2.8.2
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1. Preface
The Spring for Apache Kafka project applies core Spring concepts to the development of Kafka-based messaging solutions. We provide a “template” as a high-level abstraction for sending messages. We also provide support for Message-driven POJOs.
2. What’s new?
2.1. What’s New in 2.8 Since 2.7
This section covers the changes made from version 2.7 to version 2.8. For changes in earlier version, see Change History.
2.1.1. Kafka Client Version
This version requires the 3.0.0 kafka-clients
When using transactions, kafka-clients 3.0.0 and later no longer support EOSMode.V2 (aka BETA ) (and automatic fallback to V1 - aka ALPHA ) with brokers earlier than 2.5; you must therefore override the default EOSMode (V2 ) with V1 if your brokers are older (or upgrade your brokers).
|
See Exactly Once Semantics and KIP-447 for more information.
2.1.2. Package Changes
Classes and interfaces related to type mapping have been moved from …support.converter
to …support.mapping
.
-
AbstractJavaTypeMapper
-
ClassMapper
-
DefaultJackson2JavaTypeMapper
-
Jackson2JavaTypeMapper
2.1.3. Out of Order Manual Commits
The listener container can now be configured to accept manual offset commits out of order (usually asynchronously). The container will defer the commit until the missing offset is acknowledged. See Manually Committing Offsets for more information.
2.1.4. @KafkaListener
Changes
It is now possible to specify whether the listener method is a batch listener on the method itself. This allows the same container factory to be used for both record and batch listeners.
See Batch Listeners for more information.
Batch listeners can now handle conversion exceptions.
See Conversion Errors with Batch Error Handlers for more information.
RecordFilterStrategy
, when used with batch listeners, can now filter the entire batch in one call.
See the note at the end of Batch Listeners for more information.
2.1.5. KafkaTemplate
Changes
You can now receive a single record, given the topic, partition and offset.
See Using KafkaTemplate
to Receive for more information.
2.1.6. CommonErrorHandler
Added
The legacy GenericErrorHandler
and its sub-interface hierarchies for record an batch listeners have been replaced by a new single interface CommonErrorHandler
with implementations corresponding to most legacy implementations of GenericErrorHandler
.
See Container Error Handlers for more information.
2.1.7. Listener Container Changes
The interceptBeforeTx
container property is now true
by default.
The authorizationExceptionRetryInterval
property has been renamed to authExceptionRetryInterval
and now applies to AuthenticationException
s in addition to AuthorizationException
s previously.
Both exceptions are considered fatal and the container will stop by default, unless this property is set.
See Using KafkaMessageListenerContainer
and Listener Container Properties for more information.
2.1.8. Serializer/Deserializer Changes
The DelegatingByTopicSerializer
and DelegatingByTopicDeserializer
are now provided.
See Delegating Serializer and Deserializer for more information.
2.1.9. DeadLetterPublishingRecover
Changes
The property stripPreviousExceptionHeaders
is now true
by default.
See Managing Dead Letter Record Headers for more information.
2.1.10. KafkaBackOffException Log Level Changes
The KafkaBackOffException thrown when using the retryable topics feature is now logged at DEBUG level.
See Changing KafkaBackOffException Logging Level if you need to change the logging level back to WARN or set it to any other level.
3. Introduction
This first part of the reference documentation is a high-level overview of Spring for Apache Kafka and the underlying concepts and some code snippets that can help you get up and running as quickly as possible.
3.1. Quick Tour
Prerequisites: You must install and run Apache Kafka.
Then you must put the Spring for Apache Kafka (spring-kafka
) JAR and all of its dependencies on your class path.
The easiest way to do that is to declare a dependency in your build tool.
If you are not using Spring Boot, declare the spring-kafka
jar as a dependency in your project.
<dependency>
<groupId>org.springframework.kafka</groupId>
<artifactId>spring-kafka</artifactId>
<version>2.8.2</version>
</dependency>
compile 'org.springframework.kafka:spring-kafka:2.8.2'
When using Spring Boot, (and you haven’t used start.spring.io to create your project), omit the version and Boot will automatically bring in the correct version that is compatible with your Boot version: |
<dependency>
<groupId>org.springframework.kafka</groupId>
<artifactId>spring-kafka</artifactId>
</dependency>
compile 'org.springframework.kafka:spring-kafka'
However, the quickest way to get started is to use start.spring.io (or the wizards in Spring Tool Suits and Intellij IDEA) and create a project, selecting 'Spring for Apache Kafka' as a dependency.
3.1.1. Compatibility
This quick tour works with the following versions:
-
Apache Kafka Clients 3.0.0
-
Spring Framework 5.3.x
-
Minimum Java version: 8
3.1.2. Getting Started
The simplest way to get started is to use start.spring.io (or the wizards in Spring Tool Suits and Intellij IDEA) and create a project, selecting 'Spring for Apache Kafka' as a dependency. Refer to the Spring Boot documentation for more information about its opinionated auto configuration of the infrastructure beans.
Here is a minimal consumer application.
Spring Boot Consumer App
@SpringBootApplication
public class Application {
public static void main(String[] args) {
SpringApplication.run(Application.class, args);
}
@Bean
public NewTopic topic() {
return TopicBuilder.name("topic1")
.partitions(10)
.replicas(1)
.build();
}
@KafkaListener(id = "myId", topics = "topic1")
public void listen(String in) {
System.out.println(in);
}
}
@SpringBootApplication
class Application {
@Bean
fun topic() = NewTopic("topic1", 10, 1)
@KafkaListener(id = "myId", topics = ["topic1"])
fun listen(value: String?) {
println(value)
}
}
fun main(args: Array<String>) = runApplication<Application>(*args)
spring.kafka.consumer.auto-offset-reset=earliest
The NewTopic
bean causes the topic to be created on the broker; it is not needed if the topic already exists.
Spring Boot Producer App
@SpringBootApplication
public class Application {
public static void main(String[] args) {
SpringApplication.run(Application.class, args);
}
@Bean
public NewTopic topic() {
return TopicBuilder.name("topic1")
.partitions(10)
.replicas(1)
.build();
}
@Bean
public ApplicationRunner runner(KafkaTemplate<String, String> template) {
return args -> {
template.send("topic1", "test");
};
}
}
@SpringBootApplication
class Application {
@Bean
fun topic() = NewTopic("topic1", 10, 1)
@Bean
fun runner(template: KafkaTemplate<String?, String?>) =
ApplicationRunner { template.send("topic1", "test") }
companion object {
@JvmStatic
fun main(args: Array<String>) = runApplication<Application>(*args)
}
}
With Java Configuration (No Spring Boot)
Spring for Apache Kafka is designed to be used in a Spring Application Context.
For example, if you create the listener container yourself outside of a Spring context, not all functions will work unless you satisfy all of the …Aware interfaces that the container implements.
|
Here is an example of an application that does not use Spring Boot; it has both a Consumer
and Producer
.
public class Sender {
public static void main(String[] args) {
AnnotationConfigApplicationContext context = new AnnotationConfigApplicationContext(Config.class);
context.getBean(Sender.class).send("test", 42);
}
private final KafkaTemplate<Integer, String> template;
public Sender(KafkaTemplate<Integer, String> template) {
this.template = template;
}
public void send(String toSend, int key) {
this.template.send("topic1", key, toSend);
}
}
public class Listener {
@KafkaListener(id = "listen1", topics = "topic1")
public void listen1(String in) {
System.out.println(in);
}
}
@Configuration
@EnableKafka
public class Config {
@Bean
ConcurrentKafkaListenerContainerFactory<Integer, String>
kafkaListenerContainerFactory(ConsumerFactory<Integer, String> consumerFactory) {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(consumerFactory);
return factory;
}
@Bean
public ConsumerFactory<Integer, String> consumerFactory() {
return new DefaultKafkaConsumerFactory<>(consumerProps());
}
private Map<String, Object> consumerProps() {
Map<String, Object> props = new HashMap<>();
props.put(ConsumerConfig.BOOTSTRAP_SERVERS_CONFIG, "localhost:9092");
props.put(ConsumerConfig.GROUP_ID_CONFIG, "group");
props.put(ConsumerConfig.KEY_DESERIALIZER_CLASS_CONFIG, IntegerDeserializer.class);
props.put(ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG, StringDeserializer.class);
props.put(ConsumerConfig.AUTO_OFFSET_RESET_CONFIG, "earliest");
// ...
return props;
}
@Bean
public Sender sender(KafkaTemplate<Integer, String> template) {
return new Sender(template);
}
@Bean
public Listener listener() {
return new Listener();
}
@Bean
public ProducerFactory<Integer, String> producerFactory() {
return new DefaultKafkaProducerFactory<>(senderProps());
}
private Map<String, Object> senderProps() {
Map<String, Object> props = new HashMap<>();
props.put(ProducerConfig.BOOTSTRAP_SERVERS_CONFIG, "localhost:9092");
props.put(ProducerConfig.LINGER_MS_CONFIG, 10);
props.put(ProducerConfig.KEY_SERIALIZER_CLASS_CONFIG, IntegerSerializer.class);
props.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, StringSerializer.class);
//...
return props;
}
@Bean
public KafkaTemplate<Integer, String> kafkaTemplate(ProducerFactory<Integer, String> producerFactory) {
return new KafkaTemplate<Integer, String>(producerFactory);
}
}
class Sender(private val template: KafkaTemplate<Int, String>) {
fun send(toSend: String, key: Int) {
template.send("topic1", key, toSend)
}
}
class Listener {
@KafkaListener(id = "listen1", topics = ["topic1"])
fun listen1(`in`: String) {
println(`in`)
}
}
@Configuration
@EnableKafka
class Config {
@Bean
fun kafkaListenerContainerFactory(consumerFactory: ConsumerFactory<Int, String>) =
ConcurrentKafkaListenerContainerFactory<Int, String>().also { it.consumerFactory = consumerFactory }
@Bean
fun consumerFactory() = DefaultKafkaConsumerFactory<Int, String>(consumerProps)
val consumerProps = mapOf(
ConsumerConfig.BOOTSTRAP_SERVERS_CONFIG to "localhost:9092",
ConsumerConfig.GROUP_ID_CONFIG to "group",
ConsumerConfig.KEY_DESERIALIZER_CLASS_CONFIG to IntegerDeserializer::class.java,
ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG to StringDeserializer::class.java,
ConsumerConfig.AUTO_OFFSET_RESET_CONFIG to "earliest"
)
@Bean
fun sender(template: KafkaTemplate<Int, String>) = Sender(template)
@Bean
fun listener() = Listener()
@Bean
fun producerFactory() = DefaultKafkaProducerFactory<Int, String>(senderProps)
val senderProps = mapOf(
ProducerConfig.BOOTSTRAP_SERVERS_CONFIG to "localhost:9092",
ProducerConfig.LINGER_MS_CONFIG to 10,
ProducerConfig.KEY_SERIALIZER_CLASS_CONFIG to IntegerSerializer::class.java,
ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG to StringSerializer::class.java
)
@Bean
fun kafkaTemplate(producerFactory: ProducerFactory<Int, String>) = KafkaTemplate(producerFactory)
}
As you can see, you have to define several infrastructure beans when not using Spring Boot.
4. Reference
This part of the reference documentation details the various components that comprise Spring for Apache Kafka. The main chapter covers the core classes to develop a Kafka application with Spring.
4.1. Using Spring for Apache Kafka
This section offers detailed explanations of the various concerns that impact using Spring for Apache Kafka. For a quick but less detailed introduction, see Quick Tour.
4.1.1. Connecting to Kafka
-
KafkaAdmin
- see Configuring Topics -
ProducerFactory
- see Sending Messages -
ConsumerFactory
- see Receiving Messages
Starting with version 2.5, each of these extends KafkaResourceFactory
.
This allows changing the bootstrap servers at runtime by adding a Supplier<String>
to their configuration: setBootstrapServersSupplier(() → …)
.
This will be called for all new connections to get the list of servers.
Consumers and Producers are generally long-lived.
To close existing Producers, call reset()
on the DefaultKafkaProducerFactory
.
To close existing Consumers, call stop()
(and then start()
) on the KafkaListenerEndpointRegistry
and/or stop()
and start()
on any other listener container beans.
For convenience, the framework also provides an ABSwitchCluster
which supports two sets of bootstrap servers; one of which is active at any time.
Configure the ABSwitchCluster
and add it to the producer and consumer factories, and the KafkaAdmin
, by calling setBootstrapServersSupplier()
.
When you want to switch, call primary()
or secondary()
and call reset()
on the producer factory to establish new connection(s); for consumers, stop()
and start()
all listener containers.
When using @KafkaListener
s, stop()
and start()
the KafkaListenerEndpointRegistry
bean.
See the Javadocs for more information.
Factory Listeners
Starting with version 2.5, the DefaultKafkaProducerFactory
and DefaultKafkaConsumerFactory
can be configured with a Listener
to receive notifications whenever a producer or consumer is created or closed.
interface Listener<K, V> {
default void producerAdded(String id, Producer<K, V> producer) {
}
default void producerRemoved(String id, Producer<K, V> producer) {
}
}
interface Listener<K, V> {
default void consumerAdded(String id, Consumer<K, V> consumer) {
}
default void consumerRemoved(String id, Consumer<K, V> consumer) {
}
}
In each case, the id
is created by appending the client-id
property (obtained from the metrics()
after creation) to the factory beanName
property, separated by .
.
These listeners can be used, for example, to create and bind a Micrometer KafkaClientMetrics
instance when a new client is created (and close it when the client is closed).
The framework provides listeners that do exactly that; see Micrometer Native Metrics.
4.1.2. Configuring Topics
If you define a KafkaAdmin
bean in your application context, it can automatically add topics to the broker.
To do so, you can add a NewTopic
@Bean
for each topic to the application context.
Version 2.3 introduced a new class TopicBuilder
to make creation of such beans more convenient.
The following example shows how to do so:
@Bean
public KafkaAdmin admin() {
Map<String, Object> configs = new HashMap<>();
configs.put(AdminClientConfig.BOOTSTRAP_SERVERS_CONFIG, "localhost:9092");
return new KafkaAdmin(configs);
}
@Bean
public NewTopic topic1() {
return TopicBuilder.name("thing1")
.partitions(10)
.replicas(3)
.compact()
.build();
}
@Bean
public NewTopic topic2() {
return TopicBuilder.name("thing2")
.partitions(10)
.replicas(3)
.config(TopicConfig.COMPRESSION_TYPE_CONFIG, "zstd")
.build();
}
@Bean
public NewTopic topic3() {
return TopicBuilder.name("thing3")
.assignReplicas(0, Arrays.asList(0, 1))
.assignReplicas(1, Arrays.asList(1, 2))
.assignReplicas(2, Arrays.asList(2, 0))
.config(TopicConfig.COMPRESSION_TYPE_CONFIG, "zstd")
.build();
}
@Bean
fun admin() = KafkaAdmin(mapOf(AdminClientConfig.BOOTSTRAP_SERVERS_CONFIG to "localhost:9092"))
@Bean
fun topic1() =
TopicBuilder.name("thing1")
.partitions(10)
.replicas(3)
.compact()
.build()
@Bean
fun topic2() =
TopicBuilder.name("thing2")
.partitions(10)
.replicas(3)
.config(TopicConfig.COMPRESSION_TYPE_CONFIG, "zstd")
.build()
@Bean
fun topic3() =
TopicBuilder.name("thing3")
.assignReplicas(0, Arrays.asList(0, 1))
.assignReplicas(1, Arrays.asList(1, 2))
.assignReplicas(2, Arrays.asList(2, 0))
.config(TopicConfig.COMPRESSION_TYPE_CONFIG, "zstd")
.build()
Starting with version 2.6, you can omit .partitions()
and/or replicas()
and the broker defaults will be applied to those properties.
The broker version must be at least 2.4.0 to support this feature - see KIP-464.
@Bean
public NewTopic topic4() {
return TopicBuilder.name("defaultBoth")
.build();
}
@Bean
public NewTopic topic5() {
return TopicBuilder.name("defaultPart")
.replicas(1)
.build();
}
@Bean
public NewTopic topic6() {
return TopicBuilder.name("defaultRepl")
.partitions(3)
.build();
}
@Bean
fun topic4() = TopicBuilder.name("defaultBoth").build()
@Bean
fun topic5() = TopicBuilder.name("defaultPart").replicas(1).build()
@Bean
fun topic6() = TopicBuilder.name("defaultRepl").partitions(3).build()
Starting with version 2.7, you can declare multiple NewTopic
s in a single KafkaAdmin.NewTopics
bean definition:
@Bean
public KafkaAdmin.NewTopics topics456() {
return new NewTopics(
TopicBuilder.name("defaultBoth")
.build(),
TopicBuilder.name("defaultPart")
.replicas(1)
.build(),
TopicBuilder.name("defaultRepl")
.partitions(3)
.build());
}
@Bean
fun topics456() = KafkaAdmin.NewTopics(
TopicBuilder.name("defaultBoth")
.build(),
TopicBuilder.name("defaultPart")
.replicas(1)
.build(),
TopicBuilder.name("defaultRepl")
.partitions(3)
.build()
)
When using Spring Boot, a KafkaAdmin bean is automatically registered so you only need the NewTopic (and/or NewTopics ) @Bean s.
|
By default, if the broker is not available, a message is logged, but the context continues to load.
You can programmatically invoke the admin’s initialize()
method to try again later.
If you wish this condition to be considered fatal, set the admin’s fatalIfBrokerNotAvailable
property to true
.
The context then fails to initialize.
If the broker supports it (1.0.0 or higher), the admin increases the number of partitions if it is found that an existing topic has fewer partitions than the NewTopic.numPartitions .
|
Starting with version 2.7, the KafkaAdmin
provides methods to create and examine topics at runtime.
-
createOrModifyTopics
-
describeTopics
For more advanced features, you can use the AdminClient
directly.
The following example shows how to do so:
@Autowired
private KafkaAdmin admin;
...
AdminClient client = AdminClient.create(admin.getConfigurationProperties());
...
client.close();
4.1.3. Sending Messages
This section covers how to send messages.
Using KafkaTemplate
This section covers how to use KafkaTemplate
to send messages.
Overview
The KafkaTemplate
wraps a producer and provides convenience methods to send data to Kafka topics.
The following listing shows the relevant methods from KafkaTemplate
:
ListenableFuture<SendResult<K, V>> sendDefault(V data);
ListenableFuture<SendResult<K, V>> sendDefault(K key, V data);
ListenableFuture<SendResult<K, V>> sendDefault(Integer partition, K key, V data);
ListenableFuture<SendResult<K, V>> sendDefault(Integer partition, Long timestamp, K key, V data);
ListenableFuture<SendResult<K, V>> send(String topic, V data);
ListenableFuture<SendResult<K, V>> send(String topic, K key, V data);
ListenableFuture<SendResult<K, V>> send(String topic, Integer partition, K key, V data);
ListenableFuture<SendResult<K, V>> send(String topic, Integer partition, Long timestamp, K key, V data);
ListenableFuture<SendResult<K, V>> send(ProducerRecord<K, V> record);
ListenableFuture<SendResult<K, V>> send(Message<?> message);
Map<MetricName, ? extends Metric> metrics();
List<PartitionInfo> partitionsFor(String topic);
<T> T execute(ProducerCallback<K, V, T> callback);
// Flush the producer.
void flush();
interface ProducerCallback<K, V, T> {
T doInKafka(Producer<K, V> producer);
}
See the Javadoc for more detail.
The sendDefault
API requires that a default topic has been provided to the template.
The API takes in a timestamp
as a parameter and stores this timestamp in the record.
How the user-provided timestamp is stored depends on the timestamp type configured on the Kafka topic.
If the topic is configured to use CREATE_TIME
, the user specified timestamp is recorded (or generated if not specified).
If the topic is configured to use LOG_APPEND_TIME
, the user-specified timestamp is ignored and the broker adds in the local broker time.
The metrics
and partitionsFor
methods delegate to the same methods on the underlying Producer
.
The execute
method provides direct access to the underlying Producer
.
To use the template, you can configure a producer factory and provide it in the template’s constructor. The following example shows how to do so:
@Bean
public ProducerFactory<Integer, String> producerFactory() {
return new DefaultKafkaProducerFactory<>(producerConfigs());
}
@Bean
public Map<String, Object> producerConfigs() {
Map<String, Object> props = new HashMap<>();
props.put(ProducerConfig.BOOTSTRAP_SERVERS_CONFIG, "localhost:9092");
props.put(ProducerConfig.KEY_SERIALIZER_CLASS_CONFIG, StringSerializer.class);
props.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, StringSerializer.class);
// See https://kafka.apache.org/documentation/#producerconfigs for more properties
return props;
}
@Bean
public KafkaTemplate<Integer, String> kafkaTemplate() {
return new KafkaTemplate<Integer, String>(producerFactory());
}
Starting with version 2.5, you can now override the factory’s ProducerConfig
properties to create templates with different producer configurations from the same factory.
@Bean
public KafkaTemplate<String, String> stringTemplate(ProducerFactory<String, String> pf) {
return new KafkaTemplate<>(pf);
}
@Bean
public KafkaTemplate<String, byte[]> bytesTemplate(ProducerFactory<String, byte[]> pf) {
return new KafkaTemplate<>(pf,
Collections.singletonMap(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, ByteArraySerializer.class));
}
Note that a bean of type ProducerFactory<?, ?>
(such as the one auto-configured by Spring Boot) can be referenced with different narrowed generic types.
You can also configure the template by using standard <bean/>
definitions.
Then, to use the template, you can invoke one of its methods.
When you use the methods with a Message<?>
parameter, the topic, partition, and key information is provided in a message header that includes the following items:
-
KafkaHeaders.TOPIC
-
KafkaHeaders.PARTITION_ID
-
KafkaHeaders.MESSAGE_KEY
-
KafkaHeaders.TIMESTAMP
The message payload is the data.
Optionally, you can configure the KafkaTemplate
with a ProducerListener
to get an asynchronous callback with the results of the send (success or failure) instead of waiting for the Future
to complete.
The following listing shows the definition of the ProducerListener
interface:
public interface ProducerListener<K, V> {
void onSuccess(ProducerRecord<K, V> producerRecord, RecordMetadata recordMetadata);
void onError(ProducerRecord<K, V> producerRecord, RecordMetadata recordMetadata,
Exception exception);
}
By default, the template is configured with a LoggingProducerListener
, which logs errors and does nothing when the send is successful.
For convenience, default method implementations are provided in case you want to implement only one of the methods.
Notice that the send methods return a ListenableFuture<SendResult>
.
You can register a callback with the listener to receive the result of the send asynchronously.
The following example shows how to do so:
ListenableFuture<SendResult<Integer, String>> future = template.send("myTopic", "something");
future.addCallback(new ListenableFutureCallback<SendResult<Integer, String>>() {
@Override
public void onSuccess(SendResult<Integer, String> result) {
...
}
@Override
public void onFailure(Throwable ex) {
...
}
});
SendResult
has two properties, a ProducerRecord
and RecordMetadata
.
See the Kafka API documentation for information about those objects.
The Throwable
in onFailure
can be cast to a KafkaProducerException
; its failedProducerRecord
property contains the failed record.
Starting with version 2.5, you can use a KafkaSendCallback
instead of a ListenableFutureCallback
, making it easier to extract the failed ProducerRecord
, avoiding the need to cast the Throwable
:
ListenableFuture<SendResult<Integer, String>> future = template.send("topic", 1, "thing");
future.addCallback(new KafkaSendCallback<Integer, String>() {
@Override
public void onSuccess(SendResult<Integer, String> result) {
...
}
@Override
public void onFailure(KafkaProducerException ex) {
ProducerRecord<Integer, String> failed = ex.getFailedProducerRecord();
...
}
});
You can also use a pair of lambdas:
ListenableFuture<SendResult<Integer, String>> future = template.send("topic", 1, "thing");
future.addCallback(result -> {
...
}, (KafkaFailureCallback<Integer, String>) ex -> {
ProducerRecord<Integer, String> failed = ex.getFailedProducerRecord();
...
});
If you wish to block the sending thread to await the result, you can invoke the future’s get()
method; using the method with a timeout is recommended.
You may wish to invoke flush()
before waiting or, for convenience, the template has a constructor with an autoFlush
parameter that causes the template to flush()
on each send.
Flushing is only needed if you have set the linger.ms
producer property and want to immediately send a partial batch.
Examples
This section shows examples of sending messages to Kafka:
public void sendToKafka(final MyOutputData data) {
final ProducerRecord<String, String> record = createRecord(data);
ListenableFuture<SendResult<Integer, String>> future = template.send(record);
future.addCallback(new KafkaSendCallback<Integer, String>() {
@Override
public void onSuccess(SendResult<Integer, String> result) {
handleSuccess(data);
}
@Override
public void onFailure(KafkaProducerException ex) {
handleFailure(data, record, ex);
}
});
}
public void sendToKafka(final MyOutputData data) {
final ProducerRecord<String, String> record = createRecord(data);
try {
template.send(record).get(10, TimeUnit.SECONDS);
handleSuccess(data);
}
catch (ExecutionException e) {
handleFailure(data, record, e.getCause());
}
catch (TimeoutException | InterruptedException e) {
handleFailure(data, record, e);
}
}
Note that the cause of the ExecutionException
is KafkaProducerException
with the failedProducerRecord
property.
Using RoutingKafkaTemplate
Starting with version 2.5, you can use a RoutingKafkaTemplate
to select the producer at runtime, based on the destination topic
name.
The routing template does not support transactions, execute , flush , or metrics operations because the topic is not known for those operations.
|
The template requires a map of java.util.regex.Pattern
to ProducerFactory<Object, Object>
instances.
This map should be ordered (e.g. a LinkedHashMap
) because it is traversed in order; you should add more specific patterns at the beginning.
The following simple Spring Boot application provides an example of how to use the same template to send to different topics, each using a different value serializer.
@SpringBootApplication
public class Application {
public static void main(String[] args) {
SpringApplication.run(Application.class, args);
}
@Bean
public RoutingKafkaTemplate routingTemplate(GenericApplicationContext context,
ProducerFactory<Object, Object> pf) {
// Clone the PF with a different Serializer, register with Spring for shutdown
Map<String, Object> configs = new HashMap<>(pf.getConfigurationProperties());
configs.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, ByteArraySerializer.class);
DefaultKafkaProducerFactory<Object, Object> bytesPF = new DefaultKafkaProducerFactory<>(configs);
context.registerBean(DefaultKafkaProducerFactory.class, "bytesPF", bytesPF);
Map<Pattern, ProducerFactory<Object, Object>> map = new LinkedHashMap<>();
map.put(Pattern.compile("two"), bytesPF);
map.put(Pattern.compile(".+"), pf); // Default PF with StringSerializer
return new RoutingKafkaTemplate(map);
}
@Bean
public ApplicationRunner runner(RoutingKafkaTemplate routingTemplate) {
return args -> {
routingTemplate.send("one", "thing1");
routingTemplate.send("two", "thing2".getBytes());
};
}
}
The corresponding @KafkaListener
s for this example are shown in Annotation Properties.
For another technique to achieve similar results, but with the additional capability of sending different types to the same topic, see Delegating Serializer and Deserializer.
Using DefaultKafkaProducerFactory
As seen in Using KafkaTemplate
, a ProducerFactory
is used to create the producer.
When not using Transactions, by default, the DefaultKafkaProducerFactory
creates a singleton producer used by all clients, as recommended in the KafkaProducer
javadocs.
However, if you call flush()
on the template, this can cause delays for other threads using the same producer.
Starting with version 2.3, the DefaultKafkaProducerFactory
has a new property producerPerThread
.
When set to true
, the factory will create (and cache) a separate producer for each thread, to avoid this issue.
When producerPerThread is true , user code must call closeThreadBoundProducer() on the factory when the producer is no longer needed.
This will physically close the producer and remove it from the ThreadLocal .
Calling reset() or destroy() will not clean up these producers.
|
When creating a DefaultKafkaProducerFactory
, key and/or value Serializer
classes can be picked up from configuration by calling the constructor that only takes in a Map of properties (see example in Using KafkaTemplate
), or Serializer
instances may be passed to the DefaultKafkaProducerFactory
constructor (in which case all Producer
s share the same instances).
Alternatively you can provide Supplier<Serializer>
s (starting with version 2.3) that will be used to obtain separate Serializer
instances for each Producer
:
@Bean
public ProducerFactory<Integer, CustomValue> producerFactory() {
return new DefaultKafkaProducerFactory<>(producerConfigs(), null, () -> new CustomValueSerializer());
}
@Bean
public KafkaTemplate<Integer, CustomValue> kafkaTemplate() {
return new KafkaTemplate<Integer, CustomValue>(producerFactory());
}
Starting with version 2.5.10, you can now update the producer properties after the factory is created.
This might be useful, for example, if you have to update SSL key/trust store locations after a credentials change.
The changes will not affect existing producer instances; call reset()
to close any existing producers so that new producers will be created using the new properties.
NOTE: You cannot change a transactional producer factory to non-transactional, and vice-versa.
Two new methods are now provided:
void updateConfigs(Map<String, Object> updates);
void removeConfig(String configKey);
Starting with version 2.8, if you provide serializers as objects (in the constructor or via the setters), the factory will invoke the configure()
method to configure them with the configuration properties.
Using ReplyingKafkaTemplate
Version 2.1.3 introduced a subclass of KafkaTemplate
to provide request/reply semantics.
