBean { private static final String MIN_SCORE = "0"; private static final String OFFSET = "0"; private static final String LIMIT = "10"; private static final String ORDER_QUEUE = "ORDER_QUEUE"; private static final String ORDER_DETAIL_QUEUE = "ORDER_DETAIL_QUEUE"; private static final String ENQUEUE_LUA_SCRIPT_LOCATION = "/lua/enqueue.lua"; private static final String DEQUEUE_LUA_SCRIPT_LOCATION = "/lua/dequeue.lua"; private static final AtomicReference<String> ENQUEUE_LUA_SHA = new AtomicReference<>(); private static final AtomicReference<String> DEQUEUE_LUA_SHA = new AtomicReference<>(); private static final List<String> KEYS = Lists.newArrayList(); private final JedisProvider jedisProvider; static { KEYS.add(ORDER_QUEUE); KEYS.add(ORDER_DETAIL_QUEUE); } @Override public void enqueue(OrderMessage message) { List<String> args = Lists.newArrayList(); args.add(message.getOrderId()); args.add(String.valueOf(System.currentTimeMillis())); args.add(message.getOrderId()); args.add(JSON.toJSONString(message)); try (Jedis jedis = jedisProvider.provide()) { jedis.evalsha(ENQUEUE_LUA_SHA.get(), KEYS, args); } } @Override public List<OrderMessage> dequeue() { // 30分钟之前 String maxScore = String.valueOf(System.currentTimeMillis() - 30 * 60 * 1000); return dequeue(MIN_SCORE, maxScore, OFFSET, LIMIT); } @SuppressWarnings("unchecked") @Override public List<OrderMessage> dequeue(String min, String max, String offset, String limit) { List<String> args = new ArrayList<>(); args.add(max); args.add(min); args.add(offset); args.add(limit); List<OrderMessage> result = Lists.newArrayList(); try (Jedis jedis = jedisProvider.provide()) { List<String> eval = (List<String>) jedis.evalsha(DEQUEUE_LUA_SHA.get(), KEYS, args); if (null != eval) { for (String e : eval) { result.add(JSON.parseObject(e, OrderMessage.class)); } } } return result; } @Override public String enqueueSha() { return ENQUEUE_LUA_SHA.get(); } @Override public String dequeueSha() { return DEQUEUE_LUA_SHA.get(); } @Override public void afterPropertiesSet() throws Exception { // 加载Lua脚本 loadLuaScript(); } private void loadLuaScript() throws Exception { try (Jedis jedis = jedisProvider.provide()) { ClassPathResource resource = new ClassPathResource(ENQUEUE_LUA_SCRIPT_LOCATION); String luaContent = StreamUtils.copyToString(resource.getInputStream(), StandardCharsets.UTF_8); String sha = jedis.scriptLoad(luaContent); ENQUEUE_LUA_SHA.compareAndSet(null, sha); resource = new ClassPathResource(DEQUEUE_LUA_SCRIPT_LOCATION); luaContent = StreamUtils.copyToString(resource.getInputStream(), StandardCharsets.UTF_8); sha = jedis.scriptLoad(luaContent); DEQUEUE_LUA_SHA.compareAndSet(null, sha); } } public static void main(String[] as) throws Exception { DateTimeFormatter f = DateTimeFormatter.ofPattern("yyyy-MM-dd HH:mm:ss.SSS"); JedisProvider jedisProvider = new JedisProvider(); jedisProvider.afterPropertiesSet(); RedisOrderDelayQueue queue = new RedisOrderDelayQueue(jedisProvider); queue.afterPropertiesSet(); // 写入测试数据 OrderMessage message = new OrderMessage(); message.setAmount(BigDecimal.valueOf(10086)); message.setOrderId("ORDER_ID_10086"); message.setUserId(10086L); message.setTimestamp(LocalDateTime.now().format(f)); List<String> args = Lists.newArrayList(); args.add(message.getOrderId()); // 测试需要,score设置为30分钟之前 args.add(String.valueOf(System.currentTimeMillis() - 30 * 60 * 1000)); args.add(message.getOrderId()); args.add(JSON.toJSONString(message)); try (Jedis jedis = jedisProvider.provide()) { jedis.evalsha(ENQUEUE_LUA_SHA.get(), KEYS, args); } List<OrderMessage> dequeue = queue.dequeue(); System.out.println(dequeue); } }
这里先执行一次 main()
方法验证一下延迟队列是否生效:
[OrderMessage(orderId=ORDER_ID_10086, amount=10086, userId=10086, timestamp=2019-08-21 08:32:22.885)]
确定延迟队列的代码没有问题,接着编写一个 Quartz
的 Job
类型的消费者 OrderMessageConsumer
:
@DisallowConcurrentExecution @Component public class OrderMessageConsumer implements Job { private static final AtomicInteger COUNTER = new AtomicInteger(); private static final ExecutorService BUSINESS_WORKER_POOL = Executors.newFixedThreadPool(Runtime.getRuntime().availableProcessors(), r -> { Thread thread = new Thread(r); thread.setDaemon(true); thread.setName("OrderMessageConsumerWorker-" + COUNTER.getAndIncrement()); return thread; }); private static final Logger LOGGER = LoggerFactory.getLogger(OrderMessageConsumer.class); @Autowired private OrderDelayQueue orderDelayQueue; @Override public void execute(JobExecutionContext jobExecutionContext) throws JobExecutionException { StopWatch stopWatch = new StopWatch(); stopWatch.start(); LOGGER.info("订单消息处理定时任务开始执行......"); List<OrderMessage> messages = orderDelayQueue.dequeue(); if (!messages.isEmpty()) { // 简单的列表等分放到线程池中执行 List<List<OrderMessage partition = Lists.partition(messages, 2); int size = partition.size(); final CountDownLatch latch = new CountDownLatch(size); for (List<OrderMessage> p : partition) { BUSINESS_WORKER_POOL.execute(new ConsumeTask(p, latch)); } try { latch.await(); } catch (InterruptedException ignore) { //ignore } } stopWatch.stop(); LOGGER.info("订单消息处理定时任务执行完毕,耗时:{} ms......", stopWatch.getTotalTimeMillis()); } @RequiredArgsConstructor private static class ConsumeTask implements Runnable { private final List<OrderMessage> messages; private final CountDownLatch latch; @Override public void run() { try { // 实际上这里应该单条捕获异常 for (OrderMessage message : messages) { LOGGER.info("处理订单信息,内容:{}", message); } } finally { latch.countDown(); } } } }
上面的消费者设计的时候需要有以下考量:
- 使用
@DisallowConcurrentExecution
注解不允许Job
并发执行,其实多个Job
并发执行意义不大,因为我们采用的是短间隔的轮询,而Redis
是单线程处理命令,在客户端做多线程其实效果不佳。 - 线程池
BUSINESS_WORKER_POOL
的线程容量或者队列应该综合LIMIT
值、等分订单信息列表中使用的size
值以及ConsumeTask
里面具体的执行时间进行考虑,这里只是为了方便使用了固定容量的线程池。 ConsumeTask
中应该对每一条订单信息的处理单独捕获异常和吞并异常,或者把处理单个订单信息的逻辑封装成一个不抛出异常的方法。
其他 Quartz
相关的代码:
// Quartz配置类 @Configuration public class QuartzAutoConfiguration { @Bean public SchedulerFactoryBean schedulerFactoryBean(QuartzAutowiredJobFactory quartzAutowiredJobFactory) { SchedulerFactoryBean factory = new SchedulerFactoryBean(); factory.setAutoStartup(true); factory.setJobFactory(quartzAutowiredJobFactory); return factory; } @Bean public QuartzAutowiredJobFactory quartzAutowiredJobFactory() { return new QuartzAutowiredJobFactory(); } public static class QuartzAutowiredJobFactory extends AdaptableJobFactory implements BeanFactoryAware { private AutowireCapableBeanFactory autowireCapableBeanFactory; @Override public void setBeanFactory(BeanFactory beanFactory) throws BeansException { this.autowireCapableBeanFactory = (AutowireCapableBeanFactory) beanFactory; } @Override protected Object createJobInstance(TriggerFiredBundle bundle) throws Exception { Object jobInstance = super.createJobInstance(bundle); // 这里利用AutowireCapableBeanFactory从新建的Job实例做一次自动装配,得到一个原型(prototype)的JobBean实例 autowireCapableBeanFactory.autowireBean(jobInstance); return jobInstance; } } }
这里暂时使用了内存态的 RAMJobStore
去存放任务和触发器的相关信息,如果在生产环境最好替换成基于 MySQL
也就是 JobStoreTX
进行集群化,最后是启动函数和 CommandLineRunner
的实现:
@SpringBootApplication(exclude = {DataSourceAutoConfiguration.class, TransactionAutoConfiguration.class}) public class Application implements CommandLineRunner { @Autowired private Scheduler scheduler; @Autowired private JedisProvider jedisProvider; public static void main(String[] args) { SpringApplication.run(Application.class, args); } @Override public void run(String... args) throws Exception { // 准备一些测试数据 prepareOrderMessageData(); JobDetail job = JobBuilder.newJob(OrderMessageConsumer.class) .withIdentity("OrderMessageConsumer", "DelayTask") .build(); // 触发器5秒触发一次 Trigger trigger = TriggerBuilder.newTrigger() .withIdentity("OrderMessageConsumerTrigger", "DelayTask") .withSchedule(SimpleScheduleBuilder.simpleSchedule().withIntervalInSeconds(5).repeatForever()) .build(); scheduler.scheduleJob(job, trigger); } private void prepareOrderMessageData() throws Exception { DateTimeFormatter f = DateTimeFormatter.ofPattern("yyyy-MM-dd HH:mm:ss.SSS"); try (Jedis jedis = jedisProvider.provide()) { List<OrderMessage> messages = Lists.newArrayList(); for (int i = 0; i < 100; i++) { OrderMessage message = new OrderMessage(); message.setAmount(BigDecimal.valueOf(i)); message.setOrderId("ORDER_ID_" + i); message.setUserId((long) i); message.setTimestamp(LocalDateTime.now().format(f)); messages.add(message); } // 这里暂时不使用Lua Map<String, Double> map = Maps.newHashMap(); Map<String, String> hash = Maps.newHashMap(); for (OrderMessage message : messages) { // 故意把score设计成30分钟前 map.put(message.getOrderId(), Double.valueOf(String.valueOf(System.currentTimeMillis() - 30 * 60 * 1000))); hash.put(message.getOrderId(), JSON.toJSONString(message)); } jedis.zadd("ORDER_QUEUE", map); jedis.hmset("ORDER_DETAIL_QUEUE", hash); } } }
输出结果如下:
2019-08-21 22:45:59.518 INFO 33000 --- [ryBean_Worker-1] club.throwable.OrderMessageConsumer : 订单消息处理定时任务开始执行......