The class is named ReplyingKafkaTemplate
and has two additional methods; the following shows the method signatures:
RequestReplyFuture<K, V, R> sendAndReceive(ProducerRecord<K, V> record);
RequestReplyFuture<K, V, R> sendAndReceive(ProducerRecord<K, V> record,
Duration replyTimeout);
(Also see Request/Reply with Message<?>
s).
The result is a ListenableFuture
that is asynchronously populated with the result (or an exception, for a timeout).
The result also has a sendFuture
property, which is the result of calling KafkaTemplate.send()
.
You can use this future to determine the result of the send operation.
If the first method is used, or the replyTimeout
argument is null
, the template’s defaultReplyTimeout
property is used (5 seconds by default).
The following Spring Boot application shows an example of how to use the feature:
@SpringBootApplication
public class KRequestingApplication {
public static void main(String[] args) {
SpringApplication.run(KRequestingApplication.class, args).close();
}
@Bean
public ApplicationRunner runner(ReplyingKafkaTemplate<String, String, String> template) {
return args -> {
ProducerRecord<String, String> record = new ProducerRecord<>("kRequests", "foo");
RequestReplyFuture<String, String, String> replyFuture = template.sendAndReceive(record);
SendResult<String, String> sendResult = replyFuture.getSendFuture().get(10, TimeUnit.SECONDS);
System.out.println("Sent ok: " + sendResult.getRecordMetadata());
ConsumerRecord<String, String> consumerRecord = replyFuture.get(10, TimeUnit.SECONDS);
System.out.println("Return value: " + consumerRecord.value());
};
}
@Bean
public ReplyingKafkaTemplate<String, String, String> replyingTemplate(
ProducerFactory<String, String> pf,
ConcurrentMessageListenerContainer<String, String> repliesContainer) {
return new ReplyingKafkaTemplate<>(pf, repliesContainer);
}
@Bean
public ConcurrentMessageListenerContainer<String, String> repliesContainer(
ConcurrentKafkaListenerContainerFactory<String, String> containerFactory) {
ConcurrentMessageListenerContainer<String, String> repliesContainer =
containerFactory.createContainer("kReplies");
repliesContainer.getContainerProperties().setGroupId("repliesGroup");
repliesContainer.setAutoStartup(false);
return repliesContainer;
}
@Bean
public NewTopic kRequests() {
return TopicBuilder.name("kRequests")
.partitions(10)
.replicas(2)
.build();
}
@Bean
public NewTopic kReplies() {
return TopicBuilder.name("kReplies")
.partitions(10)
.replicas(2)
.build();
}
}
Note that we can use Boot’s auto-configured container factory to create the reply container.
If a non-trivial deserializer is being used for replies, consider using an ErrorHandlingDeserializer
that delegates to your configured deserializer.
When so configured, the RequestReplyFuture
will be completed exceptionally and you can catch the ExecutionException
, with the DeserializationException
in its cause
property.
Starting with version 2.6.7, in addition to detecting DeserializationException
s, the template will call the replyErrorChecker
function, if provided.
If it returns an exception, the future will be completed exceptionally.
Here is an example:
template.setReplyErrorChecker(record -> {
Header error = record.headers().lastHeader("serverSentAnError");
if (error != null) {
return new MyException(new String(error.value()));
}
else {
return null;
}
});
...
RequestReplyFuture<Integer, String, String> future = template.sendAndReceive(record);
try {
future.getSendFuture().get(10, TimeUnit.SECONDS); // send ok
ConsumerRecord<Integer, String> consumerRecord = future.get(10, TimeUnit.SECONDS);
...
}
catch (InterruptedException e) {
...
}
catch (ExecutionException e) {
if (e.getCause instanceof MyException) {
...
}
}
catch (TimeoutException e) {
...
}
The template sets a header (named KafkaHeaders.CORRELATION_ID
by default), which must be echoed back by the server side.
In this case, the following @KafkaListener
application responds:
@SpringBootApplication
public class KReplyingApplication {
public static void main(String[] args) {
SpringApplication.run(KReplyingApplication.class, args);
}
@KafkaListener(id="server", topics = "kRequests")
@SendTo // use default replyTo expression
public String listen(String in) {
System.out.println("Server received: " + in);
return in.toUpperCase();
}
@Bean
public NewTopic kRequests() {
return TopicBuilder.name("kRequests")
.partitions(10)
.replicas(2)
.build();
}
@Bean // not required if Jackson is on the classpath
public MessagingMessageConverter simpleMapperConverter() {
MessagingMessageConverter messagingMessageConverter = new MessagingMessageConverter();
messagingMessageConverter.setHeaderMapper(new SimpleKafkaHeaderMapper());
return messagingMessageConverter;
}
}
The @KafkaListener
infrastructure echoes the correlation ID and determines the reply topic.
See Forwarding Listener Results using @SendTo
for more information about sending replies.
The template uses the default header KafKaHeaders.REPLY_TOPIC
to indicate the topic to which the reply goes.
Starting with version 2.2, the template tries to detect the reply topic or partition from the configured reply container.
If the container is configured to listen to a single topic or a single TopicPartitionOffset
, it is used to set the reply headers.
If the container is configured otherwise, the user must set up the reply headers.
In this case, an INFO
log message is written during initialization.
The following example uses KafkaHeaders.REPLY_TOPIC
:
record.headers().add(new RecordHeader(KafkaHeaders.REPLY_TOPIC, "kReplies".getBytes()));
When you configure with a single reply TopicPartitionOffset
, you can use the same reply topic for multiple templates, as long as each instance listens on a different partition.
When configuring with a single reply topic, each instance must use a different group.id
.
In this case, all instances receive each reply, but only the instance that sent the request finds the correlation ID.
This may be useful for auto-scaling, but with the overhead of additional network traffic and the small cost of discarding each unwanted reply.
When you use this setting, we recommend that you set the template’s sharedReplyTopic
to true
, which reduces the logging level of unexpected replies to DEBUG instead of the default ERROR.
The following is an example of configuring the reply container to use the same shared reply topic:
@Bean
public ConcurrentMessageListenerContainer<String, String> replyContainer(
ConcurrentKafkaListenerContainerFactory<String, String> containerFactory) {
ConcurrentMessageListenerContainer<String, String> container = containerFactory.createContainer("topic2");
container.getContainerProperties().setGroupId(UUID.randomUUID().toString()); // unique
Properties props = new Properties();
props.setProperty(ConsumerConfig.AUTO_OFFSET_RESET_CONFIG, "latest"); // so the new group doesn't get old replies
container.getContainerProperties().setKafkaConsumerProperties(props);
return container;
}
If you have multiple client instances and you do not configure them as discussed in the preceding paragraph, each instance needs a dedicated reply topic.
An alternative is to set the KafkaHeaders.REPLY_PARTITION and use a dedicated partition for each instance.
The Header contains a four-byte int (big-endian).
The server must use this header to route the reply to the correct partition (@KafkaListener does this).
In this case, though, the reply container must not use Kafka’s group management feature and must be configured to listen on a fixed partition (by using a TopicPartitionOffset in its ContainerProperties constructor).
|
The DefaultKafkaHeaderMapper requires Jackson to be on the classpath (for the @KafkaListener ).
If it is not available, the message converter has no header mapper, so you must configure a MessagingMessageConverter with a SimpleKafkaHeaderMapper , as shown earlier.
|
By default, 3 headers are used:
-
KafkaHeaders.CORRELATION_ID
- used to correlate the reply to a request -
KafkaHeaders.REPLY_TOPIC
- used to tell the server where to reply -
KafkaHeaders.REPLY_PARTITION
- (optional) used to tell the server which partition to reply to
These header names are used by the @KafkaListener
infrastructure to route the reply.
Starting with version 2.3, you can customize the header names - the template has 3 properties correlationHeaderName
, replyTopicHeaderName
, and replyPartitionHeaderName
.
This is useful if your server is not a Spring application (or does not use the @KafkaListener
).
Request/Reply with Message<?>
s
Version 2.7 added methods to the ReplyingKafkaTemplate
to send and receive spring-messaging
's Message<?>
abstraction:
RequestReplyMessageFuture<K, V> sendAndReceive(Message<?> message);
<P> RequestReplyTypedMessageFuture<K, V, P> sendAndReceive(Message<?> message,
ParameterizedTypeReference<P> returnType);
These will use the template’s default replyTimeout
, there are also overloaded versions that can take a timeout in the method call.
Use the first method if the consumer’s Deserializer
or the template’s MessageConverter
can convert the payload without any additional information, either via configuration or type metadata in the reply message.
Use the second method if you need to provide type information for the return type, to assist the message converter. This also allows the same template to receive different types, even if there is no type metadata in the replies, such as when the server side is not a Spring application. The following is an example of the latter:
@Bean
ReplyingKafkaTemplate<String, String, String> template(
ProducerFactory<String, String> pf,
ConcurrentKafkaListenerContainerFactory<String, String> factory) {
ConcurrentMessageListenerContainer<String, String> replyContainer =
factory.createContainer("replies");
replyContainer.getContainerProperties().setGroupId("request.replies");
ReplyingKafkaTemplate<String, String, String> template =
new ReplyingKafkaTemplate<>(pf, replyContainer);
template.setMessageConverter(new ByteArrayJsonMessageConverter());
template.setDefaultTopic("requests");
return template;
}
@Bean
fun template(
pf: ProducerFactory<String?, String>?,
factory: ConcurrentKafkaListenerContainerFactory<String?, String?>
): ReplyingKafkaTemplate<String?, String, String?> {
val replyContainer = factory.createContainer("replies")
replyContainer.containerProperties.groupId = "request.replies"
val template = ReplyingKafkaTemplate(pf, replyContainer)
template.messageConverter = ByteArrayJsonMessageConverter()
template.defaultTopic = "requests"
return template
}
RequestReplyTypedMessageFuture<String, String, Thing> future1 =
template.sendAndReceive(MessageBuilder.withPayload("getAThing").build(),
new ParameterizedTypeReference<Thing>() { });
log.info(future1.getSendFuture().get(10, TimeUnit.SECONDS).getRecordMetadata().toString());
Thing thing = future1.get(10, TimeUnit.SECONDS).getPayload();
log.info(thing.toString());
RequestReplyTypedMessageFuture<String, String, List<Thing>> future2 =
template.sendAndReceive(MessageBuilder.withPayload("getThings").build(),
new ParameterizedTypeReference<List<Thing>>() { });
log.info(future2.getSendFuture().get(10, TimeUnit.SECONDS).getRecordMetadata().toString());
List<Thing> things = future2.get(10, TimeUnit.SECONDS).getPayload();
things.forEach(thing1 -> log.info(thing1.toString()));
val future1: RequestReplyTypedMessageFuture<String?, String?, Thing?>? =
template.sendAndReceive(MessageBuilder.withPayload("getAThing").build(),
object : ParameterizedTypeReference<Thing?>() {})
log.info(future1?.sendFuture?.get(10, TimeUnit.SECONDS)?.recordMetadata?.toString())
val thing = future1?.get(10, TimeUnit.SECONDS)?.payload
log.info(thing.toString())
val future2: RequestReplyTypedMessageFuture<String?, String?, List<Thing?>?>? =
template.sendAndReceive(MessageBuilder.withPayload("getThings").build(),
object : ParameterizedTypeReference<List<Thing?>?>() {})
log.info(future2?.sendFuture?.get(10, TimeUnit.SECONDS)?.recordMetadata.toString())
val things = future2?.get(10, TimeUnit.SECONDS)?.payload
things?.forEach(Consumer { thing1: Thing? -> log.info(thing1.toString()) })
Reply Type Message<?>
When the @KafkaListener
returns a Message<?>
, with versions before 2.5, it was necessary to populate the reply topic and correlation id headers.
In this example, we use the reply topic header from the request:
@KafkaListener(id = "requestor", topics = "request")
@SendTo
public Message<?> messageReturn(String in) {
return MessageBuilder.withPayload(in.toUpperCase())
.setHeader(KafkaHeaders.TOPIC, replyTo)
.setHeader(KafkaHeaders.MESSAGE_KEY, 42)
.setHeader(KafkaHeaders.CORRELATION_ID, correlation)
.build();
}
This also shows how to set a key on the reply record.
Starting with version 2.5, the framework will detect if these headers are missing and populate them with the topic - either the topic determined from the @SendTo
value or the incoming KafkaHeaders.REPLY_TOPIC
header (if present).
It will also echo the incoming KafkaHeaders.CORRELATION_ID
and KafkaHeaders.REPLY_PARTITION
, if present.
@KafkaListener(id = "requestor", topics = "request")
@SendTo // default REPLY_TOPIC header
public Message<?> messageReturn(String in) {
return MessageBuilder.withPayload(in.toUpperCase())
.setHeader(KafkaHeaders.MESSAGE_KEY, 42)
.build();
}
Aggregating Multiple Replies
The template in Using ReplyingKafkaTemplate
is strictly for a single request/reply scenario.
For cases where multiple receivers of a single message return a reply, you can use the AggregatingReplyingKafkaTemplate
.
This is an implementation of the client-side of the Scatter-Gather Enterprise Integration Pattern.
Like the ReplyingKafkaTemplate
, the AggregatingReplyingKafkaTemplate
constructor takes a producer factory and a listener container to receive the replies; it has a third parameter BiPredicate<List<ConsumerRecord<K, R>>, Boolean> releaseStrategy
which is consulted each time a reply is received; when the predicate returns true
, the collection of ConsumerRecord
s is used to complete the Future
returned by the sendAndReceive
method.
There is an additional property returnPartialOnTimeout
(default false).
When this is set to true
, instead of completing the future with a KafkaReplyTimeoutException
, a partial result completes the future normally (as long as at least one reply record has been received).
Starting with version 2.3.5, the predicate is also called after a timeout (if returnPartialOnTimeout
is true
).
The first argument is the current list of records; the second is true
if this call is due to a timeout.
The predicate can modify the list of records.
AggregatingReplyingKafkaTemplate<Integer, String, String> template =
new AggregatingReplyingKafkaTemplate<>(producerFactory, container,
coll -> coll.size() == releaseSize);
...
RequestReplyFuture<Integer, String, Collection<ConsumerRecord<Integer, String>>> future =
template.sendAndReceive(record);
future.getSendFuture().get(10, TimeUnit.SECONDS); // send ok
ConsumerRecord<Integer, Collection<ConsumerRecord<Integer, String>>> consumerRecord =
future.get(30, TimeUnit.SECONDS);
Notice that the return type is a ConsumerRecord
with a value that is a collection of ConsumerRecord
s.
The "outer" ConsumerRecord
is not a "real" record, it is synthesized by the template, as a holder for the actual reply records received for the request.
When a normal release occurs (release strategy returns true), the topic is set to aggregatedResults
; if returnPartialOnTimeout
is true, and timeout occurs (and at least one reply record has been received), the topic is set to partialResultsAfterTimeout
.
The template provides constant static variables for these "topic" names:
/**
* Pseudo topic name for the "outer" {@link ConsumerRecords} that has the aggregated
* results in its value after a normal release by the release strategy.
*/
public static final String AGGREGATED_RESULTS_TOPIC = "aggregatedResults";
/**
* Pseudo topic name for the "outer" {@link ConsumerRecords} that has the aggregated
* results in its value after a timeout.
*/
public static final String PARTIAL_RESULTS_AFTER_TIMEOUT_TOPIC = "partialResultsAfterTimeout";
The real ConsumerRecord
s in the Collection
contain the actual topic(s) from which the replies are received.
The listener container for the replies MUST be configured with AckMode.MANUAL or AckMode.MANUAL_IMMEDIATE ; the consumer property enable.auto.commit must be false (the default since version 2.3).
To avoid any possibility of losing messages, the template only commits offsets when there are zero requests outstanding, i.e. when the last outstanding request is released by the release strategy.
After a rebalance, it is possible for duplicate reply deliveries; these will be ignored for any in-flight requests; you may see error log messages when duplicate replies are received for already released replies.
|
If you use an ErrorHandlingDeserializer with this aggregating template, the framework will not automatically detect DeserializationException s.
Instead, the record (with a null value) will be returned intact, with the deserialization exception(s) in headers.
It is recommended that applications call the utility method ReplyingKafkaTemplate.checkDeserialization() method to determine if a deserialization exception occurred.
See its javadocs for more information.
The replyErrorChecker is also not called for this aggregating template; you should perform the checks on each element of the reply.
|
4.1.4. Receiving Messages
You can receive messages by configuring a MessageListenerContainer
and providing a message listener or by using the @KafkaListener
annotation.
Message Listeners
When you use a message listener container, you must provide a listener to receive data. There are currently eight supported interfaces for message listeners. The following listing shows these interfaces:
public interface MessageListener<K, V> { (1)
void onMessage(ConsumerRecord<K, V> data);
}
public interface AcknowledgingMessageListener<K, V> { (2)
void onMessage(ConsumerRecord<K, V> data, Acknowledgment acknowledgment);
}
public interface ConsumerAwareMessageListener<K, V> extends MessageListener<K, V> { (3)
void onMessage(ConsumerRecord<K, V> data, Consumer<?, ?> consumer);
}
public interface AcknowledgingConsumerAwareMessageListener<K, V> extends MessageListener<K, V> { (4)
void onMessage(ConsumerRecord<K, V> data, Acknowledgment acknowledgment, Consumer<?, ?> consumer);
}
public interface BatchMessageListener<K, V> { (5)
void onMessage(List<ConsumerRecord<K, V>> data);
}
public interface BatchAcknowledgingMessageListener<K, V> { (6)
void onMessage(List<ConsumerRecord<K, V>> data, Acknowledgment acknowledgment);
}
public interface BatchConsumerAwareMessageListener<K, V> extends BatchMessageListener<K, V> { (7)
void onMessage(List<ConsumerRecord<K, V>> data, Consumer<?, ?> consumer);
}
public interface BatchAcknowledgingConsumerAwareMessageListener<K, V> extends BatchMessageListener<K, V> { (8)
void onMessage(List<ConsumerRecord<K, V>> data, Acknowledgment acknowledgment, Consumer<?, ?> consumer);
}
1 | Use this interface for processing individual ConsumerRecord instances received from the Kafka consumer poll() operation when using auto-commit or one of the container-managed commit methods. |
2 | Use this interface for processing individual ConsumerRecord instances received from the Kafka consumer poll() operation when using one of the manual commit methods. |
3 | Use this interface for processing individual ConsumerRecord instances received from the Kafka consumer poll() operation when using auto-commit or one of the container-managed commit methods.
Access to the Consumer object is provided. |
4 | Use this interface for processing individual ConsumerRecord instances received from the Kafka consumer poll() operation when using one of the manual commit methods.
Access to the Consumer object is provided. |
5 | Use this interface for processing all ConsumerRecord instances received from the Kafka consumer poll() operation when using auto-commit or one of the container-managed commit methods.
AckMode.RECORD is not supported when you use this interface, since the listener is given the complete batch. |
6 | Use this interface for processing all ConsumerRecord instances received from the Kafka consumer poll() operation when using one of the manual commit methods. |
7 | Use this interface for processing all ConsumerRecord instances received from the Kafka consumer poll() operation when using auto-commit or one of the container-managed commit methods.
AckMode.RECORD is not supported when you use this interface, since the listener is given the complete batch.
Access to the Consumer object is provided. |
8 | Use this interface for processing all ConsumerRecord instances received from the Kafka consumer poll() operation when using one of the manual commit methods.
Access to the Consumer object is provided. |
The Consumer object is not thread-safe.
You must only invoke its methods on the thread that calls the listener.
|
You should not execute any Consumer<?, ?> methods that affect the consumer’s positions and or committed offsets in your listener; the container needs to manage such information.
|
Message Listener Containers
Two MessageListenerContainer
implementations are provided:
-
KafkaMessageListenerContainer
-
ConcurrentMessageListenerContainer
The KafkaMessageListenerContainer
receives all message from all topics or partitions on a single thread.
The ConcurrentMessageListenerContainer
delegates to one or more KafkaMessageListenerContainer
instances to provide multi-threaded consumption.
Starting with version 2.2.7, you can add a RecordInterceptor
to the listener container; it will be invoked before calling the listener allowing inspection or modification of the record.
If the interceptor returns null, the listener is not called.
Starting with version 2.7, it has additional methods which are called after the listener exits (normally, or by throwing an exception).
Also, starting with version 2.7, there is now a BatchInterceptor
, providing similar functionality for Batch Listeners.
In addition, the ConsumerAwareRecordInterceptor
(and BatchInterceptor
) provide access to the Consumer<?, ?>
.
This might be used, for example, to access the consumer metrics in the interceptor.
You should not execute any methods that affect the consumer’s positions and or committed offsets in these interceptors; the container needs to manage such information. |
The CompositeRecordInterceptor
and CompositeBatchInterceptor
can be used to invoke multiple interceptors.
By default, starting with version 2.8, when using transactions, the interceptor is invoked before the transaction has started.
You can set the listener container’s interceptBeforeTx
property to false
to invoke the interceptor after the transaction has started instead.
Starting with versions 2.3.8, 2.4.6, the ConcurrentMessageListenerContainer
now supports Static Membership when the concurrency is greater than one.
The group.instance.id
is suffixed with -n
with n
starting at 1
.
This, together with an increased session.timeout.ms
, can be used to reduce rebalance events, for example, when application instances are restarted.
Using KafkaMessageListenerContainer
The following constructor is available:
public KafkaMessageListenerContainer(ConsumerFactory<K, V> consumerFactory,
ContainerProperties containerProperties)
It receives a ConsumerFactory
and information about topics and partitions, as well as other configuration, in a ContainerProperties
object.
ContainerProperties
has the following constructors:
public ContainerProperties(TopicPartitionOffset... topicPartitions)
public ContainerProperties(String... topics)
public ContainerProperties(Pattern topicPattern)
The first constructor takes an array of TopicPartitionOffset
arguments to explicitly instruct the container about which partitions to use (using the consumer assign()
method) and with an optional initial offset.
A positive value is an absolute offset by default.
A negative value is relative to the current last offset within a partition by default.
A constructor for TopicPartitionOffset
that takes an additional boolean
argument is provided.
If this is true
, the initial offsets (positive or negative) are relative to the current position for this consumer.
The offsets are applied when the container is started.
The second takes an array of topics, and Kafka allocates the partitions based on the group.id
property — distributing partitions across the group.
The third uses a regex Pattern
to select the topics.
To assign a MessageListener
to a container, you can use the ContainerProps.setMessageListener
method when creating the Container.
The following example shows how to do so:
ContainerProperties containerProps = new ContainerProperties("topic1", "topic2");
containerProps.setMessageListener(new MessageListener<Integer, String>() {
...
});
DefaultKafkaConsumerFactory<Integer, String> cf =
new DefaultKafkaConsumerFactory<>(consumerProps());
KafkaMessageListenerContainer<Integer, String> container =
new KafkaMessageListenerContainer<>(cf, containerProps);
return container;
Note that when creating a DefaultKafkaConsumerFactory
, using the constructor that just takes in the properties as above means that key and value Deserializer
classes are picked up from configuration.
Alternatively, Deserializer
instances may be passed to the DefaultKafkaConsumerFactory
constructor for key and/or value, in which case all Consumers share the same instances.
Another option is to provide Supplier<Deserializer>
s (starting with version 2.3) that will be used to obtain separate Deserializer
instances for each Consumer
:
DefaultKafkaConsumerFactory<Integer, CustomValue> cf =
new DefaultKafkaConsumerFactory<>(consumerProps(), null, () -> new CustomValueDeserializer());
KafkaMessageListenerContainer<Integer, String> container =
new KafkaMessageListenerContainer<>(cf, containerProps);
return container;
Refer to the Javadoc for ContainerProperties
for more information about the various properties that you can set.
Since version 2.1.1, a new property called logContainerConfig
is available.
When true
and INFO
logging is enabled each listener container writes a log message summarizing its configuration properties.
By default, logging of topic offset commits is performed at the DEBUG
logging level.
Starting with version 2.1.2, a property in ContainerProperties
called commitLogLevel
lets you specify the log level for these messages.
For example, to change the log level to INFO
, you can use containerProperties.setCommitLogLevel(LogIfLevelEnabled.Level.INFO);
.
Starting with version 2.2, a new container property called missingTopicsFatal
has been added (default: false
since 2.3.4).
This prevents the container from starting if any of the configured topics are not present on the broker.
It does not apply if the container is configured to listen to a topic pattern (regex).
Previously, the container threads looped within the consumer.poll()
method waiting for the topic to appear while logging many messages.
Aside from the logs, there was no indication that there was a problem.
As of version 2.8, a new container property authExceptionRetryInterval
has been introduced.
This causes the container to retry fetching messages after getting any AuthenticationException
or AuthorizationException
from the KafkaConsumer
.
This can happen when, for example, the configured user is denied access to read a certain topic or credentials are incorrect.
Defining authExceptionRetryInterval
allows the container to recover when proper permissions are granted.
By default, no interval is configured - authentication and authorization errors are considered fatal, which causes the container to stop. |
Starting with version 2.8, when creating the consumer factory, if you provide deserializers as objects (in the constructor or via the setters), the factory will invoke the configure()
method to configure them with the configuration properties.
Using ConcurrentMessageListenerContainer
The single constructor is similar to the KafkaListenerContainer
constructor.
The following listing shows the constructor’s signature:
public ConcurrentMessageListenerContainer(ConsumerFactory<K, V> consumerFactory,
ContainerProperties containerProperties)
It also has a concurrency
property.
For example, container.setConcurrency(3)
creates three KafkaMessageListenerContainer
instances.
For the first constructor, Kafka distributes the partitions across the consumers using its group management capabilities.
When listening to multiple topics, the default partition distribution may not be what you expect.
For example, if you have three topics with five partitions each and you want to use When using Spring Boot, you can assign set the strategy as follows:
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When the container properties are configured with TopicPartitionOffset
s, the ConcurrentMessageListenerContainer
distributes the TopicPartitionOffset
instances across the delegate KafkaMessageListenerContainer
instances.
If, say, six TopicPartitionOffset
instances are provided and the concurrency
is 3
; each container gets two partitions.
For five TopicPartitionOffset
instances, two containers get two partitions, and the third gets one.
If the concurrency
is greater than the number of TopicPartitions
, the concurrency
is adjusted down such that each container gets one partition.
The client.id property (if set) is appended with -n where n is the consumer instance that corresponds to the concurrency.
This is required to provide unique names for MBeans when JMX is enabled.
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Starting with version 1.3, the MessageListenerContainer
provides access to the metrics of the underlying KafkaConsumer
.
In the case of ConcurrentMessageListenerContainer
, the metrics()
method returns the metrics for all the target KafkaMessageListenerContainer
instances.
The metrics are grouped into the Map<MetricName, ? extends Metric>
by the client-id
provided for the underlying KafkaConsumer
.
Starting with version 2.3, the ContainerProperties
provides an idleBetweenPolls
option to let the main loop in the listener container to sleep between KafkaConsumer.poll()
calls.
An actual sleep interval is selected as the minimum from the provided option and difference between the max.poll.interval.ms
consumer config and the current records batch processing time.
Committing Offsets
Several options are provided for committing offsets.
If the enable.auto.commit
consumer property is true
, Kafka auto-commits the offsets according to its configuration.
If it is false
, the containers support several AckMode
settings (described in the next list).
The default AckMode
is BATCH
.
Starting with version 2.3, the framework sets enable.auto.commit
to false
unless explicitly set in the configuration.
Previously, the Kafka default (true
) was used if the property was not set.
The consumer poll()
method returns one or more ConsumerRecords
.
The MessageListener
is called for each record.
The following lists describes the action taken by the container for each AckMode
(when transactions are not being used):
-
RECORD
: Commit the offset when the listener returns after processing the record. -
BATCH
: Commit the offset when all the records returned by thepoll()
have been processed. -
TIME
: Commit the offset when all the records returned by thepoll()
have been processed, as long as theackTime
since the last commit has been exceeded. -
COUNT
: Commit the offset when all the records returned by thepoll()
have been processed, as long asackCount
records have been received since the last commit. -
COUNT_TIME
: Similar toTIME
andCOUNT
, but the commit is performed if either condition istrue
. -
MANUAL
: The message listener is responsible toacknowledge()
theAcknowledgment
. After that, the same semantics asBATCH
are applied. -
MANUAL_IMMEDIATE
: Commit the offset immediately when theAcknowledgment.acknowledge()
method is called by the listener.
When using transactions, the offset(s) are sent to the transaction and the semantics are equivalent to RECORD
or BATCH
, depending on the listener type (record or batch).
MANUAL , and MANUAL_IMMEDIATE require the listener to be an AcknowledgingMessageListener or a BatchAcknowledgingMessageListener .
See Message Listeners.
|
Depending on the syncCommits
container property, the commitSync()
or commitAsync()
method on the consumer is used.
syncCommits
is true
by default; also see setSyncCommitTimeout
.
See setCommitCallback
to get the results of asynchronous commits; the default callback is the LoggingCommitCallback
which logs errors (and successes at debug level).
Because the listener container has it’s own mechanism for committing offsets, it prefers the Kafka ConsumerConfig.ENABLE_AUTO_COMMIT_CONFIG
to be false
.
Starting with version 2.3, it unconditionally sets it to false unless specifically set in the consumer factory or the container’s consumer property overrides.
The Acknowledgment
has the following method:
public interface Acknowledgment {
void acknowledge();
}
This method gives the listener control over when offsets are committed.
Starting with version 2.3, the Acknowledgment
interface has two additional methods nack(long sleep)
and nack(int index, long sleep)
.
The first one is used with a record listener, the second with a batch listener.
Calling the wrong method for your listener type will throw an IllegalStateException
.
If you want to commit a partial batch, using nack() , When using transactions, set the AckMode to MANUAL ; invoking nack() will send the offsets of the successfully processed records to the transaction.
|
nack() can only be called on the consumer thread that invokes your listener.
|
With a record listener, when nack()
is called, any pending offsets are committed, the remaing records from the last poll are discarded, and seeks are performed on their partitions so that the failed record and unprocessed records are redelivered on the next poll()
.
The consumer thread can be paused before redelivery, by setting the sleep
argument.
This is similar functionality to throwing an exception when the container is configured with a DefaultErrorHandler
.
When using a batch listener, you can specify the index within the batch where the failure occurred.
When nack()
is called, offsets will be committed for records before the index and seeks are performed on the partitions for the failed and discarded records so that they will be redelivered on the next poll()
.
See Container Error Handlers for more information.
When using partition assignment via group management, it is important to ensure the sleep argument (plus the time spent processing records from the previous poll) is less than the consumer max.poll.interval.ms property.
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Listener Container Auto Startup
The listener containers implement SmartLifecycle
, and autoStartup
is true
by default.
The containers are started in a late phase (Integer.MAX-VALUE - 100
).
Other components that implement SmartLifecycle
, to handle data from listeners, should be started in an earlier phase.
The - 100
leaves room for later phases to enable components to be auto-started after the containers.
Manually Committing Offsets
Normally, when using AckMode.MANUAL
or AckMode.MANUAL_IMMEDIATE
, the acknowledgments must be acknowledged in order, because Kafka does not maintain state for each record, only a committed offset for each group/partition.
Starting with version 2.8, you can now set the container property asyncAcks
, which allows the acknowledgments for records returned by the poll to be acknowledged in any order.
The listener container will defer the out-of-order commits until the missing acknowledgments are received.
The consumer will be paused (no new records delivered) until all the offsets for the previous poll have been committed.
While this feature allows applications to process records asynchronously, it should be understood that it increases the possibility of duplicate deliveries after a failure. |
@KafkaListener
Annotation
The @KafkaListener
annotation is used to designate a bean method as a listener for a listener container.
The bean is wrapped in a MessagingMessageListenerAdapter
configured with various features, such as converters to convert the data, if necessary, to match the method parameters.
You can configure most attributes on the annotation with SpEL by using #{…}
or property placeholders (${…}
).
See the Javadoc for more information.
Record Listeners
The @KafkaListener
annotation provides a mechanism for simple POJO listeners.
The following example shows how to use it:
public class Listener {
@KafkaListener(id = "foo", topics = "myTopic", clientIdPrefix = "myClientId")
public void listen(String data) {
...
}
}
This mechanism requires an @EnableKafka
annotation on one of your @Configuration
classes and a listener container factory, which is used to configure the underlying ConcurrentMessageListenerContainer
.
By default, a bean with name kafkaListenerContainerFactory
is expected.
The following example shows how to use ConcurrentMessageListenerContainer
:
@Configuration
@EnableKafka
public class KafkaConfig {
@Bean
KafkaListenerContainerFactory<ConcurrentMessageListenerContainer<Integer, String>>
kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(consumerFactory());
factory.setConcurrency(3);
factory.getContainerProperties().setPollTimeout(3000);
return factory;
}
@Bean
public ConsumerFactory<Integer, String> consumerFactory() {
return new DefaultKafkaConsumerFactory<>(consumerConfigs());
}
@Bean
public Map<String, Object> consumerConfigs() {
Map<String, Object> props = new HashMap<>();
props.put(ProducerConfig.BOOTSTRAP_SERVERS_CONFIG, embeddedKafka.getBrokersAsString());
...
return props;
}
}
Notice that, to set container properties, you must use the getContainerProperties()
method on the factory.
It is used as a template for the actual properties injected into the container.
Starting with version 2.1.1, you can now set the client.id
property for consumers created by the annotation.
The clientIdPrefix
is suffixed with -n
, where n
is an integer representing the container number when using concurrency.
Starting with version 2.2, you can now override the container factory’s concurrency
and autoStartup
properties by using properties on the annotation itself.
The properties can be simple values, property placeholders, or SpEL expressions.
The following example shows how to do so:
@KafkaListener(id = "myListener", topics = "myTopic",
autoStartup = "${listen.auto.start:true}", concurrency = "${listen.concurrency:3}")
public void listen(String data) {
...
}
Explicit Partition Assignment
You can also configure POJO listeners with explicit topics and partitions (and, optionally, their initial offsets). The following example shows how to do so:
@KafkaListener(id = "thing2", topicPartitions =
{ @TopicPartition(topic = "topic1", partitions = { "0", "1" }),
@TopicPartition(topic = "topic2", partitions = "0",
partitionOffsets = @PartitionOffset(partition = "1", initialOffset = "100"))
})
public void listen(ConsumerRecord<?, ?> record) {
...
}
You can specify each partition in the partitions
or partitionOffsets
attribute but not both.
As with most annotation properties, you can use SpEL expressions; for an example of how to generate a large list of partitions, see Manually Assigning All Partitions.
Starting with version 2.5.5, you can apply an initial offset to all assigned partitions:
@KafkaListener(id = "thing3", topicPartitions =
{ @TopicPartition(topic = "topic1", partitions = { "0", "1" },
partitionOffsets = @PartitionOffset(partition = "*", initialOffset = "0"))
})
public void listen(ConsumerRecord<?, ?> record) {
...
}
The *
wildcard represents all partitions in the partitions
attribute.
There must only be one @PartitionOffset
with the wildcard in each @TopicPartition
.
In addition, when the listener implements ConsumerSeekAware
, onPartitionsAssigned
is now called, even when using manual assignment.
This allows, for example, any arbitrary seek operations at that time.
Starting with version 2.6.4, you can specify a comma-delimited list of partitions, or partition ranges:
@KafkaListener(id = "pp", autoStartup = "false",
topicPartitions = @TopicPartition(topic = "topic1",
partitions = "0-5, 7, 10-15"))
public void process(String in) {
...
}
The range is inclusive; the example above will assign partitions 0, 1, 2, 3, 4, 5, 7, 10, 11, 12, 13, 14, 15
.
The same technique can be used when specifying initial offsets:
@KafkaListener(id = "thing3", topicPartitions =
{ @TopicPartition(topic = "topic1",
partitionOffsets = @PartitionOffset(partition = "0-5", initialOffset = "0"))
})
public void listen(ConsumerRecord<?, ?> record) {
...
}
The initial offset will be applied to all 6 partitions.
Manual Acknowledgment
When using manual AckMode
, you can also provide the listener with the Acknowledgment
.
The following example also shows how to use a different container factory.
@KafkaListener(id = "cat", topics = "myTopic",
containerFactory = "kafkaManualAckListenerContainerFactory")
public void listen(String data, Acknowledgment ack) {
...
ack.acknowledge();
}
Consumer Record Metadata
Finally, metadata about the record is available from message headers. You can use the following header names to retrieve the headers of the message:
-
KafkaHeaders.OFFSET
-
KafkaHeaders.RECEIVED_MESSAGE_KEY
-
KafkaHeaders.RECEIVED_TOPIC
-
KafkaHeaders.RECEIVED_PARTITION_ID
-
KafkaHeaders.RECEIVED_TIMESTAMP
-
KafkaHeaders.TIMESTAMP_TYPE
Starting with version 2.5 the RECEIVED_MESSAGE_KEY
is not present if the incoming record has a null
key; previously the header was populated with a null
value.
This change is to make the framework consistent with spring-messaging
conventions where null
valued headers are not present.
The following example shows how to use the headers:
@KafkaListener(id = "qux", topicPattern = "myTopic1")
public void listen(@Payload String foo,
@Header(name = KafkaHeaders.RECEIVED_MESSAGE_KEY, required = false) Integer key,
@Header(KafkaHeaders.RECEIVED_PARTITION_ID) int partition,
@Header(KafkaHeaders.RECEIVED_TOPIC) String topic,
@Header(KafkaHeaders.RECEIVED_TIMESTAMP) long ts
) {
...
}
Starting with version 2.5, instead of using discrete headers, you can receive record metadata in a ConsumerRecordMetadata
parameter.
@KafkaListener(...)
public void listen(String str, ConsumerRecordMetadata meta) {
...
}
This contains all the data from the ConsumerRecord
except the key and value.
Batch Listeners
Starting with version 1.1, you can configure @KafkaListener
methods to receive the entire batch of consumer records received from the consumer poll.
To configure the listener container factory to create batch listeners, you can set the batchListener
property.
The following example shows how to do so:
@Bean
public KafkaListenerContainerFactory<?, ?> batchFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(consumerFactory());
factory.setBatchListener(true); // <<<<<<<<<<<<<<<<<<<<<<<<<
return factory;
}
Starting with version 2.8, you can override the factory’s batchListener propery using the batch property on the @KafkaListener annotation.
This, together with the changes to Container Error Handlers allows the same factory to be used for both record and batch listeners.
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The following example shows how to receive a list of payloads:
@KafkaListener(id = "list", topics = "myTopic", containerFactory = "batchFactory")
public void listen(List<String> list) {
...
}
The topic, partition, offset, and so on are available in headers that parallel the payloads. The following example shows how to use the headers:
@KafkaListener(id = "list", topics = "myTopic", containerFactory = "batchFactory")
public void listen(List<String> list,
@Header(KafkaHeaders.RECEIVED_MESSAGE_KEY) List<Integer> keys,
@Header(KafkaHeaders.RECEIVED_PARTITION_ID) List<Integer> partitions,
@Header(KafkaHeaders.RECEIVED_TOPIC) List<String> topics,
@Header(KafkaHeaders.OFFSET) List<Long> offsets) {
...
}
Alternatively, you can receive a List
of Message<?>
objects with each offset and other details in each message, but it must be the only parameter (aside from optional Acknowledgment
, when using manual commits, and/or Consumer<?, ?>
parameters) defined on the method.
The following example shows how to do so:
@KafkaListener(id = "listMsg", topics = "myTopic", containerFactory = "batchFactory")
public void listen14(List<Message<?>> list) {
...
}
@KafkaListener(id = "listMsgAck", topics = "myTopic", containerFactory = "batchFactory")
public void listen15(List<Message<?>> list, Acknowledgment ack) {
...
}
@KafkaListener(id = "listMsgAckConsumer", topics = "myTopic", containerFactory = "batchFactory")
public void listen16(List<Message<?>> list, Acknowledgment ack, Consumer<?, ?> consumer) {
...
}
No conversion is performed on the payloads in this case.
If the BatchMessagingMessageConverter
is configured with a RecordMessageConverter
, you can also add a generic type to the Message
parameter and the payloads are converted.
See Payload Conversion with Batch Listeners for more information.
You can also receive a list of ConsumerRecord<?, ?>
objects, but it must be the only parameter (aside from optional Acknowledgment
, when using manual commits and Consumer<?, ?>
parameters) defined on the method.
The following example shows how to do so:
@KafkaListener(id = "listCRs", topics = "myTopic", containerFactory = "batchFactory")
public void listen(List<ConsumerRecord<Integer, String>> list) {
...
}
@KafkaListener(id = "listCRsAck", topics = "myTopic", containerFactory = "batchFactory")
public void listen(List<ConsumerRecord<Integer, String>> list, Acknowledgment ack) {
...
}
Starting with version 2.2, the listener can receive the complete ConsumerRecords<?, ?>
object returned by the poll()
method, letting the listener access additional methods, such as partitions()
(which returns the TopicPartition
instances in the list) and records(TopicPartition)
(which gets selective records).
Again, this must be the only parameter (aside from optional Acknowledgment
, when using manual commits or Consumer<?, ?>
parameters) on the method.
The following example shows how to do so:
@KafkaListener(id = "pollResults", topics = "myTopic", containerFactory = "batchFactory")
public void pollResults(ConsumerRecords<?, ?> records) {
...
}
If the container factory has a RecordFilterStrategy configured, it is ignored for ConsumerRecords<?, ?> listeners, with a WARN log message emitted.
Records can only be filtered with a batch listener if the <List<?>> form of listener is used.
By default, records are filtered one-at-a-time; starting with version 2.8, you can override filterBatch to filter the entire batch in one call.
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Annotation Properties
Starting with version 2.0, the id
property (if present) is used as the Kafka consumer group.id
property, overriding the configured property in the consumer factory, if present.
You can also set groupId
explicitly or set idIsGroup
to false to restore the previous behavior of using the consumer factory group.id
.
You can use property placeholders or SpEL expressions within most annotation properties, as the following example shows:
@KafkaListener(topics = "${some.property}")
@KafkaListener(topics = "#{someBean.someProperty}",
groupId = "#{someBean.someProperty}.group")
Starting with version 2.1.2, the SpEL expressions support a special token: __listener
.
It is a pseudo bean name that represents the current bean instance within which this annotation exists.
Consider the following example:
@Bean
public Listener listener1() {
return new Listener("topic1");
}
@Bean
public Listener listener2() {
return new Listener("topic2");
}
Given the beans in the previous example, we can then use the following:
public class Listener {
private final String topic;
public Listener(String topic) {
this.topic = topic;
}
@KafkaListener(topics = "#{__listener.topic}",
groupId = "#{__listener.topic}.group")
public void listen(...) {
...
}
public String getTopic() {
return this.topic;
}
}
If, in the unlikely event that you have an actual bean called __listener
, you can change the expression token byusing the beanRef
attribute.
The following example shows how to do so:
@KafkaListener(beanRef = "__x", topics = "#{__x.topic}",
groupId = "#{__x.topic}.group")
Starting with version 2.2.4, you can specify Kafka consumer properties directly on the annotation, these will override any properties with the same name configured in the consumer factory. You cannot specify the group.id
and client.id
properties this way; they will be ignored; use the groupId
and clientIdPrefix
annotation properties for those.
The properties are specified as individual strings with the normal Java Properties
file format: foo:bar
, foo=bar
, or foo bar
.
@KafkaListener(topics = "myTopic", groupId = "group", properties = {
"max.poll.interval.ms:60000",
ConsumerConfig.MAX_POLL_RECORDS_CONFIG + "=100"
})
The following is an example of the corresponding listeners for the example in Using RoutingKafkaTemplate
.
@KafkaListener(id = "one", topics = "one")
public void listen1(String in) {
System.out.println("1: " + in);
}
@KafkaListener(id = "two", topics = "two",
properties = "value.deserializer:org.apache.kafka.common.serialization.ByteArrayDeserializer")
public void listen2(byte[] in) {
System.out.println("2: " + new String(in));
}
Obtaining the Consumer group.id
When running the same listener code in multiple containers, it may be useful to be able to determine which container (identified by its group.id
consumer property) that a record came from.
You can call KafkaUtils.getConsumerGroupId()
on the listener thread to do this.
Alternatively, you can access the group id in a method parameter.
@KafkaListener(id = "bar", topicPattern = "${topicTwo:annotated2}", exposeGroupId = "${always:true}")
public void listener(@Payload String foo,
@Header(KafkaHeaders.GROUP_ID) String groupId) {
...
}
This is available in record listeners and batch listeners that receive a List<?> of records.
It is not available in a batch listener that receives a ConsumerRecords<?, ?> argument.
Use the KafkaUtils mechanism in that case.
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Container Thread Naming
Listener containers currently use two task executors, one to invoke the consumer and another that is used to invoke the listener when the kafka consumer property enable.auto.commit
is false
.
You can provide custom executors by setting the consumerExecutor
and listenerExecutor
properties of the container’s ContainerProperties
.
When using pooled executors, be sure that enough threads are available to handle the concurrency across all the containers in which they are used.
When using the ConcurrentMessageListenerContainer
, a thread from each is used for each consumer (concurrency
).
If you do not provide a consumer executor, a SimpleAsyncTaskExecutor
is used.
This executor creates threads with names similar to <beanName>-C-1
(consumer thread).
For the ConcurrentMessageListenerContainer
, the <beanName>
part of the thread name becomes <beanName>-m
, where m
represents the consumer instance.
n
increments each time the container is started.
So, with a bean name of container
, threads in this container will be named container-0-C-1
, container-1-C-1
etc., after the container is started the first time; container-0-C-2
, container-1-C-2
etc., after a stop and subsequent start.
@KafkaListener
as a Meta Annotation
Starting with version 2.2, you can now use @KafkaListener
as a meta annotation.
The following example shows how to do so:
@Target(ElementType.METHOD)
@Retention(RetentionPolicy.RUNTIME)
@KafkaListener
public @interface MyThreeConsumersListener {
@AliasFor(annotation = KafkaListener.class, attribute = "id")
String id();
@AliasFor(annotation = KafkaListener.class, attribute = "topics")
String[] topics();
@AliasFor(annotation = KafkaListener.class, attribute = "concurrency")
String concurrency() default "3";
}
You must alias at least one of topics
, topicPattern
, or topicPartitions
(and, usually, id
or groupId
unless you have specified a group.id
in the consumer factory configuration).
The following example shows how to do so:
@MyThreeConsumersListener(id = "my.group", topics = "my.topic")
public void listen1(String in) {
...
}
@KafkaListener
on a Class
When you use @KafkaListener
at the class-level, you must specify @KafkaHandler
at the method level.
When messages are delivered, the converted message payload type is used to determine which method to call.
The following example shows how to do so:
@KafkaListener(id = "multi", topics = "myTopic")
static class MultiListenerBean {
@KafkaHandler
public void listen(String foo) {
...
}
@KafkaHandler
public void listen(Integer bar) {
...
}
@KafkaHandler(isDefault = true)
public void listenDefault(Object object) {
...
}
}
Starting with version 2.1.3, you can designate a @KafkaHandler
method as the default method that is invoked if there is no match on other methods.
At most, one method can be so designated.
When using @KafkaHandler
methods, the payload must have already been converted to the domain object (so the match can be performed).
Use a custom deserializer, the JsonDeserializer
, or the JsonMessageConverter
with its TypePrecedence
set to TYPE_ID
.
See Serialization, Deserialization, and Message Conversion for more information.
Due to some limitations in the way Spring resolves method arguments, a default @KafkaHandler cannot receive discrete headers; it must use the ConsumerRecordMetadata as discussed in Consumer Record Metadata.
|
For example:
@KafkaHandler(isDefault = true)
public void listenDefault(Object object, @Header(KafkaHeaders.RECEIVED_TOPIC) String topic) {
...
}
This won’t work if the object is a String
; the topic
parameter will also get a reference to object
.
If you need metadata about the record in a default method, use this:
@KafkaHandler(isDefault = true)
void listen(Object in, @Header(KafkaHeaders.RECORD_METADATA) ConsumerRecordMetadata meta) {
String topic = meta.topic();
...
}
@KafkaListener
Attribute Modification
Starting with version 2.7.2, you can now programmatically modify annotation attributes before the container is created.
To do so, add one or more KafkaListenerAnnotationBeanPostProcessor.AnnotationEnhancer
to the application context.
AnnotationEnhancer
is a BiFunction<Map<String, Object>, AnnotatedElement, Map<String, Object>
and must return a map of attributes.
The attribute values can contain SpEL and/or property placeholders; the enhancer is called before any resolution is performed.
If more than one enhancer is present, and they implement Ordered
, they will be invoked in order.
AnnotationEnhancer bean definitions must be declared static because they are required very early in the application context’s lifecycle.
|
An example follows:
@Bean
public static AnnotationEnhancer groupIdEnhancer() {
return (attrs, element) -> {
attrs.put("groupId", attrs.get("id") + "." + (element instanceof Class
? ((Class<?>) element).getSimpleName()
: ((Method) element).getDeclaringClass().getSimpleName()
+ "." + ((Method) element).getName()));
return attrs;
};
}
@KafkaListener
Lifecycle Management
The listener containers created for @KafkaListener
annotations are not beans in the application context.
Instead, they are registered with an infrastructure bean of type KafkaListenerEndpointRegistry
.
This bean is automatically declared by the framework and manages the containers' lifecycles; it will auto-start any containers that have autoStartup
set to true
.
All containers created by all container factories must be in the same phase
.
See Listener Container Auto Startup for more information.
You can manage the lifecycle programmatically by using the registry.
Starting or stopping the registry will start or stop all the registered containers.
Alternatively, you can get a reference to an individual container by using its id
attribute.
You can set autoStartup
on the annotation, which overrides the default setting configured into the container factory.
You can get a reference to the bean from the application context, such as auto-wiring, to manage its registered containers.
The following examples show how to do so:
@KafkaListener(id = "myContainer", topics = "myTopic", autoStartup = "false")
public void listen(...) { ... }
@Autowired
private KafkaListenerEndpointRegistry registry;
...
this.registry.getListenerContainer("myContainer").start();
...
The registry only maintains the life cycle of containers it manages; containers declared as beans are not managed by the registry and can be obtained from the application context.
A collection of managed containers can be obtained by calling the registry’s getListenerContainers()
method.
Version 2.2.5 added a convenience method getAllListenerContainers()
, which returns a collection of all containers, including those managed by the registry and those declared as beans.
The collection returned will include any prototype beans that have been initialized, but it will not initialize any lazy bean declarations.
@KafkaListener
@Payload
Validation
Starting with version 2.2, it is now easier to add a Validator
to validate @KafkaListener
@Payload
arguments.
Previously, you had to configure a custom DefaultMessageHandlerMethodFactory
and add it to the registrar.
Now, you can add the validator to the registrar itself.
The following code shows how to do so:
@Configuration
@EnableKafka
public class Config implements KafkaListenerConfigurer {
...
@Override
public void configureKafkaListeners(KafkaListenerEndpointRegistrar registrar) {
registrar.setValidator(new MyValidator());
}
}
When you use Spring Boot with the validation starter, a LocalValidatorFactoryBean is auto-configured, as the following example shows:
|
@Configuration
@EnableKafka
public class Config implements KafkaListenerConfigurer {
@Autowired
private LocalValidatorFactoryBean validator;
...
@Override
public void configureKafkaListeners(KafkaListenerEndpointRegistrar registrar) {
registrar.setValidator(this.validator);
}
}
The following examples show how to validate:
public static class ValidatedClass {
@Max(10)
private int bar;
public int getBar() {
return this.bar;
}
public void setBar(int bar) {
this.bar = bar;
}
}
@KafkaListener(id="validated", topics = "annotated35", errorHandler = "validationErrorHandler",
containerFactory = "kafkaJsonListenerContainerFactory")
public void validatedListener(@Payload @Valid ValidatedClass val) {
...
}
@Bean
public KafkaListenerErrorHandler validationErrorHandler() {
return (m, e) -> {
...
};
}
Starting with version 2.5.11, validation now works on payloads for @KafkaHandler
methods in a class-level listener.
See @KafkaListener
on a Class.
Rebalancing Listeners
ContainerProperties
has a property called consumerRebalanceListener
, which takes an implementation of the Kafka client’s ConsumerRebalanceListener
interface.
If this property is not provided, the container configures a logging listener that logs rebalance events at the INFO
level.
The framework also adds a sub-interface ConsumerAwareRebalanceListener
.
The following listing shows the ConsumerAwareRebalanceListener
interface definition:
public interface ConsumerAwareRebalanceListener extends ConsumerRebalanceListener {
void onPartitionsRevokedBeforeCommit(Consumer<?, ?> consumer, Collection<TopicPartition> partitions);
void onPartitionsRevokedAfterCommit(Consumer<?, ?> consumer, Collection<TopicPartition> partitions);
void onPartitionsAssigned(Consumer<?, ?> consumer, Collection<TopicPartition> partitions);
void onPartitionsLost(Consumer<?, ?> consumer, Collection<TopicPartition> partitions);
}
Notice that there are two callbacks when partitions are revoked. The first is called immediately. The second is called after any pending offsets are committed. This is useful if you wish to maintain offsets in some external repository, as the following example shows:
containerProperties.setConsumerRebalanceListener(new ConsumerAwareRebalanceListener() {
@Override
public void onPartitionsRevokedBeforeCommit(Consumer<?, ?> consumer, Collection<TopicPartition> partitions) {
// acknowledge any pending Acknowledgments (if using manual acks)
}
@Override
public void onPartitionsRevokedAfterCommit(Consumer<?, ?> consumer, Collection<TopicPartition> partitions) {
// ...
store(consumer.position(partition));
// ...
}
@Override
public void onPartitionsAssigned(Collection<TopicPartition> partitions) {
// ...
consumer.seek(partition, offsetTracker.getOffset() + 1);
// ...
}
});
Starting with version 2.4, a new method onPartitionsLost() has been added (similar to a method with the same name in ConsumerRebalanceLister ).
The default implementation on ConsumerRebalanceLister simply calls onPartionsRevoked .
The default implementation on ConsumerAwareRebalanceListener does nothing.
When supplying the listener container with a custom listener (of either type), it is important that your implementation not call onPartitionsRevoked from onPartitionsLost .
If you implement ConsumerRebalanceListener you should override the default method.
This is because the listener container will call its own onPartitionsRevoked from its implementation of onPartitionsLost after calling the method on your implementation.
If you implementation delegates to the default behavior, onPartitionsRevoked will be called twice each time the Consumer calls that method on the container’s listener.
|
Forwarding Listener Results using @SendTo
Starting with version 2.0, if you also annotate a @KafkaListener
with a @SendTo
annotation and the method invocation returns a result, the result is forwarded to the topic specified by the @SendTo
.
The @SendTo
value can have several forms:
-
@SendTo("someTopic")
routes to the literal topic -
@SendTo("#{someExpression}")
routes to the topic determined by evaluating the expression once during application context initialization. -
@SendTo("!{someExpression}")
routes to the topic determined by evaluating the expression at runtime. The#root
object for the evaluation has three properties:-
request
: The inboundConsumerRecord
(orConsumerRecords
object for a batch listener)) -
source
: Theorg.springframework.messaging.Message<?>
converted from therequest
. -
result
: The method return result.
-
-
@SendTo
(no properties): This is treated as!{source.headers['kafka_replyTopic']}
(since version 2.1.3).
Starting with versions 2.1.11 and 2.2.1, property placeholders are resolved within @SendTo
values.
The result of the expression evaluation must be a String
that represents the topic name.
The following examples show the various ways to use @SendTo
:
@KafkaListener(topics = "annotated21")
@SendTo("!{request.value()}") // runtime SpEL
public String replyingListener(String in) {
...
}
@KafkaListener(topics = "${some.property:annotated22}")
@SendTo("#{myBean.replyTopic}") // config time SpEL
public Collection<String> replyingBatchListener(List<String> in) {
...
}
@KafkaListener(topics = "annotated23", errorHandler = "replyErrorHandler")
@SendTo("annotated23reply") // static reply topic definition
public String replyingListenerWithErrorHandler(String in) {
...
}
...
@KafkaListener(topics = "annotated25")
@SendTo("annotated25reply1")
public class MultiListenerSendTo {
@KafkaHandler
public String foo(String in) {
...
}
@KafkaHandler
@SendTo("!{'annotated25reply2'}")
public String bar(@Payload(required = false) KafkaNull nul,
@Header(KafkaHeaders.RECEIVED_MESSAGE_KEY) int key) {
...
}
}
In order to support @SendTo , the listener container factory must be provided with a KafkaTemplate (in its replyTemplate property), which is used to send the reply.
This should be a KafkaTemplate and not a ReplyingKafkaTemplate which is used on the client-side for request/reply processing.
When using Spring Boot, boot will auto-configure the template into the factory; when configuring your own factory, it must be set as shown in the examples below.
|
Starting with version 2.2, you can add a ReplyHeadersConfigurer
to the listener container factory.
This is consulted to determine which headers you want to set in the reply message.
The following example shows how to add a ReplyHeadersConfigurer
:
@Bean
public ConcurrentKafkaListenerContainerFactory<Integer, String> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(cf());
factory.setReplyTemplate(template());
factory.setReplyHeadersConfigurer((k, v) -> k.equals("cat"));
return factory;
}
You can also add more headers if you wish. The following example shows how to do so:
@Bean
public ConcurrentKafkaListenerContainerFactory<Integer, String> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(cf());
factory.setReplyTemplate(template());
factory.setReplyHeadersConfigurer(new ReplyHeadersConfigurer() {
@Override
public boolean shouldCopy(String headerName, Object headerValue) {
return false;
}
@Override
public Map<String, Object> additionalHeaders() {
return Collections.singletonMap("qux", "fiz");
}
});
return factory;
}
When you use @SendTo
, you must configure the ConcurrentKafkaListenerContainerFactory
with a KafkaTemplate
in its replyTemplate
property to perform the send.
Unless you use request/reply semantics only the simple send(topic, value) method is used, so you may wish to create a subclass to generate the partition or key.
The following example shows how to do so:
|
@Bean
public KafkaTemplate<String, String> myReplyingTemplate() {
return new KafkaTemplate<Integer, String>(producerFactory()) {
@Override
public ListenableFuture<SendResult<String, String>> send(String topic, String data) {
return super.send(topic, partitionForData(data), keyForData(data), data);
}
...
};
}
If the listener method returns
|
When using request/reply semantics, the target partition can be requested by the sender.
You can annotate a
See Handling Exceptions for more information. |
If a listener method returns an Iterable , by default a record for each element as the value is sent.
Starting with version 2.3.5, set the splitIterables property on @KafkaListener to false and the entire result will be sent as the value of a single ProducerRecord .
This requires a suitable serializer in the reply template’s producer configuration.