2019-08-21 22:45:59.525 INFO 33000 --- [onsumerWorker-4] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_91, amount=91, userId=91, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.525 INFO 33000 --- [onsumerWorker-2] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_95, amount=95, userId=95, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.525 INFO 33000 --- [onsumerWorker-1] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_97, amount=97, userId=97, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.525 INFO 33000 --- [onsumerWorker-0] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_99, amount=99, userId=99, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.525 INFO 33000 --- [onsumerWorker-3] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_93, amount=93, userId=93, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.539 INFO 33000 --- [onsumerWorker-2] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_94, amount=94, userId=94, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.539 INFO 33000 --- [onsumerWorker-1] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_96, amount=96, userId=96, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.539 INFO 33000 --- [onsumerWorker-3] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_92, amount=92, userId=92, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.539 INFO 33000 --- [onsumerWorker-0] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_98, amount=98, userId=98, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.539 INFO 33000 --- [onsumerWorker-4] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_90, amount=90, userId=90, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:45:59.540 INFO 33000 --- [ryBean_Worker-1] club.throwable.OrderMessageConsumer : 订单消息处理定时任务执行完毕,耗时:22 ms......
2019-08-21 22:46:04.515 INFO 33000 --- [ryBean_Worker-2] club.throwable.OrderMessageConsumer : 订单消息处理定时任务开始执行......
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-5] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_89, amount=89, userId=89, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-6] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_87, amount=87, userId=87, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-7] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_85, amount=85, userId=85, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-5] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_88, amount=88, userId=88, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-2] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_83, amount=83, userId=83, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-1] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_81, amount=81, userId=81, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-6] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_86, amount=86, userId=86, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-2] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_82, amount=82, userId=82, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-7] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_84, amount=84, userId=84, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [onsumerWorker-1] club.throwable.OrderMessageConsumer : 处理订单信息,内容:OrderMessage(orderId=ORDER_ID_80, amount=80, userId=80, timestamp=2019-08-21 22:45:59.475)
2019-08-21 22:46:04.516 INFO 33000 --- [ryBean_Worker-2] club.throwable.OrderMessageConsumer : 订单消息处理定时任务执行完毕,耗时:1 ms......
......
首次执行的时候涉及到一些组件的初始化,会比较慢,后面看到由于我们只是简单打印订单信息,所以定时任务执行比较快。如果在不调整当前架构的情况下,生产中需要注意:
- 切换
JobStore
为JDBC
模式,Quartz
官方有完整教程,或者看笔者之前翻译的Quartz
文档。 - 需要监控或者收集任务的执行状态,添加预警等等。
这里其实有一个性能隐患,命令 ZREVRANGEBYSCORE
的时间复杂度可以视为为 O(N)
, N
是集合的元素个数,由于这里把所有的订单信息都放进了同一个 Sorted Set
( ORDER_QUEUE
)中,所以在一直有新增数据的时候, dequeue
脚本的时间复杂度一直比较高,后续订单量升高之后会此处一定会成为性能瓶颈,后面会给出解决的方案。
小结
这篇文章主要从一个实际生产案例的仿真例子入手,分析了当前延时任务的一些实现方案,还基于 Redis
和 Quartz
给出了一个完整的示例。当前的示例只是处于可运行的状态,有些问题尚未解决。下一篇文章会着眼于解决两个方面的问题:
- 分片。
- 监控。
还有一点, 架构是基于业务形态演进出来的,很多东西需要结合场景进行方案设计和改进,思路仅供参考,切勿照搬代码 。
以上所述是小编给大家介绍的使用Redis实现延时任务的解决方案,非常不错,具有一定的参考借鉴价值,需要的朋友参考下吧!
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