However, if the reply is Iterable<Message<?>> the property is ignored and each message is sent separately.
|
Filtering Messages
In certain scenarios, such as rebalancing, a message that has already been processed may be redelivered. The framework cannot know whether such a message has been processed or not. That is an application-level function. This is known as the Idempotent Receiver pattern and Spring Integration provides an implementation of it.
The Spring for Apache Kafka project also provides some assistance by means of the FilteringMessageListenerAdapter
class, which can wrap your MessageListener
.
This class takes an implementation of RecordFilterStrategy
in which you implement the filter
method to signal that a message is a duplicate and should be discarded.
This has an additional property called ackDiscarded
, which indicates whether the adapter should acknowledge the discarded record.
It is false
by default.
When you use @KafkaListener
, set the RecordFilterStrategy
(and optionally ackDiscarded
) on the container factory so that the listener is wrapped in the appropriate filtering adapter.
In addition, a FilteringBatchMessageListenerAdapter
is provided, for when you use a batch message listener.
The FilteringBatchMessageListenerAdapter is ignored if your @KafkaListener receives a ConsumerRecords<?, ?> instead of List<ConsumerRecord<?, ?>> , because ConsumerRecords is immutable.
|
Retrying Deliveries
See the DefaultErrorHandler
in Handling Exceptions.
Starting @KafkaListener
s in Sequence
A common use case is to start a listener after another listener has consumed all the records in a topic.
For example, you may want to load the contents of one or more compacted topics into memory before processing records from other topics.
Starting with version 2.7.3, a new component ContainerGroupSequencer
has been introduced.
It uses the @KafkaListener
containerGroup
property to group containers together and start the containers in the next group, when all the containers in the current group have gone idle.
It is best illustrated with an example.
@KafkaListener(id = "listen1", topics = "topic1", containerGroup = "g1", concurrency = "2")
public void listen1(String in) {
}
@KafkaListener(id = "listen2", topics = "topic2", containerGroup = "g1", concurrency = "2")
public void listen2(String in) {
}
@KafkaListener(id = "listen3", topics = "topic3", containerGroup = "g2", concurrency = "2")
public void listen3(String in) {
}
@KafkaListener(id = "listen4", topics = "topic4", containerGroup = "g2", concurrency = "2")
public void listen4(String in) {
}
@Bean
ContainerGroupSequencer sequencer(KafkaListenerEndpointRegistry registry) {
return new ContainerGroupSequencer(registry, 5000, "g1", "g2");
}
Here, we have 4 listeners in two groups, g1
and g2
.
During application context initialization, the sequencer, sets the autoStartup
property of all the containers in the provided groups to false
.
It also sets the idleEventInterval
for any containers (that do not already have one set) to the supplied value (5000ms in this case).
Then, when the sequencer is started by the application context, the containers in the first group are started.
As ListenerContainerIdleEvent
s are received, each individual child container in each container is stopped.
When all child containers in a ConcurrentMessageListenerContainer
are stopped, the parent container is stopped.
When all containers in a group have been stopped, the containers in the next group are started.
There is no limit to the number of groups or containers in a group.
By default, the containers in the final group (g2
above) are not stopped when they go idle.
To modify that behavior, set stopLastGroupWhenIdle
to true
on the sequencer.
As an aside; previously, containers in each group were added to a bean of type Collection<MessageListenerContainer>
with the bean name being the containerGroup
.
These collections are now deprecated in favor of beans of type ContainerGroup
with a bean name that is the group name, suffixed with .group
; in the example above, there would be 2 beans g1.group
and g2.group
.
The Collection
beans will be removed in a future release.
Using KafkaTemplate
to Receive
This section covers how to use KafkaTemplate
to receive messages.
Starting with version 2.8, the template has four receive()
methods:
ConsumerRecord<K, V> receive(String topic, int partition, long offset);
ConsumerRecord<K, V> receive(String topic, int partition, long offset, Duration pollTimeout);
ConsumerRecords<K, V> receive(Collection<TopicPartitionOffset> requested);
ConsumerRecords<K, V> receive(Collection<TopicPartitionOffset> requested, Duration pollTimeout);
As you can see, you need to know the partition and offset of the record(s) you need to retrieve; a new Consumer
is created (and closed) for each operation.
With the last two methods, each record is retrieved individually and the results assembled into a ConsumerRecords
object.
When creating the TopicPartitionOffset
s for the request, only positive, absolute offsets are supported.
4.1.5. Listener Container Properties
Property | Default | Description |
---|---|---|
1 |
The number of records before committing pending offsets when the |
|
|
A chain of |
|
BATCH |
Controls how often offsets are committed - see Committing Offsets. |
|
|
[DEPRECATED in favor of |
|
5000 |
The time in milliseconds after which pending offsets are committed when the |
|
LATEST_ONLY _NO_TX |
Whether or not to commit the initial position on assignment; by default, the initial offset will only be committed if the |
|
|
When not null, a |
|
(empty string) |
A prefix for the |
|
false |
Set to |
|
false |
Set to |
|
|
When present and |
|
DEBUG |
The logging level for logs pertaining to committing offsets. |
|
|
A rebalance listener; see Rebalancing Listeners. |
|
30s |
The time to wait for the consumer to start before logging an error; this might happen if, say, you use a task executor with insufficient threads. |
|
|
A task executor to run the consumer threads.
The default executor creates threads named |
|
|
||
|
Exactly Once Semantics mode; see Exactly Once Semantics. |
|
|
When consuming records produced by a transactional producer, and the consumer is positioned at the end of a partition, the lag can incorrectly be reported as greater than zero, due to the pseudo record used to indicate transaction commit/rollback and, possibly, the presence of rolled-back records.
This does not functionally affect the consumer but some users have expressed concern that the "lag" is non-zero.
Set this property to |
|
|
Overrides the consumer |
|
5.0 |
Multiplier for |
|
0 |
Used to slow down deliveries by sleeping the thread between polls.
The time to process a batch of records plus this value must be less than the |
|
|
When set, enables publication of |
|
|
When set, enables publication of |
|
None |
Used to override any arbitrary consumer properties configured on the consumer factory. |
|
|
Set to true to log at INFO level all container properties. |
|
|
The message listener. |
|
|
Whether or not to maintain Micrometer timers for the consumer threads. |
|
|
When true prevents the container from starting if the confifgured topic(s) are not present on the broker. |
|
30s |
How often to check the state of the consumer threads for |
|
3.0 |
Multiplied by |
|
|
Set to false to log the complete consumer record (in error, debug logs etc) instead of just |
|
5000 |
The timeout passed into |
|
|
A scheduler on which to run the consumer monitor task. |
|
10000 |
The maximum time in ms to block the |
|
|
Stop the listener container if a |
|
|
When the container is stopped, stop processing after the current record instead of after processing all the records from the previous poll. |
|
See desc. |
When using a batch listener, if this is |
|
|
The timeout to use when |
|
|
Whether to use sync or async commits for offsets; see |
|
n/a |
The configured topics, topic pattern or explicitly assigned topics/partitions.
Mutually exclusive; at least one must be provided; enforced by |
|
|
See Transactions. |
Property | Default | Description |
---|---|---|
|
An |
|
application context |
The event publisher. |
|
See desc. |
Deprecated - see |
|
|
Set a |
|
bean name |
The bean name of the container; suffixed with |
|
See desc. |
|
|
|
The container properties instance. |
|
See desc. |
Deprecated - see |
|
See desc. |
Deprecated - see |
|
See desc. |
The |
|
|
Determines whether the |
|
See desc. |
The bean name for user-configured containers or the |
|
(read only) |
True if a consumer pause has been requested. |
|
|
Set a |
|
30s |
When the |
Property | Default | Description |
---|---|---|
(read only) |
The partitions currently assigned to this container (explicitly or not). |
|
(read only) |
The partitions currently assigned to this container (explicitly or not). |
|
|
Used by the concurrent container to give each child container’s consumer a unique |
|
n/a |
True if pause has been requested and the consumer has actually paused. |
Property | Default | Description |
---|---|---|
|
Set to false to suppress adding a suffix to the |
|
(read only) |
The aggregate of partitions currently assigned to this container’s child |
|
(read only) |
The partitions currently assigned to this container’s child |
|
1 |
The number of child |
|
n/a |
True if pause has been requested and all child containers' consumer has actually paused. |
|
n/a |
A reference to all child |
4.1.6. Application Events
The following Spring application events are published by listener containers and their consumers:
-
ConsumerStartingEvent
- published when a consumer thread is first started, before it starts polling. -
ConsumerStartedEvent
- published when a consumer is about to start polling. -
ConsumerFailedToStartEvent
- published if noConsumerStartingEvent
is published within theconsumerStartTimeout
container property. This event might signal that the configured task executor has insufficient threads to support the containers it is used in and their concurrency. An error message is also logged when this condition occurs. -
ListenerContainerIdleEvent
: published when no messages have been received inidleInterval
(if configured). -
ListenerContainerNoLongerIdleEvent
: published when a record is consumed after previously publishing aListenerContainerIdleEvent
. -
ListenerContainerPartitionIdleEvent
: published when no messages have been received from that partition inidlePartitionEventInterval
(if configured). -
ListenerContainerPartitionNoLongerIdleEvent
: published when a record is consumed from a partition that has previously published aListenerContainerPartitionIdleEvent
. -
NonResponsiveConsumerEvent
: published when the consumer appears to be blocked in thepoll
method. -
ConsumerPartitionPausedEvent
: published by each consumer when a partition is paused. -
ConsumerPartitionResumedEvent
: published by each consumer when a partition is resumed. -
ConsumerPausedEvent
: published by each consumer when the container is paused. -
ConsumerResumedEvent
: published by each consumer when the container is resumed. -
ConsumerStoppingEvent
: published by each consumer just before stopping. -
ConsumerStoppedEvent
: published after the consumer is closed. See Thread Safety. -
ContainerStoppedEvent
: published when all consumers have stopped.
By default, the application context’s event multicaster invokes event listeners on the calling thread.
If you change the multicaster to use an async executor, you must not invoke any Consumer methods when the event contains a reference to the consumer.
|
The ListenerContainerIdleEvent
has the following properties:
-
source
: The listener container instance that published the event. -
container
: The listener container or the parent listener container, if the source container is a child. -
id
: The listener ID (or container bean name). -
idleTime
: The time the container had been idle when the event was published. -
topicPartitions
: The topics and partitions that the container was assigned at the time the event was generated. -
consumer
: A reference to the KafkaConsumer
object. For example, if the consumer’spause()
method was previously called, it canresume()
when the event is received. -
paused
: Whether the container is currently paused. See Pausing and Resuming Listener Containers for more information.
The ListenerContainerNoLongerIdleEvent
has the same properties, except idleTime
and paused
.
The ListenerContainerPartitionIdleEvent
has the following properties:
-
source
: The listener container instance that published the event. -
container
: The listener container or the parent listener container, if the source container is a child. -
id
: The listener ID (or container bean name). -
idleTime
: The time partition consumption had been idle when the event was published. -
topicPartition
: The topic and partition that triggered the event. -
consumer
: A reference to the KafkaConsumer
object. For example, if the consumer’spause()
method was previously called, it canresume()
when the event is received. -
paused
: Whether that partition consumption is currently paused for that consumer. See Pausing and Resuming Listener Containers for more information.
The ListenerContainerPartitionNoLongerIdleEvent
has the same properties, except idleTime
and paused
.
The NonResponsiveConsumerEvent
has the following properties:
-
source
: The listener container instance that published the event. -
container
: The listener container or the parent listener container, if the source container is a child. -
id
: The listener ID (or container bean name). -
timeSinceLastPoll
: The time just before the container last calledpoll()
. -
topicPartitions
: The topics and partitions that the container was assigned at the time the event was generated. -
consumer
: A reference to the KafkaConsumer
object. For example, if the consumer’spause()
method was previously called, it canresume()
when the event is received. -
paused
: Whether the container is currently paused. See Pausing and Resuming Listener Containers for more information.
The ConsumerPausedEvent
, ConsumerResumedEvent
, and ConsumerStopping
events have the following properties:
-
source
: The listener container instance that published the event. -
container
: The listener container or the parent listener container, if the source container is a child. -
partitions
: TheTopicPartition
instances involved.
The ConsumerPartitionPausedEvent
, ConsumerPartitionResumedEvent
events have the following properties:
-
source
: The listener container instance that published the event. -
container
: The listener container or the parent listener container, if the source container is a child. -
partition
: TheTopicPartition
instance involved.
The ConsumerStartingEvent
, ConsumerStartingEvent
, ConsumerFailedToStartEvent
, ConsumerStoppedEvent
and ContainerStoppedEvent
events have the following properties:
-
source
: The listener container instance that published the event. -
container
: The listener container or the parent listener container, if the source container is a child.
All containers (whether a child or a parent) publish ContainerStoppedEvent
.
For a parent container, the source and container properties are identical.
In addition, the ConsumerStoppedEvent
has the following additional property:
-
reason
-
NORMAL
- the consumer stopped normally (container was stopped). -
ERROR
- ajava.lang.Error
was thrown. -
FENCED
- the transactional producer was fenced and thestopContainerWhenFenced
container property istrue
. -
AUTH
- anAuthenticationException
orAuthorizationException
was thrown and theauthExceptionRetryInterval
is not configured. -
NO_OFFSET
- there is no offset for a partition and theauto.offset.reset
policy isnone
.
-
You can use this event to restart the container after such a condition:
if (event.getReason.equals(Reason.FENCED)) {
event.getSource(MessageListenerContainer.class).start();
}
Detecting Idle and Non-Responsive Consumers
While efficient, one problem with asynchronous consumers is detecting when they are idle. You might want to take some action if no messages arrive for some period of time.
You can configure the listener container to publish a ListenerContainerIdleEvent
when some time passes with no message delivery.
While the container is idle, an event is published every idleEventInterval
milliseconds.
To configure this feature, set the idleEventInterval
on the container.
The following example shows how to do so:
@Bean
public KafkaMessageListenerContainer(ConsumerFactory<String, String> consumerFactory) {
ContainerProperties containerProps = new ContainerProperties("topic1", "topic2");
...
containerProps.setIdleEventInterval(60000L);
...
KafkaMessageListenerContainer<String, String> container = new KafKaMessageListenerContainer<>(...);
return container;
}
The following example shows how to set the idleEventInterval
for a @KafkaListener
:
@Bean
public ConcurrentKafkaListenerContainerFactory kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<String, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
...
factory.getContainerProperties().setIdleEventInterval(60000L);
...
return factory;
}
In each of these cases, an event is published once per minute while the container is idle.
In addition, if the broker is unreachable, the consumer poll()
method does not exit, so no messages are received and idle events cannot be generated.
To solve this issue, the container publishes a NonResponsiveConsumerEvent
if a poll does not return within 3x
the pollTimeout
property.
By default, this check is performed once every 30 seconds in each container.
You can modify this behavior by setting the monitorInterval
(default 30 seconds) and noPollThreshold
(default 3.0) properties in the ContainerProperties
when configuring the listener container.
The noPollThreshold
should be greater than 1.0
to avoid getting spurious events due to a race condition.
Receiving such an event lets you stop the containers, thus waking the consumer so that it can stop.
Starting with version 2.6.2, if a container has published a ListenerContainerIdleEvent
, it will publish a ListenerContainerNoLongerIdleEvent
when a record is subsequently received.
Event Consumption
You can capture these events by implementing ApplicationListener
— either a general listener or one narrowed to only receive this specific event.
You can also use @EventListener
, introduced in Spring Framework 4.2.
The next example combines @KafkaListener
and @EventListener
into a single class.
You should understand that the application listener gets events for all containers, so you may need to check the listener ID if you want to take specific action based on which container is idle.
You can also use the @EventListener
condition
for this purpose.
See Application Events for information about event properties.
The event is normally published on the consumer thread, so it is safe to interact with the Consumer
object.
The following example uses both @KafkaListener
and @EventListener
:
public class Listener {
@KafkaListener(id = "qux", topics = "annotated")
public void listen4(@Payload String foo, Acknowledgment ack) {
...
}
@EventListener(condition = "event.listenerId.startsWith('qux-')")
public void eventHandler(ListenerContainerIdleEvent event) {
...
}
}
Event listeners see events for all containers.
Consequently, in the preceding example, we narrow the events received based on the listener ID.
Since containers created for the @KafkaListener support concurrency, the actual containers are named id-n where the n is a unique value for each instance to support the concurrency.
That is why we use startsWith in the condition.
|
If you wish to use the idle event to stop the lister container, you should not call container.stop() on the thread that calls the listener.
Doing so causes delays and unnecessary log messages.
Instead, you should hand off the event to a different thread that can then stop the container.
Also, you should not stop() the container instance if it is a child container.
You should stop the concurrent container instead.
|
Current Positions when Idle
Note that you can obtain the current positions when idle is detected by implementing ConsumerSeekAware
in your listener.
See onIdleContainer()
in Seeking to a Specific Offset.
4.1.7. Topic/Partition Initial Offset
There are several ways to set the initial offset for a partition.
When manually assigning partitions, you can set the initial offset (if desired) in the configured TopicPartitionOffset
arguments (see Message Listener Containers).
You can also seek to a specific offset at any time.
When you use group management where the broker assigns partitions:
-
For a new
group.id
, the initial offset is determined by theauto.offset.reset
consumer property (earliest
orlatest
). -
For an existing group ID, the initial offset is the current offset for that group ID. You can, however, seek to a specific offset during initialization (or at any time thereafter).
4.1.8. Seeking to a Specific Offset
In order to seek, your listener must implement ConsumerSeekAware
, which has the following methods:
void registerSeekCallback(ConsumerSeekCallback callback);
void onPartitionsAssigned(Map<TopicPartition, Long> assignments, ConsumerSeekCallback callback);
void onPartitionsRevoked(Collection<TopicPartition> partitions)
void onIdleContainer(Map<TopicPartition, Long> assignments, ConsumerSeekCallback callback);
The registerSeekCallback
is called when the container is started and whenever partitions are assigned.
You should use this callback when seeking at some arbitrary time after initialization.
You should save a reference to the callback.
If you use the same listener in multiple containers (or in a ConcurrentMessageListenerContainer
), you should store the callback in a ThreadLocal
or some other structure keyed by the listener Thread
.
When using group management, onPartitionsAssigned
is called when partitions are assigned.
You can use this method, for example, for setting initial offsets for the partitions, by calling the callback.
You can also use this method to associate this thread’s callback with the assigned partitions (see the example below).
You must use the callback argument, not the one passed into registerSeekCallback
.
Starting with version 2.5.5, this method is called, even when using manual partition assignment.
onPartitionsRevoked
is called when the container is stopped or Kafka revokes assignments.
You should discard this thread’s callback and remove any associations to the revoked partitions.
The callback has the following methods:
void seek(String topic, int partition, long offset);
void seekToBeginning(String topic, int partition);
void seekToBeginning(Collection=<TopicPartitions> partitions);
void seekToEnd(String topic, int partition);
void seekToEnd(Collection=<TopicPartitions> partitions);
void seekRelative(String topic, int partition, long offset, boolean toCurrent);
void seekToTimestamp(String topic, int partition, long timestamp);
void seekToTimestamp(Collection<TopicPartition> topicPartitions, long timestamp);
seekRelative
was added in version 2.3, to perform relative seeks.
-
offset
negative andtoCurrent
false
- seek relative to the end of the partition. -
offset
positive andtoCurrent
false
- seek relative to the beginning of the partition. -
offset
negative andtoCurrent
true
- seek relative to the current position (rewind). -
offset
positive andtoCurrent
true
- seek relative to the current position (fast forward).
The seekToTimestamp
methods were also added in version 2.3.
When seeking to the same timestamp for multiple partitions in the onIdleContainer or onPartitionsAssigned methods, the second method is preferred because it is more efficient to find the offsets for the timestamps in a single call to the consumer’s offsetsForTimes method.
When called from other locations, the container will gather all timestamp seek requests and make one call to offsetsForTimes .
|
You can also perform seek operations from onIdleContainer()
when an idle container is detected.
See Detecting Idle and Non-Responsive Consumers for how to enable idle container detection.
The seekToBeginning method that accepts a collection is useful, for example, when processing a compacted topic and you wish to seek to the beginning every time the application is started:
|
public class MyListener implements ConsumerSeekAware {
...
@Override
public void onPartitionsAssigned(Map<TopicPartition, Long> assignments, ConsumerSeekCallback callback) {
callback.seekToBeginning(assignments.keySet());
}
}
To arbitrarily seek at runtime, use the callback reference from the registerSeekCallback
for the appropriate thread.
Here is a trivial Spring Boot application that demonstrates how to use the callback; it sends 10 records to the topic; hitting <Enter>
in the console causes all partitions to seek to the beginning.
@SpringBootApplication
public class SeekExampleApplication {
public static void main(String[] args) {
SpringApplication.run(SeekExampleApplication.class, args);
}
@Bean
public ApplicationRunner runner(Listener listener, KafkaTemplate<String, String> template) {
return args -> {
IntStream.range(0, 10).forEach(i -> template.send(
new ProducerRecord<>("seekExample", i % 3, "foo", "bar")));
while (true) {
System.in.read();
listener.seekToStart();
}
};
}
@Bean
public NewTopic topic() {
return new NewTopic("seekExample", 3, (short) 1);
}
}
@Component
class Listener implements ConsumerSeekAware {
private static final Logger logger = LoggerFactory.getLogger(Listener.class);
private final ThreadLocal<ConsumerSeekCallback> callbackForThread = new ThreadLocal<>();
private final Map<TopicPartition, ConsumerSeekCallback> callbacks = new ConcurrentHashMap<>();
@Override
public void registerSeekCallback(ConsumerSeekCallback callback) {
this.callbackForThread.set(callback);
}
@Override
public void onPartitionsAssigned(Map<TopicPartition, Long> assignments, ConsumerSeekCallback callback) {
assignments.keySet().forEach(tp -> this.callbacks.put(tp, this.callbackForThread.get()));
}
@Override
public void onPartitionsRevoked(Collection<TopicPartition> partitions) {
partitions.forEach(tp -> this.callbacks.remove(tp));
this.callbackForThread.remove();
}
@Override
public void onIdleContainer(Map<TopicPartition, Long> assignments, ConsumerSeekCallback callback) {
}
@KafkaListener(id = "seekExample", topics = "seekExample", concurrency = "3")
public void listen(ConsumerRecord<String, String> in) {
logger.info(in.toString());
}
public void seekToStart() {
this.callbacks.forEach((tp, callback) -> callback.seekToBeginning(tp.topic(), tp.partition()));
}
}
To make things simpler, version 2.3 added the AbstractConsumerSeekAware
class, which keeps track of which callback is to be used for a topic/partition.
The following example shows how to seek to the last record processed, in each partition, each time the container goes idle.
It also has methods that allow arbitrary external calls to rewind partitions by one record.
public class SeekToLastOnIdleListener extends AbstractConsumerSeekAware {
@KafkaListener(id = "seekOnIdle", topics = "seekOnIdle")
public void listen(String in) {
...
}
@Override
public void onIdleContainer(Map<org.apache.kafka.common.TopicPartition, Long> assignments,
ConsumerSeekCallback callback) {
assignments.keySet().forEach(tp -> callback.seekRelative(tp.topic(), tp.partition(), -1, true));
}
/**
* Rewind all partitions one record.
*/
public void rewindAllOneRecord() {
getSeekCallbacks()
.forEach((tp, callback) ->
callback.seekRelative(tp.topic(), tp.partition(), -1, true));
}
/**
* Rewind one partition one record.
*/
public void rewindOnePartitionOneRecord(String topic, int partition) {
getSeekCallbackFor(new org.apache.kafka.common.TopicPartition(topic, partition))
.seekRelative(topic, partition, -1, true);
}
}
Version 2.6 added convenience methods to the abstract class:
-
seekToBeginning()
- seeks all assigned partitions to the beginning -
seekToEnd()
- seeks all assigned partitions to the end -
seekToTimestamp(long time)
- seeks all assigned partitions to the offset represented by that timestamp.
Example:
public class MyListener extends AbstractConsumerSeekAware {
@KafkaListener(...)
void listn(...) {
...
}
}
public class SomeOtherBean {
MyListener listener;
...
void someMethod() {
this.listener.seekToTimestamp(System.currentTimeMillis - 60_000);
}
}
4.1.9. Container factory
As discussed in @KafkaListener
Annotation, a ConcurrentKafkaListenerContainerFactory
is used to create containers for annotated methods.
Starting with version 2.2, you can use the same factory to create any ConcurrentMessageListenerContainer
.
This might be useful if you want to create several containers with similar properties or you wish to use some externally configured factory, such as the one provided by Spring Boot auto-configuration.
Once the container is created, you can further modify its properties, many of which are set by using container.getContainerProperties()
.
The following example configures a ConcurrentMessageListenerContainer
:
@Bean
public ConcurrentMessageListenerContainer<String, String>(
ConcurrentKafkaListenerContainerFactory<String, String> factory) {
ConcurrentMessageListenerContainer<String, String> container =
factory.createContainer("topic1", "topic2");
container.setMessageListener(m -> { ... } );
return container;
}
Containers created this way are not added to the endpoint registry.
They should be created as @Bean definitions so that they are registered with the application context.
|
Starting with version 2.3.4, you can add a ContainerCustomizer
to the factory to further configure each container after it has been created and configured.
@Bean
public KafkaListenerContainerFactory<?, ?> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
...
factory.setContainerCustomizer(container -> { /* customize the container */ });
return factory;
}
4.1.10. Thread Safety
When using a concurrent message listener container, a single listener instance is invoked on all consumer threads. Listeners, therefore, need to be thread-safe, and it is preferable to use stateless listeners. If it is not possible to make your listener thread-safe or adding synchronization would significantly reduce the benefit of adding concurrency, you can use one of a few techniques:
-
Use
n
containers withconcurrency=1
with a prototype scopedMessageListener
bean so that each container gets its own instance (this is not possible when using@KafkaListener
). -
Keep the state in
ThreadLocal<?>
instances. -
Have the singleton listener delegate to a bean that is declared in
SimpleThreadScope
(or a similar scope).
To facilitate cleaning up thread state (for the second and third items in the preceding list), starting with version 2.2, the listener container publishes a ConsumerStoppedEvent
when each thread exits.
You can consume these events with an ApplicationListener
or @EventListener
method to remove ThreadLocal<?>
instances or remove()
thread-scoped beans from the scope.
Note that SimpleThreadScope
does not destroy beans that have a destruction interface (such as DisposableBean
), so you should destroy()
the instance yourself.
By default, the application context’s event multicaster invokes event listeners on the calling thread. If you change the multicaster to use an async executor, thread cleanup is not effective. |
4.1.11. Monitoring
Monitoring Listener Performance
Starting with version 2.3, the listener container will automatically create and update Micrometer Timer
s for the listener, if Micrometer
is detected on the class path, and a single MeterRegistry
is present in the application context.
The timers can be disabled by setting the ContainerProperty
micrometerEnabled
to false
.
Two timers are maintained - one for successful calls to the listener and one for failures.
The timers are named spring.kafka.listener
and have the following tags:
-
name
: (container bean name) -
result
:success
orfailure
-
exception
:none
orListenerExecutionFailedException
You can add additional tags using the ContainerProperties
micrometerTags
property.
With the concurrent container, timers are created for each thread and the name tag is suffixed with -n where n is 0 to concurrency-1 .
|
Monitoring KafkaTemplate Performance
Starting with version 2.5, the template will automatically create and update Micrometer Timer
s for send operations, if Micrometer
is detected on the class path, and a single MeterRegistry
is present in the application context.
The timers can be disabled by setting the template’s micrometerEnabled
property to false
.
Two timers are maintained - one for successful calls to the listener and one for failures.
The timers are named spring.kafka.template
and have the following tags:
-
name
: (template bean name) -
result
:success
orfailure
-
exception
:none
or the exception class name for failures
You can add additional tags using the template’s micrometerTags
property.
Micrometer Native Metrics
Starting with version 2.5, the framework provides Factory Listeners to manage a Micrometer KafkaClientMetrics
instance whenever producers and consumers are created and closed.
To enable this feature, simply add the listeners to your producer and consumer factories:
@Bean
public ConsumerFactory<String, String> myConsumerFactory() {
Map<String, Object> configs = consumerConfigs();
...
DefaultKafkaConsumerFactory<String, String> cf = new DefaultKafkaConsumerFactory<>(configs);
...
cf.addListener(new MicrometerConsumerListener<String, String>(meterRegistry(),
Collections.singletonList(new ImmutableTag("customTag", "customTagValue"))));
...
return cf;
}
@Bean
public ProducerFactory<String, String> myProducerFactory() {
Map<String, Object> configs = producerConfigs();
configs.put(ProducerConfig.CLIENT_ID_CONFIG, "myClientId");
...
DefaultKafkaProducerFactory<String, String> pf = new DefaultKafkaProducerFactory<>(configs);
...
pf.addListener(new MicrometerProducerListener<String, String>(meterRegistry(),
Collections.singletonList(new ImmutableTag("customTag", "customTagValue"))));
...
return pf;
}
The consumer/producer id
passed to the listener is added to the meter’s tags with tag name spring.id
.
double count = this.meterRegistry.get("kafka.producer.node.incoming.byte.total")
.tag("customTag", "customTagValue")
.tag("spring.id", "myProducerFactory.myClientId-1")
.functionCounter()
.count()
A similar listener is provided for the StreamsBuilderFactoryBean
- see KafkaStreams Micrometer Support.
4.1.12. Transactions
This section describes how Spring for Apache Kafka supports transactions.
Overview
The 0.11.0.0 client library added support for transactions. Spring for Apache Kafka adds support in the following ways:
-
KafkaTransactionManager
: Used with normal Spring transaction support (@Transactional
,TransactionTemplate
etc). -
Transactional
KafkaMessageListenerContainer
-
Local transactions with
KafkaTemplate
-
Transaction synchronization with other transaction managers
Transactions are enabled by providing the DefaultKafkaProducerFactory
with a transactionIdPrefix
.
In that case, instead of managing a single shared Producer
, the factory maintains a cache of transactional producers.
When the user calls close()
on a producer, it is returned to the cache for reuse instead of actually being closed.
The transactional.id
property of each producer is transactionIdPrefix
+ n
, where n
starts with 0
and is incremented for each new producer, unless the transaction is started by a listener container with a record-based listener.
In that case, the transactional.id
is <transactionIdPrefix>.<group.id>.<topic>.<partition>
.
This is to properly support fencing zombies, as described here.
This new behavior was added in versions 1.3.7, 2.0.6, 2.1.10, and 2.2.0.
If you wish to revert to the previous behavior, you can set the producerPerConsumerPartition
property on the DefaultKafkaProducerFactory
to false
.
While transactions are supported with batch listeners, by default, zombie fencing is not supported because a batch may contain records from multiple topics or partitions.
However, starting with version 2.3.2, zombie fencing is supported if you set the container property subBatchPerPartition to true.
In that case, the batch listener is invoked once per partition received from the last poll, as if each poll only returned records for a single partition.
This is true by default since version 2.5 when transactions are enabled with EOSMode.ALPHA ; set it to false if you are using transactions but are not concerned about zombie fencing.
Also see Exactly Once Semantics.
|
Also see transactionIdPrefix
.
With Spring Boot, it is only necessary to set the spring.kafka.producer.transaction-id-prefix
property - Boot will automatically configure a KafkaTransactionManager
bean and wire it into the listener container.
Starting with version 2.5.8, you can now configure the maxAge property on the producer factory.
This is useful when using transactional producers that might lay idle for the broker’s transactional.id.expiration.ms .
With current kafka-clients , this can cause a ProducerFencedException without a rebalance.
By setting the maxAge to less than transactional.id.expiration.ms , the factory will refresh the producer if it is past it’s max age.
|
Using KafkaTransactionManager
The KafkaTransactionManager
is an implementation of Spring Framework’s PlatformTransactionManager
.
It is provided with a reference to the producer factory in its constructor.
If you provide a custom producer factory, it must support transactions.
See ProducerFactory.transactionCapable()
.
You can use the KafkaTransactionManager
with normal Spring transaction support (@Transactional
, TransactionTemplate
, and others).
If a transaction is active, any KafkaTemplate
operations performed within the scope of the transaction use the transaction’s Producer
.
The manager commits or rolls back the transaction, depending on success or failure.
You must configure the KafkaTemplate
to use the same ProducerFactory
as the transaction manager.
Transaction Synchronization
This section refers to producer-only transactions (transactions not started by a listener container); see Using Consumer-Initiated Transactions for information about chaining transactions when the container starts the transaction.
If you want to send records to kafka and perform some database updates, you can use normal Spring transaction management with, say, a DataSourceTransactionManager
.
@Transactional
public void process(List<Thing> things) {
things.forEach(thing -> this.kafkaTemplate.send("topic", thing));
updateDb(things);
}
The interceptor for the @Transactional
annotation starts the transaction and the KafkaTemplate
will synchronize a transaction with that transaction manager; each send will participate in that transaction.
When the method exits, the database transaction will commit followed by the Kafka transaction.
If you wish the commits to be performed in the reverse order (Kafka first), use nested @Transactional
methods, with the outer method configured to use the DataSourceTransactionManager
, and the inner method configured to use the KafkaTransactionManager
.
See Examples of Kafka Transactions with Other Transaction Managers for examples of an application that synchronizes JDBC and Kafka transactions in Kafka-first or DB-first configurations.
Starting with versions 2.5.17, 2.6.12, 2.7.9 and 2.8.0, if the commit fails on the synchronized transaction (after the primary transaction has committed), the exception will be thrown to the caller. Previously, this was silently ignored (logged at debug). Applications should take remedial action, if necessary, to compensate for the committed primary transaction. |
Using Consumer-Initiated Transactions
The ChainedKafkaTransactionManager
is now deprecated, since version 2.7; see the javadocs for its super class ChainedTransactionManager
for more information.
Instead, use a KafkaTransactionManager
in the container to start the Kafka transaction and annotate the listener method with @Transactional
to start the other transaction.
See Examples of Kafka Transactions with Other Transaction Managers for an example application that chains JDBC and Kafka transactions.
KafkaTemplate
Local Transactions
You can use the KafkaTemplate
to execute a series of operations within a local transaction.
The following example shows how to do so:
boolean result = template.executeInTransaction(t -> {
t.sendDefault("thing1", "thing2");
t.sendDefault("cat", "hat");
return true;
});
The argument in the callback is the template itself (this
).
If the callback exits normally, the transaction is committed.
If an exception is thrown, the transaction is rolled back.
If there is a KafkaTransactionManager (or synchronized) transaction in process, it is not used.
Instead, a new "nested" transaction is used.
|
transactionIdPrefix
As mentioned in the overview, the producer factory is configured with this property to build the producer transactional.id
property.
There is a dichotomy when specifying this property in that, when running multiple instances of the application with EOSMode.ALPHA
, it must be the same on all instances to satisfy fencing zombies (also mentioned in the overview) when producing records on a listener container thread.
However, when producing records using transactions that are not started by a listener container, the prefix has to be different on each instance.
Version 2.3, makes this simpler to configure, especially in a Spring Boot application.
In previous versions, you had to create two producer factories and KafkaTemplate
s - one for producing records on a listener container thread and one for stand-alone transactions started by kafkaTemplate.executeInTransaction()
or by a transaction interceptor on a @Transactional
method.
Now, you can override the factory’s transactionalIdPrefix
on the KafkaTemplate
and the KafkaTransactionManager
.
When using a transaction manager and template for a listener container, you would normally leave this to default to the producer factory’s property.
This value should be the same for all application instances when using EOSMode.ALPHA
.
With EOSMode.BETA
it is no longer necessary to use the same transactional.id
, even for consumer-initiated transactions; in fact, it must be unique on each instance the same as producer-initiated transactions.
For transactions started by the template (or the transaction manager for @Transaction
) you should set the property on the template and transaction manager respectively.
This property must have a different value on each application instance.
This problem (different rules for transactional.id
) has been eliminated when EOSMode.BETA
is being used (with broker versions >= 2.5); see Exactly Once Semantics.
KafkaTemplate
Transactional and non-Transactional Publishing
Normally, when a KafkaTemplate
is transactional (configured with a transaction-capable producer factory), transactions are required.
The transaction can be started by a TransactionTemplate
, a @Transactional
method, calling executeInTransaction
, or by a listener container, when configured with a KafkaTransactionManager
.
Any attempt to use the template outside the scope of a transaction results in the template throwing an IllegalStateException
.
Starting with version 2.4.3, you can set the template’s allowNonTransactional
property to true
.
In that case, the template will allow the operation to run without a transaction, by calling the ProducerFactory
's createNonTransactionalProducer()
method; the producer will be cached, or thread-bound, as normal for reuse.
See Using DefaultKafkaProducerFactory
.
Transactions with Batch Listeners
When a listener fails while transactions are being used, the AfterRollbackProcessor
is invoked to take some action after the rollback occurs.
When using the default AfterRollbackProcessor
with a record listener, seeks are performed so that the failed record will be redelivered.
With a batch listener, however, the whole batch will be redelivered because the framework doesn’t know which record in the batch failed.
See After-rollback Processor for more information.
When using a batch listener, version 2.4.2 introduced an alternative mechanism to deal with failures while processing a batch; the BatchToRecordAdapter
.
When a container factory with batchListener
set to true is configured with a BatchToRecordAdapter
, the listener is invoked with one record at a time.
This enables error handling within the batch, while still making it possible to stop processing the entire batch, depending on the exception type.
A default BatchToRecordAdapter
is provided, that can be configured with a standard ConsumerRecordRecoverer
such as the DeadLetterPublishingRecoverer
.
The following test case configuration snippet illustrates how to use this feature:
public static class TestListener {
final List<String> values = new ArrayList<>();
@KafkaListener(id = "batchRecordAdapter", topics = "test")
public void listen(String data) {
values.add(data);
if ("bar".equals(data)) {
throw new RuntimeException("reject partial");
}
}
}
@Configuration
@EnableKafka
public static class Config {
ConsumerRecord<?, ?> failed;
@Bean
public TestListener test() {
return new TestListener();
}
@Bean
public ConsumerFactory<?, ?> consumerFactory() {
return mock(ConsumerFactory.class);
}
@Bean
public ConcurrentKafkaListenerContainerFactory<String, String> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory factory = new ConcurrentKafkaListenerContainerFactory();
factory.setConsumerFactory(consumerFactory());
factory.setBatchListener(true);
factory.setBatchToRecordAdapter(new DefaultBatchToRecordAdapter<>((record, ex) -> {
this.failed = record;
}));
return factory;
}
}
4.1.13. Exactly Once Semantics
You can provide a listener container with a KafkaAwareTransactionManager
instance.
When so configured, the container starts a transaction before invoking the listener.
Any KafkaTemplate
operations performed by the listener participate in the transaction.
If the listener successfully processes the record (or multiple records, when using a BatchMessageListener
), the container sends the offset(s) to the transaction by using producer.sendOffsetsToTransaction()
), before the transaction manager commits the transaction.
If the listener throws an exception, the transaction is rolled back and the consumer is repositioned so that the rolled-back record(s) can be retrieved on the next poll.
See After-rollback Processor for more information and for handling records that repeatedly fail.
Using transactions enables Exactly Once Semantics (EOS).
This means that, for a read→process-write
sequence, it is guaranteed that the sequence is completed exactly once.
(The read and process are have at least once semantics).
Spring for Apache Kafka version 2.5 and later supports two EOS modes:
-
ALPHA
- alias forV1
(deprecated) -
BETA
- alias forV2
(deprecated) -
V1
- akatransactional.id
fencing (since version 0.11.0.0) -
V2
- aka fetch-offset-request fencing (since version 2.5)
With mode V1
, the producer is "fenced" if another instance with the same transactional.id
is started.
Spring manages this by using a Producer
for each group.id/topic/partition
; when a rebalance occurs a new instance will use the same transactional.id
and the old producer is fenced.
With mode V2
, it is not necessary to have a producer for each group.id/topic/partition
because consumer metadata is sent along with the offsets to the transaction and the broker can determine if the producer is fenced using that information instead.
Starting with version 2.6, the default EOSMode
is V2
.
To configure the container to use mode ALPHA
, set the container property EOSMode
to ALPHA
, to revert to the previous behavior.
With V2 (default), your brokers must be version 2.5 or later; kafka-clients version 3.0, the producer will no longer fall back to V1 ; if the broker does not support V2 , an exception is thrown.
If your brokers are earlier than 2.5, you must set the EOSMode to V1 , leave the DefaultKafkaProducerFactory producerPerConsumerPartition set to true and, if you are using a batch listener, you should set subBatchPerPartition to true .
|
When your brokers are upgraded to 2.5 or later, you should switch the mode to V2
, but the number of producers will remain as before.
You can then do a rolling upgrade of your application with producerPerConsumerPartition
set to false
to reduce the number of producers; you should also no longer set the subBatchPerPartition
container property.
If your brokers are already 2.5 or newer, you should set the DefaultKafkaProducerFactory
producerPerConsumerPartition
property to false
, to reduce the number of producers needed.
When using EOSMode.V2 with producerPerConsumerPartition=false the transactional.id must be unique across all application instances.
|
When using V2
mode, it is no longer necessary to set the subBatchPerPartition
to true
; it will default to false
when the EOSMode
is V2
.
Refer to KIP-447 for more information.
V1
and V2
were previously ALPHA
and BETA
; they have been changed to align the framework with KIP-732.
4.1.14. Wiring Spring Beans into Producer/Consumer Interceptors
Apache Kafka provides a mechanism to add interceptors to producers and consumers.
These objects are managed by Kafka, not Spring, and so normal Spring dependency injection won’t work for wiring in dependent Spring Beans.
However, you can manually wire in those dependencies using the interceptor config()
method.
The following Spring Boot application shows how to do this by overriding boot’s default factories to add some dependent bean into the configuration properties.
@SpringBootApplication
public class Application {
public static void main(String[] args) {
SpringApplication.run(Application.class, args);
}
@Bean
public ConsumerFactory<?, ?> kafkaConsumerFactory(SomeBean someBean) {
Map<String, Object> consumerProperties = new HashMap<>();
// consumerProperties.put(..., ...)
// ...
consumerProperties.put(ConsumerConfig.INTERCEPTOR_CLASSES_CONFIG, MyConsumerInterceptor.class.getName());
consumerProperties.put("some.bean", someBean);
return new DefaultKafkaConsumerFactory<>(consumerProperties);
}
@Bean
public ProducerFactory<?, ?> kafkaProducerFactory(SomeBean someBean) {
Map<String, Object> producerProperties = new HashMap<>();
// producerProperties.put(..., ...)
// ...
Map<String, Object> producerProperties = properties.buildProducerProperties();
producerProperties.put(ProducerConfig.INTERCEPTOR_CLASSES_CONFIG, MyProducerInterceptor.class.getName());
producerProperties.put("some.bean", someBean);
DefaultKafkaProducerFactory<?, ?> factory = new DefaultKafkaProducerFactory<>(producerProperties);
return factory;
}
@Bean
public SomeBean someBean() {
return new SomeBean();
}
@KafkaListener(id = "kgk897", topics = "kgh897")
public void listen(String in) {
System.out.println("Received " + in);
}
@Bean
public ApplicationRunner runner(KafkaTemplate<String, String> template) {
return args -> template.send("kgh897", "test");
}
@Bean
public NewTopic kRequests() {
return TopicBuilder.name("kgh897")
.partitions(1)
.replicas(1)
.build();
}
}
public class SomeBean {
public void someMethod(String what) {
System.out.println(what + " in my foo bean");
}
}
public class MyProducerInterceptor implements ProducerInterceptor<String, String> {
private SomeBean bean;
@Override
public void configure(Map<String, ?> configs) {
this.bean = (SomeBean) configs.get("some.bean");
}
@Override
public ProducerRecord<String, String> onSend(ProducerRecord<String, String> record) {
this.bean.someMethod("producer interceptor");
return record;
}
@Override
public void onAcknowledgement(RecordMetadata metadata, Exception exception) {
}
@Override
public void close() {
}
}
public class MyConsumerInterceptor implements ConsumerInterceptor<String, String> {
private SomeBean bean;
@Override
public void configure(Map<String, ?> configs) {
this.bean = (SomeBean) configs.get("some.bean");
}
@Override
public ConsumerRecords<String, String> onConsume(ConsumerRecords<String, String> records) {
this.bean.someMethod("consumer interceptor");
return records;
}
@Override
public void onCommit(Map<TopicPartition, OffsetAndMetadata> offsets) {
}
@Override
public void close() {
}
}
Result:
producer interceptor in my foo bean
consumer interceptor in my foo bean
Received test
4.1.15. Pausing and Resuming Listener Containers
Version 2.1.3 added pause()
and resume()
methods to listener containers.
Previously, you could pause a consumer within a ConsumerAwareMessageListener
and resume it by listening for a ListenerContainerIdleEvent
, which provides access to the Consumer
object.
While you could pause a consumer in an idle container by using an event listener, in some cases, this was not thread-safe, since there is no guarantee that the event listener is invoked on the consumer thread.
To safely pause and resume consumers, you should use the pause
and resume
methods on the listener containers.
A pause()
takes effect just before the next poll()
; a resume()
takes effect just after the current poll()
returns.
When a container is paused, it continues to poll()
the consumer, avoiding a rebalance if group management is being used, but it does not retrieve any records.
See the Kafka documentation for more information.
Starting with version 2.1.5, you can call isPauseRequested()
to see if pause()
has been called.
However, the consumers might not have actually paused yet.
isConsumerPaused()
returns true if all Consumer
instances have actually paused.
In addition (also since 2.1.5), ConsumerPausedEvent
and ConsumerResumedEvent
instances are published with the container as the source
property and the TopicPartition
instances involved in the partitions
property.
The following simple Spring Boot application demonstrates by using the container registry to get a reference to a @KafkaListener
method’s container and pausing or resuming its consumers as well as receiving the corresponding events:
@SpringBootApplication
public class Application implements ApplicationListener<KafkaEvent> {
public static void main(String[] args) {
SpringApplication.run(Application.class, args).close();
}
@Override
public void onApplicationEvent(KafkaEvent event) {
System.out.println(event);
}
@Bean
public ApplicationRunner runner(KafkaListenerEndpointRegistry registry,
KafkaTemplate<String, String> template) {
return args -> {
template.send("pause.resume.topic", "thing1");
Thread.sleep(10_000);
System.out.println("pausing");
registry.getListenerContainer("pause.resume").pause();
Thread.sleep(10_000);
template.send("pause.resume.topic", "thing2");
Thread.sleep(10_000);
System.out.println("resuming");
registry.getListenerContainer("pause.resume").resume();
Thread.sleep(10_000);
};
}
@KafkaListener(id = "pause.resume", topics = "pause.resume.topic")
public void listen(String in) {
System.out.println(in);
}
@Bean
public NewTopic topic() {
return TopicBuilder.name("pause.resume.topic")
.partitions(2)
.replicas(1)
.build();
}
}
The following listing shows the results of the preceding example:
partitions assigned: [pause.resume.topic-1, pause.resume.topic-0]
thing1
pausing
ConsumerPausedEvent [partitions=[pause.resume.topic-1, pause.resume.topic-0]]
resuming
ConsumerResumedEvent [partitions=[pause.resume.topic-1, pause.resume.topic-0]]
thing2
4.1.16. Pausing and Resuming Partitions on Listener Containers
Since version 2.7 you can pause and resume the consumption of specific partitions assigned to that consumer by using the pausePartition(TopicPartition topicPartition)
and resumePartition(TopicPartition topicPartition)
methods in the listener containers.
The pausing and resuming takes place respectively before and after the poll()
similar to the pause()
and resume()
methods.
The isPartitionPauseRequested()
method returns true if pause for that partition has been requested.
The isPartitionPaused()
method returns true if that partition has effectively been paused.
Also since version 2.7 ConsumerPartitionPausedEvent
and ConsumerPartitionResumedEvent
instances are published with the container as the source
property and the TopicPartition
instance.
4.1.17. Serialization, Deserialization, and Message Conversion
Overview
Apache Kafka provides a high-level API for serializing and deserializing record values as well as their keys.
It is present with the org.apache.kafka.common.serialization.Serializer<T>
and
org.apache.kafka.common.serialization.Deserializer<T>
abstractions with some built-in implementations.
Meanwhile, we can specify serializer and deserializer classes by using Producer
or Consumer
configuration properties.
The following example shows how to do so:
props.put(ConsumerConfig.KEY_DESERIALIZER_CLASS_CONFIG, IntegerDeserializer.class);
props.put(ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG, StringDeserializer.class);
...
props.put(ProducerConfig.KEY_SERIALIZER_CLASS_CONFIG, IntegerSerializer.class);
props.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, StringSerializer.class);
For more complex or particular cases, the KafkaConsumer
(and, therefore, KafkaProducer
) provides overloaded
constructors to accept Serializer
and Deserializer
instances for keys
and values
, respectively.
When you use this API, the DefaultKafkaProducerFactory
and DefaultKafkaConsumerFactory
also provide properties (through constructors or setter methods) to inject custom Serializer
and Deserializer
instances into the target Producer
or Consumer
.
Also, you can pass in Supplier<Serializer>
or Supplier<Deserializer>
instances through constructors - these Supplier
s are called on creation of each Producer
or Consumer
.
String serialization
Since version 2.5, Spring for Apache Kafka provides ToStringSerializer
and ParseStringDeserializer
classes that use String representation of entities.
They rely on methods toString
and some Function<String>
or BiFunction<String, Headers>
to parse the String and populate properties of an instance.
Usually, this would invoke some static method on the class, such as parse
:
ToStringSerializer<Thing> thingSerializer = new ToStringSerializer<>();
//...
ParseStringDeserializer<Thing> deserializer = new ParseStringDeserializer<>(Thing::parse);
By default, the ToStringSerializer
is configured to convey type information about the serialized entity in the record Headers
.
You can disable this by setting the addTypeInfo
property to false.
This information can be used by ParseStringDeserializer
on the receiving side.
-
ToStringSerializer.ADD_TYPE_INFO_HEADERS
(defaulttrue
): You can set it tofalse
to disable this feature on theToStringSerializer
(sets theaddTypeInfo
property).
ParseStringDeserializer<Object> deserializer = new ParseStringDeserializer<>((str, headers) -> {
byte[] header = headers.lastHeader(ToStringSerializer.VALUE_TYPE).value();
String entityType = new String(header);
if (entityType.contains("Thing")) {
return Thing.parse(str);
}
else {
// ...parsing logic
}
});
You can configure the Charset
used to convert String
to/from byte[]
with the default being UTF-8
.
You can configure the deserializer with the name of the parser method using ConsumerConfig
properties:
-
ParseStringDeserializer.KEY_PARSER
-
ParseStringDeserializer.VALUE_PARSER
The properties must contain the fully qualified name of the class followed by the method name, separated by a period .
.
The method must be static and have a signature of either (String, Headers)
or (String)
.
A ToFromStringSerde
is also provided, for use with Kafka Streams.
JSON
Spring for Apache Kafka also provides JsonSerializer
and JsonDeserializer
implementations that are based on the
Jackson JSON object mapper.
The JsonSerializer
allows writing any Java object as a JSON byte[]
.
The JsonDeserializer
requires an additional Class<?> targetType
argument to allow the deserialization of a consumed byte[]
to the proper target object.
The following example shows how to create a JsonDeserializer
:
JsonDeserializer<Thing> thingDeserializer = new JsonDeserializer<>(Thing.class);
You can customize both JsonSerializer
and JsonDeserializer
with an ObjectMapper
.
You can also extend them to implement some particular configuration logic in the configure(Map<String, ?> configs, boolean isKey)
method.
Starting with version 2.3, all the JSON-aware components are configured by default with a JacksonUtils.enhancedObjectMapper()
instance, which comes with the MapperFeature.DEFAULT_VIEW_INCLUSION
and DeserializationFeature.FAIL_ON_UNKNOWN_PROPERTIES
features disabled.
Also such an instance is supplied with well-known modules for custom data types, such a Java time and Kotlin support.
See JacksonUtils.enhancedObjectMapper()
JavaDocs for more information.
This method also registers a org.springframework.kafka.support.JacksonMimeTypeModule
for org.springframework.util.MimeType
objects serialization into the plain string for inter-platform compatibility over the network.
A JacksonMimeTypeModule
can be registered as a bean in the application context and it will be auto-configured into Spring Boot ObjectMapper
instance.
Also starting with version 2.3, the JsonDeserializer
provides TypeReference
-based constructors for better handling of target generic container types.
Starting with version 2.1, you can convey type information in record Headers
, allowing the handling of multiple types.
In addition, you can configure the serializer and deserializer by using the following Kafka properties.
They have no effect if you have provided Serializer
and Deserializer
instances for KafkaConsumer
and KafkaProducer
, respectively.
Configuration Properties
-
JsonSerializer.ADD_TYPE_INFO_HEADERS
(defaulttrue
): You can set it tofalse
to disable this feature on theJsonSerializer
(sets theaddTypeInfo
property). -
JsonSerializer.TYPE_MAPPINGS
(defaultempty
): See Mapping Types. -
JsonDeserializer.USE_TYPE_INFO_HEADERS
(defaulttrue
): You can set it tofalse
to ignore headers set by the serializer. -
JsonDeserializer.REMOVE_TYPE_INFO_HEADERS
(defaulttrue
): You can set it tofalse
to retain headers set by the serializer. -
JsonDeserializer.KEY_DEFAULT_TYPE
: Fallback type for deserialization of keys if no header information is present. -
JsonDeserializer.VALUE_DEFAULT_TYPE
: Fallback type for deserialization of values if no header information is present. -
JsonDeserializer.TRUSTED_PACKAGES
(defaultjava.util
,java.lang
): Comma-delimited list of package patterns allowed for deserialization.*
means deserialize all. -
JsonDeserializer.TYPE_MAPPINGS
(defaultempty
): See Mapping Types. -
JsonDeserializer.KEY_TYPE_METHOD
(defaultempty
): See Using Methods to Determine Types. -
JsonDeserializer.VALUE_TYPE_METHOD
(defaultempty
): See Using Methods to Determine Types.
Starting with version 2.2, the type information headers (if added by the serializer) are removed by the deserializer.
You can revert to the previous behavior by setting the removeTypeHeaders
property to false
, either directly on the deserializer or with the configuration property described earlier.
Starting with version 2.8, if you construct the serializer or deserializer programmatically as shown in Programmatic Construction, the above properties will be applied by the factories, as long as you have not set any properties explicitly (using set*() methods or using the fluent API).
Previously, when creating programmatically, the configuration properties were never applied; this is still the case if you explicitly set properties on the object directly.
|
Mapping Types
Starting with version 2.2, when using JSON, you can now provide type mappings by using the properties in the preceding list.
Previously, you had to customize the type mapper within the serializer and deserializer.
Mappings consist of a comma-delimited list of token:className
pairs.
On outbound, the payload’s class name is mapped to the corresponding token.
On inbound, the token in the type header is mapped to the corresponding class name.
The following example creates a set of mappings:
senderProps.put(ProducerConfig.VALUE_SERIALIZER_CLASS_CONFIG, JsonSerializer.class);
senderProps.put(JsonSerializer.TYPE_MAPPINGS, "cat:com.mycat.Cat, hat:com.myhat.hat");
...
consumerProps.put(ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG, JsonDeserializer.class);
consumerProps.put(JsonDeSerializer.TYPE_MAPPINGS, "cat:com.yourcat.Cat, hat:com.yourhat.hat");
The corresponding objects must be compatible. |
If you use Spring Boot, you can provide these properties in the application.properties
(or yaml) file.
The following example shows how to do so:
spring.kafka.producer.value-serializer=org.springframework.kafka.support.serializer.JsonSerializer
spring.kafka.producer.properties.spring.json.type.mapping=cat:com.mycat.Cat,hat:com.myhat.Hat
You can perform only simple configuration with properties.
For more advanced configuration (such as using a custom
Setters are also provided, as an alternative to using these constructors. |
Starting with version 2.2, you can explicitly configure the deserializer to use the supplied target type and ignore type information in headers by using one of the overloaded constructors that have a boolean useHeadersIfPresent
(which is true
by default).
The following example shows how to do so:
DefaultKafkaConsumerFactory<Integer, Cat1> cf = new DefaultKafkaConsumerFactory<>(props,
new IntegerDeserializer(), new JsonDeserializer<>(Cat1.class, false));
Using Methods to Determine Types
Starting with version 2.5, you can now configure the deserializer, via properties, to invoke a method to determine the target type.
If present, this will override any of the other techniques discussed above.
This can be useful if the data is published by an application that does not use the Spring serializer and you need to deserialize to different types depending on the data, or other headers.
Set these properties to the method name - a fully qualified class name followed by the method name, separated by a period .
.
The method must be declared as public static
, have one of three signatures (String topic, byte[] data, Headers headers)
, (byte[] data, Headers headers)
or (byte[] data)
and return a Jackson JavaType
.
-
JsonDeserializer.KEY_TYPE_METHOD
:spring.json.key.type.method
-
JsonDeserializer.VALUE_TYPE_METHOD
:spring.json.value.type.method
You can use arbitrary headers or inspect the data to determine the type.
JavaType thing1Type = TypeFactory.defaultInstance().constructType(Thing1.class);
JavaType thing2Type = TypeFactory.defaultInstance().constructType(Thing2.class);
public static JavaType thingOneOrThingTwo(byte[] data, Headers headers) {
// {"thisIsAFieldInThing1":"value", ...
if (data[21] == '1') {
return thing1Type;
}
else {
return thing2Type;
}
}
For more sophisticated data inspection consider using JsonPath
or similar but, the simpler the test to determine the type, the more efficient the process will be.
The following is an example of creating the deserializer programmatically (when providing the consumer factory with the deserializer in the constructor):
JsonDeserializer<Object> deser = new JsonDeserializer<>()
.trustedPackages("*")
.typeResolver(SomeClass::thing1Thing2JavaTypeForTopic);
...
public static JavaType thing1Thing2JavaTypeForTopic(String topic, byte[] data, Headers headers) {
...
}
Programmatic Construction
When constructing the serializer/deserializer programmatically for use in the producer/consumer factory, since version 2.3, you can use the fluent API, which simplifies configuration.
@Bean
public ProducerFactory<MyKeyType, MyValueType> pf() {
Map<String, Object> props = new HashMap<>();
// props.put(..., ...)
// ...
DefaultKafkaProducerFactory<MyKeyType, MyValueType> pf = new DefaultKafkaProducerFactory<>(props,
new JsonSerializer<MyKeyType>()
.forKeys()
.noTypeInfo(),
new JsonSerializer<MyValueType>()
.noTypeInfo());
return pf;
}
@Bean
public ConsumerFactory<MyKeyType, MyValueType> cf() {
Map<String, Object> props = new HashMap<>();
// props.put(..., ...)
// ...
DefaultKafkaConsumerFactory<MyKeyType, MyValueType> cf = new DefaultKafkaConsumerFactory<>(props,
new JsonDeserializer<>(MyKeyType.class)
.forKeys()
.ignoreTypeHeaders(),
new JsonDeserializer<>(MyValueType.class)
.ignoreTypeHeaders());
return cf;
}
To provide type mapping programmatically, similar to Using Methods to Determine Types, use the typeFunction
property.
JsonDeserializer<Object> deser = new JsonDeserializer<>()
.trustedPackages("*")
.typeFunction(MyUtils::thingOneOrThingTwo);
Alternatively, as long as you don’t use the fluent API to configure properties, or set them using set*()
methods, the factories will configure the serializer/deserializer using the configuration properties; see Configuration Properties.
Using Headers
Version 2.3 introduced the DelegatingSerializer
and DelegatingDeserializer
, which allow producing and consuming records with different key and/or value types.
Producers must set a header DelegatingSerializer.VALUE_SERIALIZATION_SELECTOR
to a selector value that is used to select which serializer to use for the value and DelegatingSerializer.KEY_SERIALIZATION_SELECTOR
for the key; if a match is not found, an IllegalStateException
is thrown.
For incoming records, the deserializer uses the same headers to select the deserializer to use; if a match is not found or the header is not present, the raw byte[]
is returned.
You can configure the map of selector to Serializer
/ Deserializer
via a constructor, or you can configure it via Kafka producer/consumer properties with the keys DelegatingSerializer.VALUE_SERIALIZATION_SELECTOR_CONFIG
and DelegatingSerializer.KEY_SERIALIZATION_SELECTOR_CONFIG
.
For the serializer, the producer property can be a Map<String, Object>
where the key is the selector and the value is a Serializer
instance, a serializer Class
or the class name.
The property can also be a String of comma-delimited map entries, as shown below.
For the deserializer, the consumer property can be a Map<String, Object>
where the key is the selector and the value is a Deserializer
instance, a deserializer Class
or the class name.
The property can also be a String of comma-delimited map entries, as shown below.
To configure using properties, use the following syntax:
producerProps.put(DelegatingSerializer.VALUE_SERIALIZATION_SELECTOR_CONFIG,
"thing1:com.example.MyThing1Serializer, thing2:com.example.MyThing2Serializer")
consumerProps.put(DelegatingDeserializer.VALUE_SERIALIZATION_SELECTOR_CONFIG,
"thing1:com.example.MyThing1Deserializer, thing2:com.example.MyThing2Deserializer")
Producers would then set the DelegatingSerializer.VALUE_SERIALIZATION_SELECTOR
header to thing1
or thing2
.
This technique supports sending different types to the same topic (or different topics).
Starting with version 2.5.1, it is not necessary to set the selector header, if the type (key or value) is one of the standard types supported by Serdes (Long , Integer , etc).
Instead, the serializer will set the header to the class name of the type.
It is not necessary to configure serializers or deserializers for these types, they will be created (once) dynamically.
|
For another technique to send different types to different topics, see Using RoutingKafkaTemplate
.
2.8 introduced the DelegatingByTypeSerializer
.
@Bean
public ProducerFactory<Integer, Object> producerFactory(Map<String, Object> config) {
return new DefaultKafkaProducerFactory<>(config,
null, new DelegatingByTypeSerializer(Map.of(
byte[].class, new ByteArraySerializer(),
Bytes.class, new BytesSerializer(),
String.class, new StringSerializer())));
}
By Topic
Starting with version 2.8, the DelegatingByTopicSerializer
and DelegatingByTopicDeserializer
allow selection of a serializer/deserializer based on the topic name.
Regex Pattern
s are used to lookup the instance to use.
The map can be configured using a constructor, or via properties (a comma delimited list of pattern:serializer
).
producerConfigs.put(DelegatingByTopicSerializer.VALUE_SERIALIZATION_TOPIC_CONFIG,
"topic[0-4]:" + ByteArraySerializer.class.getName()
+ ", topic[5-9]:" + StringSerializer.class.getName());
...
ConsumerConfigs.put(DelegatingByTopicDeserializer.VALUE_SERIALIZATION_TOPIC_CONFIG,
"topic[0-4]:" + ByteArrayDeserializer.class.getName()
+ ", topic[5-9]:" + StringDeserializer.class.getName());
Use KEY_SERIALIZATION_TOPIC_CONFIG
when using this for keys.
@Bean
public ProducerFactory<Integer, Object> producerFactory(Map<String, Object> config) {
return new DefaultKafkaProducerFactory<>(config,
null,
new DelegatingByTopicSerializer(Map.of(
Pattern.compile("topic[0-4]"), new ByteArraySerializer(),
Pattern.compile("topic[5-9]"), new StringSerializer())),
new JsonSerializer<Object>()); // default
}
You can specify a default serializer/deserializer to use when there is no pattern match using DelegatingByTopicSerialization.KEY_SERIALIZATION_TOPIC_DEFAULT
and DelegatingByTopicSerialization.VALUE_SERIALIZATION_TOPIC_DEFAULT
.
An additional property DelegatingByTopicSerialization.CASE_SENSITIVE
(default true
), when set to false
makes the topic lookup case insensitive.
Retrying Deserializer
The RetryingDeserializer
uses a delegate Deserializer
and RetryTemplate
to retry deserialization when the delegate might have transient errors, such a network issues, during deserialization.
ConsumerFactory cf = new DefaultKafkaConsumerFactory(myConsumerConfigs,
new RetryingDeserializer(myUnreliableKeyDeserializer, retryTemplate),
new RetryingDeserializer(myUnreliableValueDeserializer, retryTemplate));
Refer to the spring-retry project for configuration of the RetryTemplate
with a retry policy, back off policy, etc.
Spring Messaging Message Conversion
Although the Serializer
and Deserializer
API is quite simple and flexible from the low-level Kafka Consumer
and Producer
perspective, you might need more flexibility at the Spring Messaging level, when using either @KafkaListener
or Spring Integration’s Apache Kafka Support.
To let you easily convert to and from org.springframework.messaging.Message
, Spring for Apache Kafka provides a MessageConverter
abstraction with the MessagingMessageConverter
implementation and its JsonMessageConverter
(and subclasses) customization.
You can inject the MessageConverter
into a KafkaTemplate
instance directly and by using AbstractKafkaListenerContainerFactory
bean definition for the @KafkaListener.containerFactory()
property.
The following example shows how to do so:
@Bean
public KafkaListenerContainerFactory<?, ?> kafkaJsonListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(consumerFactory());
factory.setMessageConverter(new JsonMessageConverter());
return factory;
}
...
@KafkaListener(topics = "jsonData",
containerFactory = "kafkaJsonListenerContainerFactory")
public void jsonListener(Cat cat) {
...
}
When using Spring Boot, simply define the converter as a @Bean
and Spring Boot auto configuration will wire it into the auto-configured template and container factory.
When you use a @KafkaListener
, the parameter type is provided to the message converter to assist with the conversion.
This type inference can be achieved only when the |
On the consumer side, you can configure a On the producer side, when you use Spring Integration or the
Again, using For convenience, starting with version 2.3, the framework also provides a |
Starting with version 2.7.1, message payload conversion can be delegated to a spring-messaging
SmartMessageConverter
; this enables conversion, for example, to be based on the MessageHeaders.CONTENT_TYPE
header.
The KafkaMessageConverter.fromMessage() method is called for outbound conversion to a ProducerRecord with the message payload in the ProducerRecord.value() property.
The KafkaMessageConverter.toMessage() method is called for inbound conversion from ConsumerRecord with the payload being the ConsumerRecord.value() property.
The SmartMessageConverter.toMessage() method is called to create a new outbound Message<?> from the Message passed to`fromMessage()` (usually by KafkaTemplate.send(Message<?> msg) ).
Similarly, in the KafkaMessageConverter.toMessage() method, after the converter has created a new Message<?> from the ConsumerRecord , the SmartMessageConverter.fromMessage() method is called and then the final inbound message is created with the newly converted payload.
In either case, if the SmartMessageConverter returns null , the original message is used.
|
When the default converter is used in the KafkaTemplate
and listener container factory, you configure the SmartMessageConverter
by calling setMessagingConverter()
on the template and via the contentMessageConverter
property on @KafkaListener
methods.
Examples:
template.setMessagingConverter(mySmartConverter);
@KafkaListener(id = "withSmartConverter", topics = "someTopic",
contentTypeConverter = "mySmartConverter")
public void smart(Thing thing) {
...
}
Using Spring Data Projection Interfaces
Starting with version 2.1.1, you can convert JSON to a Spring Data Projection interface instead of a concrete type. This allows very selective, and low-coupled bindings to data, including the lookup of values from multiple places inside the JSON document. For example the following interface can be defined as message payload type:
interface SomeSample {
@JsonPath({ "$.username", "$.user.name" })
String getUsername();
}
@KafkaListener(id="projection.listener", topics = "projection")
public void projection(SomeSample in) {
String username = in.getUsername();
...
}
Accessor methods will be used to lookup the property name as field in the received JSON document by default.
The @JsonPath
expression allows customization of the value lookup, and even to define multiple JSON Path expressions, to lookup values from multiple places until an expression returns an actual value.
To enable this feature, use a ProjectingMessageConverter
configured with an appropriate delegate converter (used for outbound conversion and converting non-projection interfaces).
You must also add spring-data:spring-data-commons
and com.jayway.jsonpath:json-path
to the class path.
When used as the parameter to a @KafkaListener
method, the interface type is automatically passed to the converter as normal.
Using ErrorHandlingDeserializer
When a deserializer fails to deserialize a message, Spring has no way to handle the problem, because it occurs before the poll()
returns.
To solve this problem, the ErrorHandlingDeserializer
has been introduced.
This deserializer delegates to a real deserializer (key or value).
If the delegate fails to deserialize the record content, the ErrorHandlingDeserializer
returns a null
value and a DeserializationException
in a header that contains the cause and the raw bytes.
When you use a record-level MessageListener
, if the ConsumerRecord
contains a DeserializationException
header for either the key or value, the container’s ErrorHandler
is called with the failed ConsumerRecord
.
The record is not passed to the listener.
Alternatively, you can configure the ErrorHandlingDeserializer
to create a custom value by providing a failedDeserializationFunction
, which is a Function<FailedDeserializationInfo, T>
.
This function is invoked to create an instance of T
, which is passed to the listener in the usual fashion.
An object of type FailedDeserializationInfo
, which contains all the contextual information is provided to the function.
You can find the DeserializationException
(as a serialized Java object) in headers.
See the Javadoc for the ErrorHandlingDeserializer
for more information.
You can use the DefaultKafkaConsumerFactory
constructor that takes key and value Deserializer
objects and wire in appropriate ErrorHandlingDeserializer
instances that you have configured with the proper delegates.
Alternatively, you can use consumer configuration properties (which are used by the ErrorHandlingDeserializer
) to instantiate the delegates.
The property names are ErrorHandlingDeserializer.KEY_DESERIALIZER_CLASS
and ErrorHandlingDeserializer.VALUE_DESERIALIZER_CLASS
.
The property value can be a class or class name.
The following example shows how to set these properties:
... // other props
props.put(ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG, ErrorHandlingDeserializer.class);
props.put(ConsumerConfig.KEY_DESERIALIZER_CLASS_CONFIG, ErrorHandlingDeserializer.class);
props.put(ErrorHandlingDeserializer.KEY_DESERIALIZER_CLASS, JsonDeserializer.class);
props.put(JsonDeserializer.KEY_DEFAULT_TYPE, "com.example.MyKey")
props.put(ErrorHandlingDeserializer.VALUE_DESERIALIZER_CLASS, JsonDeserializer.class.getName());
props.put(JsonDeserializer.VALUE_DEFAULT_TYPE, "com.example.MyValue")
props.put(JsonDeserializer.TRUSTED_PACKAGES, "com.example")
return new DefaultKafkaConsumerFactory<>(props);
The following example uses a failedDeserializationFunction
.
public class BadFoo extends Foo {
private final FailedDeserializationInfo failedDeserializationInfo;
public BadFoo(FailedDeserializationInfo failedDeserializationInfo) {
this.failedDeserializationInfo = failedDeserializationInfo;
}
public FailedDeserializationInfo getFailedDeserializationInfo() {
return this.failedDeserializationInfo;
}
}
public class FailedFooProvider implements Function<FailedDeserializationInfo, Foo> {
@Override
public Foo apply(FailedDeserializationInfo info) {
return new BadFoo(info);
}
}
The preceding example uses the following configuration:
...
consumerProps.put(ConsumerConfig.VALUE_DESERIALIZER_CLASS_CONFIG, ErrorHandlingDeserializer.class);
consumerProps.put(ErrorHandlingDeserializer.VALUE_DESERIALIZER_CLASS, JsonDeserializer.class);
consumerProps.put(ErrorHandlingDeserializer.VALUE_FUNCTION, FailedFooProvider.class);
...
If the consumer is configured with an ErrorHandlingDeserializer it is important to configure the KafkaTemplate and its producer with a serializer that can handle normal objects as well as raw byte[] values, which result from deserialization exceptions.
The generic value type of the template should be Object .
One technique is to use the DelegatingByTypeSerializer ; an example follows:
|
@Bean
public ProducerFactory<String, Object> producerFactory() {
return new DefaultKafkaProducerFactory<>(producerConfiguration(), new StringSerializer(),
new DelegatingByTypeSerializer(Map.of(byte[].class, new ByteArraySerializer(),
MyNormalObject.class, new JsonSerializer<Object>())));
}
@Bean
public KafkaTemplate<String, Object> kafkaTemplate() {
return new KafkaTemplate<>(producerFactory());
}
When using an ErrorHandlingDeserializer
with a batch listener, you must check for the deserialization exceptions in message headers.
When used with a RecoveringBatchErrorHandler
, you can use that header to determine which record the exception failed on and communicate to the error handler via a BatchListenerFailedException
.
@KafkaListener(id = "test", topics = "test")
void listen(List<Thing> in, @Header(KafkaHeaders.BATCH_CONVERTED_HEADERS) List<Map<String, Object>> headers) {
for (int i = 0; i < in.size(); i++) {
Thing thing = in.get(i);
if (thing == null
&& headers.get(i).get(SerializationUtils.VALUE_DESERIALIZER_EXCEPTION_HEADER) != null) {
DeserializationException deserEx = ListenerUtils.byteArrayToDeserializationException(this.logger,
(byte[]) headers.get(i).get(SerializationUtils.VALUE_DESERIALIZER_EXCEPTION_HEADER));
if (deserEx != null) {
logger.error(deserEx, "Record at index " + i + " could not be deserialized");
}
throw new BatchListenerFailedException("Deserialization", deserEx, i);
}
process(thing);
}
}
ListenerUtils.byteArrayToDeserializationException()
can be used to convert the header to a DeserializationException
.
When consuming List<ConsumerRecord<?, ?>
, ListenerUtils.getExceptionFromHeader()
is used instead:
@KafkaListener(id = "kgh2036", topics = "kgh2036")
void listen(List<ConsumerRecord<String, Thing>> in) {
for (int i = 0; i < in.size(); i++) {
ConsumerRecord<String, Thing> rec = in.get(i);
if (rec.value() == null) {
DeserializationException deserEx = ListenerUtils.getExceptionFromHeader(rec,
SerializationUtils.VALUE_DESERIALIZER_EXCEPTION_HEADER, this.logger);
if (deserEx != null) {
logger.error(deserEx, "Record at offset " + rec.offset() + " could not be deserialized");
throw new BatchListenerFailedException("Deserialization", deserEx, i);
}
}
process(rec.value());
}
}
Payload Conversion with Batch Listeners
You can also use a JsonMessageConverter
within a BatchMessagingMessageConverter
to convert batch messages when you use a batch listener container factory.
See Serialization, Deserialization, and Message Conversion and Spring Messaging Message Conversion for more information.
By default, the type for the conversion is inferred from the listener argument.
If you configure the JsonMessageConverter
with a DefaultJackson2TypeMapper
that has its TypePrecedence
set to TYPE_ID
(instead of the default INFERRED
), the converter uses the type information in headers (if present) instead.
This allows, for example, listener methods to be declared with interfaces instead of concrete classes.
Also, the type converter supports mapping, so the deserialization can be to a different type than the source (as long as the data is compatible).
This is also useful when you use class-level @KafkaListener
instances where the payload must have already been converted to determine which method to invoke.
The following example creates beans that use this method:
@Bean
public KafkaListenerContainerFactory<?, ?> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
factory.setConsumerFactory(consumerFactory());
factory.setBatchListener(true);
factory.setMessageConverter(new BatchMessagingMessageConverter(converter()));
return factory;
}
@Bean
public JsonMessageConverter converter() {
return new JsonMessageConverter();
}
Note that, for this to work, the method signature for the conversion target must be a container object with a single generic parameter type, such as the following:
@KafkaListener(topics = "blc1")
public void listen(List<Foo> foos, @Header(KafkaHeaders.OFFSET) List<Long> offsets) {
...
}
Note that you can still access the batch headers.
If the batch converter has a record converter that supports it, you can also receive a list of messages where the payloads are converted according to the generic type. The following example shows how to do so:
@KafkaListener(topics = "blc3", groupId = "blc3")
public void listen1(List<Message<Foo>> fooMessages) {
...
}
ConversionService
Customization
Starting with version 2.1.1, the org.springframework.core.convert.ConversionService
used by the default o.s.messaging.handler.annotation.support.MessageHandlerMethodFactory
to resolve parameters for the invocation of a listener method is supplied with all beans that implement any of the following interfaces:
-
org.springframework.core.convert.converter.Converter
-
org.springframework.core.convert.converter.GenericConverter
-
org.springframework.format.Formatter
This lets you further customize listener deserialization without changing the default configuration for ConsumerFactory
and KafkaListenerContainerFactory
.
Setting a custom MessageHandlerMethodFactory on the KafkaListenerEndpointRegistrar through a KafkaListenerConfigurer bean disables this feature.
|
Adding custom HandlerMethodArgumentResolver
to @KafkaListener
Starting with version 2.4.2 you are able to add your own HandlerMethodArgumentResolver
and resolve custom method parameters.
All you need is to implement KafkaListenerConfigurer
and use method setCustomMethodArgumentResolvers()
from class KafkaListenerEndpointRegistrar
.
@Configuration
class CustomKafkaConfig implements KafkaListenerConfigurer {
@Override
public void configureKafkaListeners(KafkaListenerEndpointRegistrar registrar) {
registrar.setCustomMethodArgumentResolvers(
new HandlerMethodArgumentResolver() {
@Override
public boolean supportsParameter(MethodParameter parameter) {
return CustomMethodArgument.class.isAssignableFrom(parameter.getParameterType());
}
@Override
public Object resolveArgument(MethodParameter parameter, Message<?> message) {
return new CustomMethodArgument(
message.getHeaders().get(KafkaHeaders.RECEIVED_TOPIC, String.class)
);
}
}
);
}
}
You can also completely replace the framework’s argument resolution by adding a custom MessageHandlerMethodFactory
to the KafkaListenerEndpointRegistrar
bean.
If you do this, and your application needs to handle tombstone records, with a null
value()
(e.g. from a compacted topic), you should add a KafkaNullAwarePayloadArgumentResolver
to the factory; it must be the last resolver because it supports all types and can match arguments without a @Payload
annotation.
If you are using a DefaultMessageHandlerMethodFactory
, set this resolver as the last custom resolver; the factory will ensure that this resolver will be used before the standard PayloadMethodArgumentResolver
, which has no knowledge of KafkaNull
payloads.
4.1.18. Message Headers
The 0.11.0.0 client introduced support for headers in messages.
As of version 2.0, Spring for Apache Kafka now supports mapping these headers to and from spring-messaging
MessageHeaders
.
Previous versions mapped ConsumerRecord and ProducerRecord to spring-messaging Message<?> , where the value property is mapped to and from the payload and other properties (topic , partition , and so on) were mapped to headers.
This is still the case, but additional (arbitrary) headers can now be mapped.
|
Apache Kafka headers have a simple API, shown in the following interface definition:
public interface Header {
String key();
byte[] value();
}
The KafkaHeaderMapper
strategy is provided to map header entries between Kafka Headers
and MessageHeaders
.
Its interface definition is as follows:
public interface KafkaHeaderMapper {
void fromHeaders(MessageHeaders headers, Headers target);
void toHeaders(Headers source, Map<String, Object> target);
}
The DefaultKafkaHeaderMapper
maps the key to the MessageHeaders
header name and, in order to support rich header types for outbound messages, JSON conversion is performed.
A “special” header (with a key of spring_json_header_types
) contains a JSON map of <key>:<type>
.
This header is used on the inbound side to provide appropriate conversion of each header value to the original type.
On the inbound side, all Kafka Header
instances are mapped to MessageHeaders
.
On the outbound side, by default, all MessageHeaders
are mapped, except id
, timestamp
, and the headers that map to ConsumerRecord
properties.
You can specify which headers are to be mapped for outbound messages, by providing patterns to the mapper. The following listing shows a number of example mappings:
public DefaultKafkaHeaderMapper() { (1)
...
}
public DefaultKafkaHeaderMapper(ObjectMapper objectMapper) { (2)
...
}
public DefaultKafkaHeaderMapper(String... patterns) { (3)
...
}
public DefaultKafkaHeaderMapper(ObjectMapper objectMapper, String... patterns) { (4)
...
}
1 | Uses a default Jackson ObjectMapper and maps most headers, as discussed before the example. |
2 | Uses the provided Jackson ObjectMapper and maps most headers, as discussed before the example. |
3 | Uses a default Jackson ObjectMapper and maps headers according to the provided patterns. |
4 | Uses the provided Jackson ObjectMapper and maps headers according to the provided patterns. |
Patterns are rather simple and can contain a leading wildcard (), a trailing wildcard, or both (for example,
.cat.*
).
You can negate patterns with a leading !
.
The first pattern that matches a header name (whether positive or negative) wins.
When you provide your own patterns, we recommend including !id
and !timestamp
, since these headers are read-only on the inbound side.
By default, the mapper deserializes only classes in java.lang and java.util .
You can trust other (or all) packages by adding trusted packages with the addTrustedPackages method.
If you receive messages from untrusted sources, you may wish to add only those packages you trust.
To trust all packages, you can use mapper.addTrustedPackages("*") .
|
Mapping String header values in a raw form is useful when communicating with systems that are not aware of the mapper’s JSON format.
|
Starting with version 2.2.5, you can specify that certain string-valued headers should not be mapped using JSON, but to/from a raw byte[]
.
The AbstractKafkaHeaderMapper
has new properties; mapAllStringsOut
when set to true, all string-valued headers will be converted to byte[]
using the charset
property (default UTF-8
).
In addition, there is a property rawMappedHeaders
, which is a map of header name : boolean
; if the map contains a header name, and the header contains a String
value, it will be mapped as a raw byte[]
using the charset.
This map is also used to map raw incoming byte[]
headers to String
using the charset if, and only if, the boolean in the map value is true
.
If the boolean is false
, or the header name is not in the map with a true
value, the incoming header is simply mapped as the raw unmapped header.
The following test case illustrates this mechanism.
@Test
public void testSpecificStringConvert() {
DefaultKafkaHeaderMapper mapper = new DefaultKafkaHeaderMapper();
Map<String, Boolean> rawMappedHeaders = new HashMap<>();
rawMappedHeaders.put("thisOnesAString", true);
rawMappedHeaders.put("thisOnesBytes", false);
mapper.setRawMappedHeaders(rawMappedHeaders);
Map<String, Object> headersMap = new HashMap<>();
headersMap.put("thisOnesAString", "thing1");
headersMap.put("thisOnesBytes", "thing2");
headersMap.put("alwaysRaw", "thing3".getBytes());
MessageHeaders headers = new MessageHeaders(headersMap);
Headers target = new RecordHeaders();
mapper.fromHeaders(headers, target);
assertThat(target).containsExactlyInAnyOrder(
new RecordHeader("thisOnesAString", "thing1".getBytes()),
new RecordHeader("thisOnesBytes", "thing2".getBytes()),
new RecordHeader("alwaysRaw", "thing3".getBytes()));
headersMap.clear();
mapper.toHeaders(target, headersMap);
assertThat(headersMap).contains(
entry("thisOnesAString", "thing1"),
entry("thisOnesBytes", "thing2".getBytes()),
entry("alwaysRaw", "thing3".getBytes()));
}
By default, the DefaultKafkaHeaderMapper
is used in the MessagingMessageConverter
and BatchMessagingMessageConverter
, as long as Jackson is on the class path.
With the batch converter, the converted headers are available in the KafkaHeaders.BATCH_CONVERTED_HEADERS
as a List<Map<String, Object>>
where the map in a position of the list corresponds to the data position in the payload.
If there is no converter (either because Jackson is not present or it is explicitly set to null
), the headers from the consumer record are provided unconverted in the KafkaHeaders.NATIVE_HEADERS
header.
This header is a Headers
object (or a List<Headers>
in the case of the batch converter), where the position in the list corresponds to the data position in the payload).
Certain types are not suitable for JSON serialization, and a simple toString() serialization might be preferred for these types.
The DefaultKafkaHeaderMapper has a method called addToStringClasses() that lets you supply the names of classes that should be treated this way for outbound mapping.
During inbound mapping, they are mapped as String .
By default, only org.springframework.util.MimeType and org.springframework.http.MediaType are mapped this way.
|
Starting with version 2.3, handling of String-valued headers is simplified.
Such headers are no longer JSON encoded, by default (i.e. they do not have enclosing "…" added).
The type is still added to the JSON_TYPES header so the receiving system can convert back to a String (from byte[] ).
The mapper can handle (decode) headers produced by older versions (it checks for a leading " ); in this way an application using 2.3 can consume records from older versions.
|
To be compatible with earlier versions, set encodeStrings to true , if records produced by a version using 2.3 might be consumed by applications using earlier versions.
When all applications are using 2.3 or higher, you can leave the property at its default value of false .
|
@Bean
MessagingMessageConverter converter() {
MessagingMessageConverter converter = new MessagingMessageConverter();
DefaultKafkaHeaderMapper mapper = new DefaultKafkaHeaderMapper();
mapper.setEncodeStrings(true);
converter.setHeaderMapper(mapper);
return converter;
}
If using Spring Boot, it will auto configure this converter bean into the auto-configured KafkaTemplate
; otherwise you should add this converter to the template.
4.1.19. Null Payloads and Log Compaction of 'Tombstone' Records
When you use Log Compaction, you can send and receive messages with null
payloads to identify the deletion of a key.
You can also receive null
values for other reasons, such as a Deserializer
that might return null
when it cannot deserialize a value.
To send a null
payload by using the KafkaTemplate
, you can pass null into the value argument of the send()
methods.
One exception to this is the send(Message<?> message)
variant.
Since spring-messaging
Message<?>
cannot have a null
payload, you can use a special payload type called KafkaNull
, and the framework sends null
.
For convenience, the static KafkaNull.INSTANCE
is provided.
When you use a message listener container, the received ConsumerRecord
has a null
value()
.
To configure the @KafkaListener
to handle null
payloads, you must use the @Payload
annotation with required = false
.
If it is a tombstone message for a compacted log, you usually also need the key so that your application can determine which key was “deleted”.
The following example shows such a configuration:
@KafkaListener(id = "deletableListener", topics = "myTopic")
public void listen(@Payload(required = false) String value, @Header(KafkaHeaders.RECEIVED_MESSAGE_KEY) String key) {
// value == null represents key deletion
}
When you use a class-level @KafkaListener
with multiple @KafkaHandler
methods, some additional configuration is needed.
Specifically, you need a @KafkaHandler
method with a KafkaNull
payload.
The following example shows how to configure one:
@KafkaListener(id = "multi", topics = "myTopic")
static class MultiListenerBean {
@KafkaHandler
public void listen(String cat) {
...
}
@KafkaHandler
public void listen(Integer hat) {
...
}
@KafkaHandler
public void delete(@Payload(required = false) KafkaNull nul, @Header(KafkaHeaders.RECEIVED_MESSAGE_KEY) int key) {
...
}
}
Note that the argument is null
, not KafkaNull
.
This feature requires the use of a KafkaNullAwarePayloadArgumentResolver which the framework will configure when using the default MessageHandlerMethodFactory .
When using a custom MessageHandlerMethodFactory , see Adding custom HandlerMethodArgumentResolver to @KafkaListener .
|
4.1.20. Handling Exceptions
This section describes how to handle various exceptions that may arise when you use Spring for Apache Kafka.
Listener Error Handlers
Starting with version 2.0, the @KafkaListener
annotation has a new attribute: errorHandler
.
You can use the errorHandler
to provide the bean name of a KafkaListenerErrorHandler
implementation.
This functional interface has one method, as the following listing shows:
@FunctionalInterface
public interface KafkaListenerErrorHandler {
Object handleError(Message<?> message, ListenerExecutionFailedException exception) throws Exception;
}
You have access to the spring-messaging Message<?>
object produced by the message converter and the exception that was thrown by the listener, which is wrapped in a ListenerExecutionFailedException
.
The error handler can throw the original or a new exception, which is thrown to the container.
Anything returned by the error handler is ignored.
Starting with version 2.7, you can set the rawRecordHeader
property on the MessagingMessageConverter
and BatchMessagingMessageConverter
which causes the raw ConsumerRecord
to be added to the converted Message<?>
in the KafkaHeaders.RAW_DATA
header.
This is useful, for example, if you wish to use a DeadLetterPublishingRecoverer
in a listener error handler.
It might be used in a request/reply scenario where you wish to send a failure result to the sender, after some number of retries, after capturing the failed record in a dead letter topic.
@Bean
KafkaListenerErrorHandler eh(DeadLetterPublishingRecoverer recoverer) {
return (msg, ex) -> {
if (msg.getHeaders().get(KafkaHeaders.DELIVERY_ATTEMPT, Integer.class) > 9) {
recoverer.accept(msg.getHeaders().get(KafkaHeaders.RAW_DATA, ConsumerRecord.class), ex);
return "FAILED";
}
throw ex;
};
}
It has a sub-interface (ConsumerAwareListenerErrorHandler
) that has access to the consumer object, through the following method:
Object handleError(Message<?> message, ListenerExecutionFailedException exception, Consumer<?, ?> consumer);
If your error handler implements this interface, you can, for example, adjust the offsets accordingly. For example, to reset the offset to replay the failed message, you could do something like the following:
@Bean
public ConsumerAwareListenerErrorHandler listen3ErrorHandler() {
return (m, e, c) -> {
this.listen3Exception = e;
MessageHeaders headers = m.getHeaders();
c.seek(new org.apache.kafka.common.TopicPartition(
headers.get(KafkaHeaders.RECEIVED_TOPIC, String.class),
headers.get(KafkaHeaders.RECEIVED_PARTITION_ID, Integer.class)),
headers.get(KafkaHeaders.OFFSET, Long.class));
return null;
};
}
Similarly, you could do something like the following for a batch listener:
@Bean
public ConsumerAwareListenerErrorHandler listen10ErrorHandler() {
return (m, e, c) -> {
this.listen10Exception = e;
MessageHeaders headers = m.getHeaders();
List<String> topics = headers.get(KafkaHeaders.RECEIVED_TOPIC, List.class);
List<Integer> partitions = headers.get(KafkaHeaders.RECEIVED_PARTITION_ID, List.class);
List<Long> offsets = headers.get(KafkaHeaders.OFFSET, List.class);
Map<TopicPartition, Long> offsetsToReset = new HashMap<>();
for (int i = 0; i < topics.size(); i++) {
int index = i;
offsetsToReset.compute(new TopicPartition(topics.get(i), partitions.get(i)),
(k, v) -> v == null ? offsets.get(index) : Math.min(v, offsets.get(index)));
}
offsetsToReset.forEach((k, v) -> c.seek(k, v));
return null;
};
}
This resets each topic/partition in the batch to the lowest offset in the batch.
The preceding two examples are simplistic implementations, and you would probably want more checking in the error handler. |
Container Error Handlers
Starting with version 2.8, the legacy ErrorHandler
and BatchErrorHandler
interfaces have been superceded by a new CommonErrorHandler
.
These error handlers can handle errors for both record and batch listeners, allowing a single listener container factory to create containers for both types of listener.
CommonErrorHandler
implementations to replace most legacy framework error handler implementations are provided and the legacy error handlers deprecated.
The legacy interfaces are still supported by listener containers and listener container factories; they will be deprecated in a future release.
When transactions are being used, no error handlers are configured, by default, so that the exception will roll back the transaction.
Error handling for transactional containers are handled by the AfterRollbackProcessor
.
If you provide a custom error handler when using transactions, it must throw an exception if you want the transaction rolled back.
This interface has a default method isAckAfterHandle()
which is called by the container to determine whether the offset(s) should be committed if the error handler returns without throwing an exception; it returns true by default.
Typically, the error handlers provided by the framework will throw an exception when the error is not "handled" (e.g. after performing a seek operation).
By default, such exceptions are logged by the container at ERROR
level.
All of the framework error handlers extend KafkaExceptionLogLevelAware
which allows you to control the level at which these exceptions are logged.
/**
* Set the level at which the exception thrown by this handler is logged.
* @param logLevel the level (default ERROR).
*/
public void setLogLevel(KafkaException.Level logLevel) {
...
}
You can specify a global error handler to be used for all listeners in the container factory. The following example shows how to do so:
@Bean
public KafkaListenerContainerFactory<ConcurrentMessageListenerContainer<Integer, String>>
kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<Integer, String> factory =
new ConcurrentKafkaListenerContainerFactory<>();
...
factory.setCommonErrorHandler(myErrorHandler);
...
return factory;
}
By default, if an annotated listener method throws an exception, it is thrown to the container, and the message is handled according to the container configuration.
The container commits any pending offset commits before calling the error handler.
If you are using Spring Boot, you simply need to add the error handler as a @Bean
and Boot will add it to the auto-configured factory.
DefaultErrorHandler
This new error handler replaces the SeekToCurrentErrorHandler
and RecoveringBatchErrorHandler
, which have been the default error handlers for several releases now.
One difference is that the fallback behavior for batch listeners (when an exception other than a BatchListenerFailedException
is thrown) is the equivalent of the Retrying Batch Error Handler.
The error handler can recover (skip) a record that keeps failing.
By default, after ten failures, the failed record is logged (at the ERROR
level).
You can configure the handler with a custom recoverer (BiConsumer
) and a BackOff
that controls the delivery attempts and delays between each.
Using a FixedBackOff
with FixedBackOff.UNLIMITED_ATTEMPTS
causes (effectively) infinite retries.
The following example configures recovery after three tries:
DefaultErrorHandler errorHandler =
new DefaultErrorHandler((record, exception) -> {
// recover after 3 failures, with no back off - e.g. send to a dead-letter topic
}, new FixedBackOff(0L, 2L));
To configure the listener container with a customized instance of this handler, add it to the container factory.
For example, with the @KafkaListener
container factory, you can add DefaultErrorHandler
as follows:
@Bean
public ConcurrentKafkaListenerContainerFactory<String, String> kafkaListenerContainerFactory() {
ConcurrentKafkaListenerContainerFactory<String, String> factory = new ConcurrentKafkaListenerContainerFactory();
factory.setConsumerFactory(consumerFactory());
factory.getContainerProperties().setAckOnError(false);
factory.getContainerProperties().setAckMode(AckMode.RECORD);
factory.setCommonErrorHandler(new DefaultErrorHandler(new FixedBackOff(1000L, 2L)));
return factory;
}
For a record listener, this will retry a delivery up to 2 times (3 delivery attempts) with a back off of 1 second, instead of the default configuration (FixedBackOff(0L, 9)
).
Failures are simply logged after retries are exhausted.
As an example; if the poll
returns six records (two from each partition 0, 1, 2) and the listener throws an exception on the fourth record, the container acknowledges the first three messages by committing their offsets.
The DefaultErrorHandler
seeks to offset 1 for partition 1 and offset 0 for partition 2.
The next poll()
returns the three unprocessed records.
If the AckMode
was BATCH
, the container commits the offsets for the first two partitions before calling the error handler.
For a batch listener, the listener must throw a BatchListenerFailedException
indicating which records in the batch failed.
The sequence of events is:
-
Commit the offsets of the records before the index.
-
If retries are not exhausted, perform seeks so that all the remaining records (including the failed record) will be redelivered.
-
If retries are exhausted, attempt recovery of the failed record (default log only) and perform seeks so that the remaining records (excluding the failed record) will be redelivered. The recovered record’s offset is committed
-
If retries are exhausted and recovery fails, seeks are performed as if retries are not exhausted.
The default recoverer logs the failed record after retries are exhausted.
You can use a custom recoverer, or one provided by the framework such as the DeadLetterPublishingRecoverer
.
When using a POJO batch listener (e.g. List<Thing>
), and you don’t have the full consumer record to add to the exception, you can just add the index of the record that failed:
@KafkaListener(id = "recovering", topics = "someTopic")
public void listen(List<Thing> things) {
for (int i = 0; i < records.size(); i++) {
try {
process(things.get(i));
}
catch (Exception e) {
throw new BatchListenerFailedException("Failed to process", i);
}
}
}
When the container is configured with AckMode.MANUAL_IMMEDIATE
, the error handler can be configured to commit the offset of recovered records; set the commitRecovered
property to true
.
See also Publishing Dead-letter Records.
When using transactions, similar functionality is provided by the DefaultAfterRollbackProcessor
.
See After-rollback Processor.
The DefaultErrorHandler
considers certain exceptions to be fatal, and retries are skipped for such exceptions; the recoverer is invoked on the first failure.
The exceptions that are considered fatal, by default, are:
-
DeserializationException
-
MessageConversionException
-
ConversionException
-
MethodArgumentResolutionException
-
NoSuchMethodException
-
ClassCastException
since these exceptions are unlikely to be resolved on a retried delivery.
You can add more exception types to the not-retryable category, or completely replace the map of classified exceptions.
See the Javadocs for DefaultErrorHandler.addNotRetryableException()
and DefaultErrorHandler.setClassifications()
for more information, as well as those for the spring-retry
BinaryExceptionClassifier
.
Here is an example that adds IllegalArgumentException
to the not-retryable exceptions:
@Bean
public DefaultErrorHandler errorHandler(ConsumerRecordRecoverer recoverer) {
DefaultErrorHandler handler = new DefaultErrorHandler(recoverer);
handler.addNotRetryableExceptions(IllegalArgumentException.class);
return handler;
}
The error handler can be configured with one or more RetryListener
s, receiving notifications of retry and recovery progress.
@FunctionalInterface
public interface RetryListener {
void failedDelivery(ConsumerRecord<?, ?> record, Exception ex, int deliveryAttempt);
default void recovered(ConsumerRecord<?, ?> record, Exception ex) {
}
default void recoveryFailed(ConsumerRecord<?, ?> record, Exception original, Exception failure) {
}
}
See the javadocs for more information.
If the recoverer fails (throws an exception), the failed record will be included in the seeks.
If the recoverer fails, the BackOff will be reset by default and redeliveries will again go through the back offs before recovery is attempted again.
To skip retries after a recovery failure, set the error handler’s resetStateOnRecoveryFailure to false .
|
You can provide the error handler with a BiFunction<ConsumerRecord<?, ?>, Exception, BackOff>
to determine the BackOff
to use, based on the failed record and/or the exception:
handler.setBackOffFunction((record, ex) -> { ... });
If the function returns null
, the handler’s default BackOff
will be used.
Set resetStateOnExceptionChange
to true
and the retry sequence will be restarted (including the selection of a new BackOff
, if so configured) if the exception type changes between failures.
By default, the exception type is not considered.
Also see Delivery Attempts Header.
4.1.21. Conversion Errors with Batch Error Handlers
Starting with version 2.8, batch listeners can now properly handle conversion errors, when using a MessageConverter
with a ByteArrayDeserializer
, a BytesDeserializer
or a StringDeserializer
, as well as a DefaultErrorHandler
.
When a conversion error occurs, the payload is set to null and a deserialization exception is added to the record headers, similar to the ErrorHandlingDeserializer
.
A list of ConversionException
s is available in the listener so the listener can throw a BatchListenerFailedException
indicating the first index at which a conversion exception occurred.
Example:
@KafkaListener(id = "test", topics = "topic")
void listen(List<Thing> in, @Header(KafkaHeaders.CONVERSION_FAILURES) List<ConversionException> exceptions) {
for (int i = 0; i < in.size(); i++) {
Foo foo = in.get(i);
if (foo == null && exceptions.get(i) != null) {
throw new BatchListenerFailedException("Conversion error", exceptions.get(i), i);
}
process(foo);
}
}
---
Retrying Batch Error Handler
This legacy BatchErrorHandler
is not deprecated at this time; it is used as the fallback when using the DefaultErrorHandler
and some exception other than BatchListenerFailedException
is thrown by the listener.
There is no guarantee that, when a batch is redelivered, the batch has the same number of records and/or the redelivered records are in the same order.
It is impossible, therefore, to maintain retry state for a batch.
The RetryingBatchErrorHandler
takes a the following approach.
If a batch listener throws an exception, and this error handler is configured (or used as the fallback described above), the retries are performed from the in-memory batch of records.
In order to avoid a rebalance during an extended retry sequence, the error handler pauses the consumer, polls it before sleeping for the back off, for each retry, and calls the listener again.
If/when retries are exhausted, the ConsumerRecordRecoverer
is called for each record in the batch.
If the recoverer throws an exception, or the thread is interrupted during its sleep, a SeekToCurrentErrorHandler
is invoked so that the batch of records will be redelivered on the next poll.
Before exiting, regardless of the outcome, the consumer is resumed.
This error handler cannot be used with transactions. |
While waiting for a BackOff
interval, the error handler will loop with a short sleep until the desired delay is reached, while checking to see if the container has been stopped, allowing the sleep to exit soon after the stop()
rather than causing a delay.
Container Stopping Error Handlers
The CommonContainerStoppingErrorHandler
stops the container if the listener throws an exception.
For record listeners, when the AckMode
is RECORD
, offsets for already processed records are committed.
For record listeners, when the AckMode
is any manual value, offsets for already acknowledged records are committed.
For record listeners, wWhen the AckMode
is BATCH
, or for batch listeners, the entire batch is replayed when the container is restarted.
After the container stops, an exception that wraps the ListenerExecutionFailedException
is thrown.
This is to cause the transaction to roll back (if transactions are enabled).
Delegating Error Handler
The CommonDelegatingErrorHandler
can delegate to different error handlers, depending on the exception type.
For example, you may wish to invoke a DefaultErrorHandler
for most exceptions, or a CommonContainerStoppingErrorHandler
for others.
Logging Error Handler
The CommonLoggingErrorHandler
simply logs the exception; with a record listener, the remaining records from the previous poll are passed to the listener.
For a batch listener, all the records in the batch are logged.
Using Different Common Error Handlers for Record and Batch Listeners
If you wish to use a different error handling strategy for record and batch listeners, the CommonMixedErrorHandler
is provided allowing the configuration of a specific error handler for each listener type.
Common Error Handler Summery
-
DefaultErrorHandler
-
CommonContainerStoppingErrorHandler
-
CommonDelegatingErrorHandler
-
CommonLoggingErrorHandler
-
CommonMixedErrorHandler
Legacy Error Handlers and Their Replacements
Legacy Error Handler | Replacement |
---|---|
|
|
|
|
|
|
|
|
|
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|
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No replacement, use |
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No replacements - use |
After-rollback Processor
When using transactions, if the listener throws an exception (and an error handler, if present, throws an exception), the transaction is rolled back.
By default, any unprocessed records (including the failed record) are re-fetched on the next poll.
This is achieved by performing seek
operations in the DefaultAfterRollbackProcessor
.
With a batch listener, the entire batch of records is reprocessed (the container has no knowledge of which record in the batch failed).
To modify this behavior, you can configure the listener container with a custom AfterRollbackProcessor
.
For example, with a record-based listener, you might want to keep track of the failed record and give up after some number of attempts, perhaps by publishing it to a dead-letter topic.
Starting with version 2.2, the DefaultAfterRollbackProcessor
can now recover (skip) a record that keeps failing.
By default, after ten failures, the failed record is logged (at the ERROR
level).
You can configure the processor with a custom recoverer (BiConsumer
) and maximum failures.
Setting the maxFailures
property to a negative number causes infinite retries.
The following example configures recovery after three tries:
AfterRollbackProcessor<String, String> processor =
new DefaultAfterRollbackProcessor((record, exception) -> {
// recover after 3 failures, with no back off - e.g. send to a dead-letter topic
}, new FixedBackOff(0L, 2L));
When you do not use transactions, you can achieve similar functionality by configuring a DefaultErrorHandler
.
See Container Error Handlers.
Recovery is not possible with a batch listener, since the framework has no knowledge about which record in the batch keeps failing. In such cases, the application listener must handle a record that keeps failing. |
See also Publishing Dead-letter Records.
Starting with version 2.2.5, the DefaultAfterRollbackProcessor
can be invoked in a new transaction (started after the failed transaction rolls back).
Then, if you are using the DeadLetterPublishingRecoverer
to publish a failed record, the processor will send the recovered record’s offset in the original topic/partition to the transaction.
To enable this feature, set the commitRecovered
and kafkaTemplate
properties on the DefaultAfterRollbackProcessor
.
If the recoverer fails (throws an exception), the failed record will be included in the seeks.
Starting with version 2.5.5, if the recoverer fails, the BackOff will be reset by default and redeliveries will again go through the back offs before recovery is attempted again.
With earlier versions, the BackOff was not reset and recovery was re-attempted on the next failure.
To revert to the previous behavior, set the processor’s resetStateOnRecoveryFailure property to false .
|
Starting with version 2.6, you can now provide the processor with a BiFunction<ConsumerRecord<?, ?>, Exception, BackOff>
to determine the BackOff
to use, based on the failed record and/or the exception:
handler.setBackOffFunction((record, ex) -> { ... });
If the function returns null
, the processor’s default BackOff
will be used.
Starting with version 2.6.3, set resetStateOnExceptionChange
to true
and the retry sequence will be restarted (including the selection of a new BackOff
, if so configured) if the exception type changes between failures.
By default, the exception type is not considered.
Starting with version 2.3.1, similar to the DefaultErrorHandler
, the DefaultAfterRollbackProcessor
considers certain exceptions to be fatal, and retries are skipped for such exceptions; the recoverer is invoked on the first failure.
The exceptions that are considered fatal, by default, are:
-
DeserializationException
-
MessageConversionException
-
ConversionException
-
MethodArgumentResolutionException
-
NoSuchMethodException
-
ClassCastException
since these exceptions are unlikely to be resolved on a retried delivery.
You can add more exception types to the not-retryable category, or completely replace the map of classified exceptions.
See the Javadocs for DefaultAfterRollbackProcessor.setClassifications()
for more information, as well as those for the spring-retry
BinaryExceptionClassifier
.
Here is an example that adds IllegalArgumentException
to the not-retryable exceptions:
@Bean
public DefaultAfterRollbackProcessor errorHandler(BiConsumer<ConsumerRecord<?, ?>, Exception> recoverer) {
DefaultAfterRollbackProcessor processor = new DefaultAfterRollbackProcessor(recoverer);
processor.addNotRetryableException(IllegalArgumentException.class);
return processor;
}
Also see Delivery Attempts Header.
With current kafka-clients , the container cannot detect whether a ProducerFencedException is caused by a rebalance or if the producer’s transactional.id has been revoked due to a timeout or expiry.
Because, in most cases, it is caused by a rebalance, the container does not call the AfterRollbackProcessor (because it’s not appropriate to seek the partitions because we no longer are assigned them).
If you ensure the timeout is large enough to process each transaction and periodically perform an "empty" transaction (e.g. via a ListenerContainerIdleEvent ) you can avoid fencing due to timeout and expiry.
Or, you can set the stopContainerWhenFenced container property to true and the container will stop, avoiding the loss of records.
You can consume a ConsumerStoppedEvent and check the Reason property for FENCED to detect this condition.
Since the event also has a reference to the container, you can restart the container using this event.
|
Starting with version 2.7, while waiting for a BackOff
interval, the error handler will loop with a short sleep until the desired delay is reached, while checking to see if the container has been stopped, allowing the sleep to exit soon after the stop()
rather than causing a delay.
Starting with version 2.7, the processor can be configured with one or more RetryListener
s, receiving notifications of retry and recovery progress.
@FunctionalInterface
public interface RetryListener {
void failedDelivery(ConsumerRecord<?, ?> record, Exception ex, int deliveryAttempt);
default void recovered(ConsumerRecord<?, ?> record, Exception ex) {
}
default void recoveryFailed(ConsumerRecord<?, ?> record, Exception original, Exception failure) {
}
}
See the javadocs for more information.
Delivery Attempts Header
The following applies to record listeners only, not batch listeners.
Starting with version 2.5, when using an ErrorHandler
or AfterRollbackProcessor
that implements DeliveryAttemptAware
, it is possible to enable the addition of the KafkaHeaders.DELIVERY_ATTEMPT
header (kafka_deliveryAttempt
) to the record.
The value of this header is an incrementing integer starting at 1.
When receiving a raw ConsumerRecord<?, ?>
the integer is in a byte[4]
.
int delivery = ByteBuffer.wrap(record.headers()
.lastHeader(KafkaHeaders.DELIVERY_ATTEMPT).value())
.getInt()
When using @KafkaListener
with the DefaultKafkaHeaderMapper
or SimpleKafkaHeaderMapper
, it can be obtained by adding @Header(KafkaHeaders.DELIVERY_ATTEMPT) int delivery
as a parameter to the listener method.
To enable population of this header, set the container property deliveryAttemptHeader
to true
.
It is disabled by default to avoid the (small) overhead of looking up the state for each record and adding the header.
The DefaultErrorHandler
and DefaultAfterRollbackProcessor
support this feature.
Publishing Dead-letter Records
You can configure the DefaultErrorHandler
and DefaultAfterRollbackProcessor
with a record recoverer when the maximum number of failures is reached for a record.
The framework provides the DeadLetterPublishingRecoverer
, which publishes the failed message to another topic.
The recoverer requires a KafkaTemplate<Object, Object>
, which is used to send the record.
You can also, optionally, configure it with a BiFunction<ConsumerRecord<?, ?>, Exception, TopicPartition>
, which is called to resolve the destination topic and partition.
By default, the dead-letter record is sent to a topic named <originalTopic>.DLT (the original topic name suffixed with .DLT ) and to the same partition as the original record.
Therefore, when you use the default resolver, the dead-letter topic must have at least as many partitions as the original topic.
|
If the returned TopicPartition
has a negative partition, the partition is not set in the ProducerRecord
, so the partition is selected by Kafka.
Starting with version 2.2.4, any ListenerExecutionFailedException
(thrown, for example, when an exception is detected in a @KafkaListener
method) is enhanced with the groupId
property.
This allows the destination resolver to use this, in addition to the information in the ConsumerRecord
to select the dead letter topic.
The following example shows how to wire a custom destination resolver:
DeadLetterPublishingRecoverer recoverer = new DeadLetterPublishingRecoverer(template,
(r, e) -> {
if (e instanceof FooException) {
return new TopicPartition(r.topic() + ".Foo.failures", r.partition());
}
else {
return new TopicPartition(r.topic() + ".other.failures", r.partition());
}
});
ErrorHandler errorHandler = new DefaultErrorHandler(recoverer, new FixedBackOff(0L, 2L));
The record sent to the dead-letter topic is enhanced with the following headers:
-
KafkaHeaders.DLT_EXCEPTION_FQCN
: The Exception class name (generally aListenerExecutionFailedException
, but can be others). -
KafkaHeaders.DLT_EXCEPTION_CAUSE_FQCN
: The Exception cause class name, if present (since version 2.8). -
KafkaHeaders.DLT_EXCEPTION_STACKTRACE
: The Exception stack trace. -
KafkaHeaders.DLT_EXCEPTION_MESSAGE
: The Exception message. -
KafkaHeaders.DLT_KEY_EXCEPTION_FQCN
: The Exception class name (key deserialization errors only). -
KafkaHeaders.DLT_KEY_EXCEPTION_STACKTRACE
: The Exception stack trace (key deserialization errors only). -
KafkaHeaders.DLT_KEY_EXCEPTION_MESSAGE
: The Exception message (key deserialization errors only). -
KafkaHeaders.DLT_ORIGINAL_TOPIC
: The original topic. -
KafkaHeaders.DLT_ORIGINAL_PARTITION
: The original partition. -
KafkaHeaders.DLT_ORIGINAL_OFFSET
: The original offset. -
KafkaHeaders.DLT_ORIGINAL_TIMESTAMP
: The original timestamp. -
KafkaHeaders.DLT_ORIGINAL_TIMESTAMP_TYPE
: The original timestamp type. -
KafkaHeaders.DLT_ORIGINAL_CONSUMER_GROUP
: The original consumer group that failed to process the record (since version 2.8).
Key exceptions are only caused by DeserializationException
s so there is no DLT_KEY_EXCEPTION_CAUSE_FQCN
.
There are two mechanisms to add more headers.
-
Subclass the recoverer and override
createProducerRecord()
- callsuper.createProducerRecord()
and add more headers. -
Provide a
BiFunction
to receive the consumer record and exception, returning aHeaders
object; headers from there will be copied to the final producer record. UsesetHeadersFunction()
to set theBiFunction
.
The second is simpler to implement but the first has more information available, including the already assembled standard headers.
Starting with version 2.3, when used in conjunction with an ErrorHandlingDeserializer
, the publisher will restore the record value()
, in the dead-letter producer record, to the original value that failed to be deserialized.
Previously, the value()
was null and user code had to decode the DeserializationException
from the message headers.
In addition, you can provide multiple KafkaTemplate
s to the publisher; this might be needed, for example, if you want to publish the byte[]
from a DeserializationException
, as well as values using a different serializer from records that were deserialized successfully.
Here is an example of configuring the publisher with KafkaTemplate
s that use a String
and byte[]
serializer:
@Bean
public DeadLetterPublishingRecoverer publisher(KafkaTemplate<?, ?> stringTemplate,
KafkaTemplate<?, ?> bytesTemplate) {
Map<Class<?>, KafkaTemplate<?, ?>> templates = new LinkedHashMap<>();
templates.put(String.class, stringTemplate);
templates.put(byte[].class, bytesTemplate);
return new DeadLetterPublishingRecoverer(templates);
}
The publisher uses the map keys to locate a template that is suitable for the value()
about to be published.
A LinkedHashMap
is recommended so that the keys are examined in order.
When publishing null
values, when there are multiple templates, the recoverer will look for a template for the Void
class; if none is present, the first template from the values().iterator()
will be used.
Since 2.7 you can use the setFailIfSendResultIsError
method so that an exception is thrown when message publishing fails.
You can also set a timeout for the verification of the sender success with setWaitForSendResultTimeout
.
If the recoverer fails (throws an exception), the failed record will be included in the seeks.
Starting with version 2.5.5, if the recoverer fails, the BackOff will be reset by default and redeliveries will again go through the back offs before recovery is attempted again.
With earlier versions, the BackOff was not reset and recovery was re-attempted on the next failure.
To revert to the previous behavior, set the error handler’s resetStateOnRecoveryFailure property to false .
|
Starting with version 2.6.3, set resetStateOnExceptionChange
to true
and the retry sequence will be restarted (including the selection of a new BackOff
, if so configured) if the exception type changes between failures.
By default, the exception type is not considered.
Starting with version 2.3, the recoverer can also be used with Kafka Streams - see Recovery from Deserialization Exceptions for more information.
The ErrorHandlingDeserializer
adds the deserialization exception(s) in headers ErrorHandlingDeserializer.VALUE_DESERIALIZER_EXCEPTION_HEADER
and ErrorHandlingDeserializer.KEY_DESERIALIZER_EXCEPTION_HEADER
(using java serialization).
By default, these headers are not retained in the message published to the dead letter topic.
Starting with version 2.7, if both the key and value fail deserialization, the original values of both are populated in the record sent to the DLT.
If incoming records are dependent on each other, but may arrive out of order, it may be useful to republish a failed record to the tail of the original topic (for some number of times), instead of sending it directly to the dead letter topic. See this Stack Overflow Question for an example.
The following error handler configuration will do exactly that:
@Bean
public ErrorHandler eh(KafkaOperations<String, String> template) {
return new DefaultErrorHandler(new DeadLetterPublishingRecoverer(template,
(rec, ex) -> {
org.apache.kafka.common.header.Header retries = rec.headers().lastHeader("retries");
if (retries == null) {
retries = new RecordHeader("retries", new byte[] { 1 });
rec.headers().add(retries);
}
else {
retries.value()[0]++;
}
return retries.value()[0] > 5
? new TopicPartition("topic.DLT", rec.partition())
: new TopicPartition("topic", rec.partition());
}), new FixedBackOff(0L, 0L));
}
Starting with version 2.7, the recoverer checks that the partition selected by the destination resolver actually exists.
If the partition is not present, the partition in the ProducerRecord
is set to null
, allowing the KafkaProducer
to select the partition.
You can disable this check by setting the verifyPartition
property to false
.
Managing Dead Letter Record Headers
Referring to Publishing Dead-letter Records above, the DeadLetterPublishingRecoverer
has two properties used to manage headers when those headers already exist (such as when reprocessing a dead letter record that failed, including when using Non-Blocking Retries).
-
appendOriginalHeaders
(defaulttrue
) -
stripPreviousExceptionHeaders
(defaulttrue
since version 2.8)
Apache Kafka supports multiple headers with the same name; to obtain the "latest" value, you can use headers.lastHeader(headerName)
; to get an iterator over multiple headers, use headers.headers(headerName).iterator()
.
When repeatedly republishing a failed record, these headers can grow (and eventually cause publication to fail due to a RecordTooLargeException
); this is especially true for the exception headers and particularly for the stack trace headers.
The reason for the two properties is because, while you might want to retain only the last exception information, you might want to retain the history of which topic(s) the record passed through for each failure.
appendOriginalHeaders
is applied to all headers named ORIGINAL
while stripPreviousExceptionHeaders
is applied to all headers named EXCEPTION
.
Also see Failure Header Management with Non-Blocking Retries.
ExponentialBackOffWithMaxRetries
Implementation
Spring Framework provides a number of BackOff
implementations.
By default, the ExponentialBackOff
will retry indefinitely; to give up after some number of retry attempts requires calculating the maxElapsedTime
.
Since version 2.7.3, Spring for Apache Kafka provides the ExponentialBackOffWithMaxRetries
which is a subclass that receives the maxRetries
property and automatically calculates the maxElapsedTime
, which is a little more convenient.
@Bean
DefaultErrorHandler handler() {
ExponentialBackOffWithMaxRetries bo = new ExponentialBackOffWithMaxRetries(6);
bo.setInitialInterval(1_000L);
bo.setMultiplier(2.0);
bo.setMaxInterval(10_000L);
return new DefaultErrorHandler(myRecoverer, bo);
}
This will retry after 1, 2, 4, 8, 10, 10
seconds, before calling the recoverer.
4.1.22. JAAS and Kerberos
Starting with version 2.0, a KafkaJaasLoginModuleInitializer
class has been added to assist with Kerberos configuration.
You can add this bean, with the desired configuration, to your application context.
The following example configures such a bean:
@Bean
public KafkaJaasLoginModuleInitializer jaasConfig() throws IOException {
KafkaJaasLoginModuleInitializer jaasConfig = new KafkaJaasLoginModuleInitializer();
jaasConfig.setControlFlag("REQUIRED");
Map<String, String> options = new HashMap<>();
options.put("useKeyTab", "true");
options.put("storeKey", "true");
options.put("keyTab", "/etc/security/keytabs/kafka_client.keytab");
options.put("principal", "[email protected]");
jaasConfig.setOptions(options);
return jaasConfig;
}
4.2. Apache Kafka Streams Support
Starting with version 1.1.4, Spring for Apache Kafka provides first-class support for Kafka Streams.
To use it from a Spring application, the kafka-streams
jar must be present on classpath.
It is an optional dependency of the Spring for Apache Kafka project and is not downloaded transitively.
4.2.1. Basics
The reference Apache Kafka Streams documentation suggests the following way of using the API:
// Use the builders to define the actual processing topology, e.g. to specify
// from which input topics to read, which stream operations (filter, map, etc.)
// should be called, and so on.
StreamsBuilder builder = ...; // when using the Kafka Streams DSL
// Use the configuration to tell your application where the Kafka cluster is,
// which serializers/deserializers to use by default, to specify security settings,
// and so on.
StreamsConfig config = ...;
KafkaStreams streams = new KafkaStreams(builder, config);
// Start the Kafka Streams instance
streams.start();
// Stop the Kafka Streams instance
streams.close();
So, we have two main components:
-
StreamsBuilder
: With an API to buildKStream
(orKTable
) instances. -
KafkaStreams
: To manage the lifecycle of those instances.
All KStream instances exposed to a KafkaStreams instance by a single StreamsBuilder are started and stopped at the same time, even if they have different logic.
In other words, all streams defined by a StreamsBuilder are tied with a single lifecycle control.
Once a KafkaStreams instance has been closed by streams.close() , it cannot be restarted.
Instead, a new KafkaStreams instance to restart stream processing must be created.
|
4.2.2. Spring Management
To simplify using Kafka Streams from the Spring application context perspective and use the lifecycle management through a container, the Spring for Apache Kafka introduces StreamsBuilderFactoryBean
.
This is an AbstractFactoryBean
implementation to expose a StreamsBuilder
singleton instance as a bean.
The following example creates such a bean:
@Bean
public FactoryBean<StreamsBuilder> myKStreamBuilder(KafkaStreamsConfiguration streamsConfig) {
return new StreamsBuilderFactoryBean(streamsConfig);
}
Starting with version 2.2, the stream configuration is now provided as a KafkaStreamsConfiguration object rather than a StreamsConfig .
|
The StreamsBuilderFactoryBean
also implements SmartLifecycle
to manage the lifecycle of an internal KafkaStreams
instance.
Similar to the Kafka Streams API, you must define the KStream
instances before you start the KafkaStreams
.
That also applies for the Spring API for Kafka Streams.
Therefore, when you use default autoStartup = true
on the StreamsBuilderFactoryBean
, you must declare KStream
instances on the StreamsBuilder
before the application context is refreshed.
For example, KStream
can be a regular bean definition, while the Kafka Streams API is used without any impacts.
The following example shows how to do so:
@Bean
public KStream<?, ?> kStream(StreamsBuilder kStreamBuilder) {
KStream<Integer, String> stream = kStreamBuilder.stream(STREAMING_TOPIC1);
// Fluent KStream API
return stream;
}
If you would like to control the lifecycle manually (for example, stopping and starting by some condition), you can reference the StreamsBuilderFactoryBean
bean directly by using the factory bean (&
) prefix.
Since StreamsBuilderFactoryBean
use its internal KafkaStreams
instance, it is safe to stop and restart it again.
A new KafkaStreams
is created on each start()
.
You might also consider using different StreamsBuilderFactoryBean
instances, if you would like to control the lifecycles for KStream
instances separately.
You also can specify KafkaStreams.StateListener
, Thread.UncaughtExceptionHandler
, and StateRestoreListener
options on the StreamsBuilderFactoryBean
, which are delegated to the internal KafkaStreams
instance.
Also, apart from setting those options indirectly on StreamsBuilderFactoryBean
, starting with version 2.1.5, you can use a KafkaStreamsCustomizer
callback interface to configure an inner KafkaStreams
instance.
Note that KafkaStreamsCustomizer
overrides the options provided by StreamsBuilderFactoryBean
.
If you need to perform some KafkaStreams
operations directly, you can access that internal KafkaStreams
instance by using StreamsBuilderFactoryBean.getKafkaStreams()
.
You can autowire StreamsBuilderFactoryBean
bean by type, but you should be sure to use the full type in the bean definition, as the following example shows:
@Bean
public StreamsBuilderFactoryBean myKStreamBuilder(KafkaStreamsConfiguration streamsConfig) {
return new StreamsBuilderFactoryBean(streamsConfig);
}
...
@Autowired
private StreamsBuilderFactoryBean myKStreamBuilderFactoryBean;
Alternatively, you can add @Qualifier
for injection by name if you use interface bean definition.
The following example shows how to do so:
@Bean
public FactoryBean<StreamsBuilder> myKStreamBuilder(KafkaStreamsConfiguration streamsConfig) {
return new StreamsBuilderFactoryBean(streamsConfig);
}
...
@Autowired
@Qualifier("&myKStreamBuilder")
private StreamsBuilderFactoryBean myKStreamBuilderFactoryBean;
Starting with version 2.4.1, the factory bean has a new property infrastructureCustomizer
with type KafkaStreamsInfrastructureCustomizer
; this allows customization of the StreamsBuilder
(e.g. to add a state store) and/or the Topology
before the stream is created.
public interface KafkaStreamsInfrastructureCustomizer {
void configureBuilder(StreamsBuilder builder);
void configureTopology(Topology topology);
}
Default no-op implementations are provided to avoid having to implement both methods if one is not required.
A CompositeKafkaStreamsInfrastructureCustomizer
is provided, for when you need to apply multiple customizers.
4.2.3. KafkaStreams Micrometer Support
Introduced in version 2.5.3, you can configure a KafkaStreamsMicrometerListener
to automatically register micrometer meters for the KafkaStreams
object managed by the factory bean:
streamsBuilderFactoryBean.addListener(new KafkaStreamsMicrometerListener(meterRegistry,
Collections.singletonList(new ImmutableTag("customTag", "customTagValue"))));
4.2.4. Streams JSON Serialization and Deserialization
For serializing and deserializing data when reading or writing to topics or state stores in JSON format, Spring for Apache Kafka provides a JsonSerde
implementation that uses JSON, delegating to the JsonSerializer
and JsonDeserializer
described in Serialization, Deserialization, and Message Conversion.
The JsonSerde
implementation provides the same configuration options through its constructor (target type or ObjectMapper
).
In the following example, we use the JsonSerde
to serialize and deserialize the Cat
payload of a Kafka stream (the JsonSerde
can be used in a similar fashion wherever an instance is required):
stream.through(Serdes.Integer(), new JsonSerde<>(Cat.class), "cats");
When constructing the serializer/deserializer programmatically for use in the producer/consumer factory, since version 2.3, you can use the fluent API, which simplifies configuration.
stream.through(new JsonSerde<>(MyKeyType.class)
.forKeys()
.noTypeInfo(),
new JsonSerde<>(MyValueType.class)
.noTypeInfo(),
"myTypes");
4.2.5. Using KafkaStreamBrancher
The KafkaStreamBrancher
class introduces a more convenient way to build conditional branches on top of KStream
.
Consider the following example that does not use KafkaStreamBrancher
:
KStream<String, String>[] branches = builder.stream("source").branch(
(key, value) -> value.contains("A"),
(key, value) -> value.contains("B"),
(key, value) -> true
);
branches[0].to("A");
branches[1].to("B");
branches[2].to("C");
The following example uses KafkaStreamBrancher
:
new KafkaStreamBrancher<String, String>()
.branch((key, value) -> value.contains("A"), ks -> ks.to("A"))
.branch((key, value) -> value.contains("B"), ks -> ks.to("B"))
//default branch should not necessarily be defined in the end of the chain!
.defaultBranch(ks -> ks.to("C"))
.onTopOf(builder.stream("source"));
//onTopOf method returns the provided stream so we can continue with method chaining
4.2.6. Configuration
To configure the Kafka Streams environment, the StreamsBuilderFactoryBean
requires a KafkaStreamsConfiguration
instance.
See the Apache Kafka documentation for all possible options.
Starting with version 2.2, the stream configuration is now provided as a KafkaStreamsConfiguration object, rather than as a StreamsConfig .
|
To avoid boilerplate code for most cases, especially when you develop microservices, Spring for Apache Kafka provides the @EnableKafkaStreams
annotation, which you should place on a @Configuration
class.
All you need is to declare a KafkaStreamsConfiguration
bean named defaultKafkaStreamsConfig
.
A StreamsBuilderFactoryBean
bean, named defaultKafkaStreamsBuilder
, is automatically declared in the application context.
You can declare and use any additional StreamsBuilderFactoryBean
beans as well.
You can perform additional customization of that bean, by providing a bean that implements StreamsBuilderFactoryBeanConfigurer
.
If there are multiple such beans, they will be applied according to their Ordered.order
property.
By default, when the factory bean is stopped, the KafkaStreams.cleanUp()
method is called.
Starting with version 2.1.2, the factory bean has additional constructors, taking a CleanupConfig
object that has properties to let you control whether the cleanUp()
method is called during start()
or stop()
or neither.
Starting with version 2.7, the default is to never clean up local state.
4.2.7. Header Enricher
Version 2.3 added the HeaderEnricher
implementation of Transformer
.
This can be used to add headers within the stream processing; the header values are SpEL expressions; the root object of the expression evaluation has 3 properties:
-
context
- theProcessorContext
, allowing access to the current record metadata -
key
- the key of the current record -
value
- the value of the current record
The expressions must return a byte[]
or a String
(which will be converted to byte[]
using UTF-8
).
To use the enricher within a stream:
.transform(() -> enricher)
The transformer does not change the key
or value
; it simply adds headers.
If your stream is multi-threaded, you need a new instance for each record. |
.transform(() -> new HeaderEnricher<..., ...>(expressionMap))
Here is a simple example, adding one literal header and one variable:
Map<String, Expression> headers = new HashMap<>();
headers.put("header1", new LiteralExpression("value1"));
SpelExpressionParser parser = new SpelExpressionParser();
headers.put("header2", parser.parseExpression("context.timestamp() + ' @' + context.offset()"));
HeaderEnricher<String, String> enricher = new HeaderEnricher<>(headers);
KStream<String, String> stream = builder.stream(INPUT);
stream
.transform(() -> enricher)
.to(OUTPUT);
4.2.8. MessagingTransformer
Version 2.3 added the MessagingTransformer
this allows a Kafka Streams topology to interact with a Spring Messaging component, such as a Spring Integration flow.
The transformer requires an implementation of MessagingFunction
.
@FunctionalInterface
public interface MessagingFunction {
Message<?> exchange(Message<?> message);
}
Spring Integration automatically provides an implementation using its GatewayProxyFactoryBean
.
It also requires a MessagingMessageConverter
to convert the key, value and metadata (including headers) to/from a Spring Messaging Message<?>
.
See [Calling a Spring Integration Flow from a KStream
] for more information.
4.2.9. Recovery from Deserialization Exceptions
Version 2.3 introduced the RecoveringDeserializationExceptionHandler
which can take some action when a deserialization exception occurs.
Refer to the Kafka documentation about DeserializationExceptionHandler
, of which the RecoveringDeserializationExceptionHandler
is an implementation.
The RecoveringDeserializationExceptionHandler
is configured with a ConsumerRecordRecoverer
implementation.
The framework provides the DeadLetterPublishingRecoverer
which sends the failed record to a dead-letter topic.
See Publishing Dead-letter Records for more information about this recoverer.
To configure the recoverer, add the following properties to your streams configuration:
@Bean(name = KafkaStreamsDefaultConfiguration.DEFAULT_STREAMS_CONFIG_BEAN_NAME)
public KafkaStreamsConfiguration kStreamsConfigs() {
Map<String, Object> props = new HashMap<>();
...
props.put(StreamsConfig.DEFAULT_DESERIALIZATION_EXCEPTION_HANDLER_CLASS_CONFIG,
RecoveringDeserializationExceptionHandler.class);
props.put(RecoveringDeserializationExceptionHandler.KSTREAM_DESERIALIZATION_RECOVERER, recoverer());
...
return new KafkaStreamsConfiguration(props);
}
@Bean
public DeadLetterPublishingRecoverer recoverer() {
return new DeadLetterPublishingRecoverer(kafkaTemplate(),
(record, ex) -> new TopicPartition("recovererDLQ", -1));
}
Of course, the recoverer()
bean can be your own implementation of ConsumerRecordRecoverer
.
4.2.10. Kafka Streams Example
The following example combines all the topics we have covered in this chapter:
@Configuration
@EnableKafka
@EnableKafkaStreams
public static class KafkaStreamsConfig {
@Bean(name = KafkaStreamsDefaultConfiguration.DEFAULT_STREAMS_CONFIG_BEAN_NAME)
public KafkaStreamsConfiguration kStreamsConfigs() {
Map<String, Object> props = new HashMap<>();
props.put(StreamsConfig.APPLICATION_ID_CONFIG, "testStreams");
props.put(StreamsConfig.BOOTSTRAP_SERVERS_CONFIG, "localhost:9092");
props.put(StreamsConfig.DEFAULT_KEY_SERDE_CLASS_CONFIG, Serdes.Integer().getClass().getName());
props.put(StreamsConfig.DEFAULT_VALUE_SERDE_CLASS_CONFIG, Serdes.String().getClass().getName());
props.put(StreamsConfig.DEFAULT_TIMESTAMP_EXTRACTOR_CLASS_CONFIG, WallclockTimestampExtractor.class.getName());
return new KafkaStreamsConfiguration(props);
}
@Bean
public StreamsBuilderFactoryBeanConfigurer configurer() {
return fb -> fb.setStateListener((newState, oldState) -> {
System.out.println("State transition from " + oldState + " to " + newState);
});
}
@Bean
public KStream<Integer, String> kStream(StreamsBuilder kStreamBuilder) {
KStream<Integer, String> stream = kStreamBuilder.stream("streamingTopic1");
stream
.mapValues((ValueMapper<String, String>) String::toUpperCase)
.groupByKey()
.windowedBy(TimeWindows.of(Duration.ofMillis(1000)))
.reduce((String value1, String value2) -> value1 + value2,
Named.as("windowStore"))
.toStream()
.map((windowedId, value) -> new KeyValue<>(windowedId.key(), value))
.filter((i, s) -> s.length() > 40)
.to("streamingTopic2");
stream.print(Printed.toSysOut());
return stream;
}
}
4.3. Testing Applications
The spring-kafka-test
jar contains some useful utilities to assist with testing your applications.
4.3.1. KafkaTestUtils
o.s.kafka.test.utils.KafkaTestUtils
provides a number of static helper methods to consume records, retrieve various record offsets, and others.
Refer to its Javadocs for complete details.
4.3.2. JUnit
o.s.kafka.test.utils.KafkaTestUtils
also provides some static methods to set up producer and consumer properties.
The following listing shows those method signatures:
/**
* Set up test properties for an {@code <Integer, String>} consumer.
* @param group the group id.
* @param autoCommit the auto commit.
* @param embeddedKafka a {@link EmbeddedKafkaBroker} instance.
* @return the properties.
*/
public static Map<String, Object> consumerProps(String group, String autoCommit,
EmbeddedKafkaBroker embeddedKafka) { ... }
/**
* Set up test properties for an {@code <Integer, String>} producer.
* @param embeddedKafka a {@link EmbeddedKafkaBroker} instance.
* @return the properties.
*/
public static Map<String, Object> producerProps(EmbeddedKafkaBroker embeddedKafka) { ... }
Starting with version 2.5, the When using the embedded broker, it is generally best practice to use a different topic for each test, to prevent cross-talk.
If this is not possible for some reason, note that the |
A JUnit 4 @Rule
wrapper for the EmbeddedKafkaBroker
is provided to create an embedded Kafka and an embedded Zookeeper server.
(See @EmbeddedKafka Annotation for information about using @EmbeddedKafka
with JUnit 5).
The following listing shows the signatures of those methods:
/**
* Create embedded Kafka brokers.
* @param count the number of brokers.
* @param controlledShutdown passed into TestUtils.createBrokerConfig.
* @param topics the topics to create (2 partitions per).
*/
public EmbeddedKafkaRule(int count, boolean controlledShutdown, String... topics) { ... }
/**
*
* Create embedded Kafka brokers.
* @param count the number of brokers.
* @param controlledShutdown passed into TestUtils.createBrokerConfig.
* @param partitions partitions per topic.
* @param topics the topics to create.
*/
public EmbeddedKafkaRule(int count, boolean controlledShutdown, int partitions, String... topics) { ... }
The EmbeddedKafkaBroker
class has a utility method that lets you consume for all the topics it created.
The following example shows how to use it:
Map<String, Object> consumerProps = KafkaTestUtils.consumerProps("testT", "false", embeddedKafka);
DefaultKafkaConsumerFactory<Integer, String> cf = new DefaultKafkaConsumerFactory<Integer, String>(
consumerProps);
Consumer<Integer, String> consumer = cf.createConsumer();
embeddedKafka.consumeFromAllEmbeddedTopics(consumer);
The KafkaTestUtils
has some utility methods to fetch results from the consumer.
The following listing shows those method signatures:
/**
* Poll the consumer, expecting a single record for the specified topic.
* @param consumer the consumer.
* @param topic the topic.
* @return the record.
* @throws org.junit.ComparisonFailure if exactly one record is not received.
*/
public static <K, V> ConsumerRecord<K, V> getSingleRecord(Consumer<K, V> consumer, String topic) { ... }
/**
* Poll the consumer for records.
* @param consumer the consumer.
* @return the records.
*/
public static <K, V> ConsumerRecords<K, V> getRecords(Consumer<K, V> consumer) { ... }
The following example shows how to use KafkaTestUtils
:
...
template.sendDefault(0, 2, "bar");
ConsumerRecord<Integer, String> received = KafkaTestUtils.getSingleRecord(consumer, "topic");
...
When the embedded Kafka and embedded Zookeeper server are started by the EmbeddedKafkaBroker
, a system property named spring.embedded.kafka.brokers
is set to the address of the Kafka brokers and a system property named spring.embedded.zookeeper.connect
is set to the address of Zookeeper.
Convenient constants (EmbeddedKafkaBroker.SPRING_EMBEDDED_KAFKA_BROKERS
and EmbeddedKafkaBroker.SPRING_EMBEDDED_ZOOKEEPER_CONNECT
) are provided for this property.
With the EmbeddedKafkaBroker.brokerProperties(Map<String, String>)
, you can provide additional properties for the Kafka servers.
See Kafka Config for more information about possible broker properties.
4.3.3. Configuring Topics
The following example configuration creates topics called cat
and hat
with five partitions, a topic called thing1
with 10 partitions, and a topic called thing2
with 15 partitions:
public class MyTests {
@ClassRule
private static EmbeddedKafkaRule embeddedKafka = new EmbeddedKafkaRule(1, false, 5, "cat", "hat");
@Test
public void test() {
embeddedKafkaRule.getEmbeddedKafka()
.addTopics(new NewTopic("thing1", 10, (short) 1), new NewTopic("thing2", 15, (short) 1));
...
}
}
By default, addTopics
will throw an exception when problems arise (such as adding a topic that already exists).
Version 2.6 added a new version of that method that returns a Map<String, Exception>
; the key is the topic name and the value is null
for success, or an Exception
for a failure.
4.3.4. Using the Same Broker(s) for Multiple Test Classes
There is no built-in support for doing so, but you can use the same broker for multiple test classes with something similar to the following:
public final class EmbeddedKafkaHolder {
private static EmbeddedKafkaBroker embeddedKafka = new EmbeddedKafkaBroker(1, false)
.brokerListProperty("spring.kafka.bootstrap-servers");
private static boolean started;
public static EmbeddedKafkaBroker getEmbeddedKafka() {
if (!started) {
try {
embeddedKafka.afterPropertiesSet();
}
catch (Exception e) {
throw new KafkaException("Embedded broker failed to start", e);
}
started = true;
}
return embeddedKafka;
}
private EmbeddedKafkaHolder() {
super();
}
}
This assumes a Spring Boot environment and the embedded broker replaces the bootstrap servers property.
Then, in each test class, you can use something similar to the following:
static {
EmbeddedKafkaHolder.getEmbeddedKafka().addTopics("topic1", "topic2");
}
private static final EmbeddedKafkaBroker broker = EmbeddedKafkaHolder.getEmbeddedKafka();
If you are not using Spring Boot, you can obtain the bootstrap servers using broker.getBrokersAsString()
.
The preceding example provides no mechanism for shutting down the broker(s) when all tests are complete.
This could be a problem if, say, you run your tests in a Gradle daemon.
You should not use this technique in such a situation, or you should use something to call destroy() on the EmbeddedKafkaBroker when your tests are complete.
|
4.3.5. @EmbeddedKafka Annotation
We generally recommend that you use the rule as a @ClassRule
to avoid starting and stopping the broker between tests (and use a different topic for each test).
Starting with version 2.0, if you use Spring’s test application context caching, you can also declare a EmbeddedKafkaBroker
bean, so a single broker can be used across multiple test classes.
For convenience, we provide a test class-level annotation called @EmbeddedKafka
to register the EmbeddedKafkaBroker
bean.
The following example shows how to use it:
@RunWith(SpringRunner.class)
@DirtiesContext
@EmbeddedKafka(partitions = 1,
topics = {
KafkaStreamsTests.STREAMING_TOPIC1,
KafkaStreamsTests.STREAMING_TOPIC2 })
public class KafkaStreamsTests {
@Autowired
private EmbeddedKafkaBroker embeddedKafka;
@Test
public void someTest() {
Map<String, Object> consumerProps = KafkaTestUtils.consumerProps("testGroup", "true", this.embeddedKafka);
consumerProps.put(ConsumerConfig.AUTO_OFFSET_RESET_CONFIG, "earliest");
ConsumerFactory<Integer, String> cf = new DefaultKafkaConsumerFactory<>(consumerProps);
Consumer<Integer, String> consumer = cf.createConsumer();
this.embeddedKafka.consumeFromAnEmbeddedTopic(consumer, KafkaStreamsTests.STREAMING_TOPIC2);
ConsumerRecords<Integer, String> replies = KafkaTestUtils.getRecords(consumer);
assertThat(replies.count()).isGreaterThanOrEqualTo(1);
}
@Configuration
@EnableKafkaStreams
public static class KafkaStreamsConfiguration {
@Value("${" + EmbeddedKafkaBroker.SPRING_EMBEDDED_KAFKA_BROKERS + "}")
private String brokerAddresses;
@Bean(name = KafkaStreamsDefaultConfiguration.DEFAULT_STREAMS_CONFIG_BEAN_NAME)
public KafkaStreamsConfiguration kStreamsConfigs() {
Map<String, Object> props = new HashMap<>();
props.put(StreamsConfig.APPLICATION_ID_CONFIG, "testStreams");
props.put(StreamsConfig.BOOTSTRAP_SERVERS_CONFIG, this.brokerAddresses);
return new KafkaStreamsConfiguration(props);
}
}
}
Starting with version 2.2.4, you can also use the @EmbeddedKafka
annotation to specify the Kafka ports property.
The following example sets the topics
, brokerProperties
, and brokerPropertiesLocation
attributes of @EmbeddedKafka
support property placeholder resolutions:
@TestPropertySource(locations = "classpath:/test.properties")
@EmbeddedKafka(topics = { "any-topic", "${kafka.topics.another-topic}" },
brokerProperties = { "log.dir=${kafka.broker.logs-dir}",
"listeners=PLAINTEXT://localhost:${kafka.broker.port}",
"auto.create.topics.enable=${kafka.broker.topics-enable:true}" },
brokerPropertiesLocation = "classpath:/broker.properties")
In the preceding example, the property placeholders ${kafka.topics.another-topic}
, ${kafka.broker.logs-dir}
, and ${kafka.broker.port}
are resolved from the Spring Environment
.
In addition, the broker properties are loaded from the broker.properties
classpath resource specified by the brokerPropertiesLocation
.
Property placeholders are resolved for the brokerPropertiesLocation
URL and for any property placeholders found in the resource.
Properties defined by brokerProperties
override properties found in brokerPropertiesLocation
.
You can use the @EmbeddedKafka
annotation with JUnit 4 or JUnit 5.
4.3.6. @EmbeddedKafka Annotation with JUnit5
Starting with version 2.3, there are two ways to use the @EmbeddedKafka
annotation with JUnit5.
When used with the @SpringJunitConfig
annotation, the embedded broker is added to the test application context.
You can auto wire the broker into your test, at the class or method level, to get the broker address list.
When not using the spring test context, the EmbdeddedKafkaCondition
creates a broker; the condition includes a parameter resolver so you can access the broker in your test method…
@EmbeddedKafka
public class EmbeddedKafkaConditionTests {
@Test
public void test(EmbeddedKafkaBroker broker) {
String brokerList = broker.getBrokersAsString();
...
}
}
A stand-alone (not Spring test context) broker will be created if the class annotated with @EmbeddedBroker
is not also annotated (or meta annotated) with ExtendedWith(SpringExtension.class)
.
@SpringJunitConfig
and @SpringBootTest
are so meta annotated and the context-based broker will be used when either of those annotations are also present.
When there is a Spring test application context available, the topics and broker properties can contain property placeholders, which will be resolved as long as the property is defined somewhere. If there is no Spring context available, these placeholders won’t be resolved. |
4.3.7. Embedded Broker in @SpringBootTest
Annotations
Spring Initializr now automatically adds the spring-kafka-test
dependency in test scope to the project configuration.
If your application uses the Kafka binder in
|
There are several ways to use an embedded broker in a Spring Boot application test.
They include:
JUnit4 Class Rule
The following example shows how to use a JUnit4 class rule to create an embedded broker:
@RunWith(SpringRunner.class)
@SpringBootTest
public class MyApplicationTests {
@ClassRule
public static EmbeddedKafkaRule broker = new EmbeddedKafkaRule(1,
false, "someTopic")
.brokerListProperty("spring.kafka.bootstrap-servers");
}
@Autowired
private KafkaTemplate<String, String> template;
@Test
public void test() {
...
}
}
Notice that, since this is a Spring Boot application, we override the broker list property to set Boot’s property.
@EmbeddedKafka
Annotation or EmbeddedKafkaBroker
Bean
The following example shows how to use an @EmbeddedKafka
Annotation to create an embedded broker:
@RunWith(SpringRunner.class)
@EmbeddedKafka(topics = "someTopic",
bootstrapServersProperty = "spring.kafka.bootstrap-servers")
public class MyApplicationTests {
@Autowired
private KafkaTemplate<String, String> template;
@Test
public void test() {
...
}
}
4.3.8. Hamcrest Matchers
The o.s.kafka.test.hamcrest.KafkaMatchers
provides the following matchers:
/**
* @param key the key
* @param <K> the type.
* @return a Matcher that matches the key in a consumer record.
*/
public static <K> Matcher<ConsumerRecord<K, ?>> hasKey(K key) { ... }
/**
* @param value the value.
* @param <V> the type.
* @return a Matcher that matches the value in a consumer record.
*/
public static <V> Matcher<ConsumerRecord<?, V>> hasValue(V value) { ... }
/**
* @param partition the partition.
* @return a Matcher that matches the partition in a consumer record.
*/
public static Matcher<ConsumerRecord<?, ?>> hasPartition(int partition) { ... }
/**
* Matcher testing the timestamp of a {@link ConsumerRecord} assuming the topic has been set with
* {@link org.apache.kafka.common.record.TimestampType#CREATE_TIME CreateTime}.
*
* @param ts timestamp of the consumer record.
* @return a Matcher that matches the timestamp in a consumer record.
*/
public static Matcher<ConsumerRecord<?, ?>> hasTimestamp(long ts) {
return hasTimestamp(TimestampType.CREATE_TIME, ts);
}
/**
* Matcher testing the timestamp of a {@link ConsumerRecord}
* @param type timestamp type of the record
* @param ts timestamp of the consumer record.
* @return a Matcher that matches the timestamp in a consumer record.
*/
public static Matcher<ConsumerRecord<?, ?>> hasTimestamp(TimestampType type, long ts) {
return new ConsumerRecordTimestampMatcher(type, ts);
}
4.3.9. AssertJ Conditions
You can use the following AssertJ conditions:
/**
* @param key the key
* @param <K> the type.
* @return a Condition that matches the key in a consumer record.
*/
public static <K> Condition<ConsumerRecord<K, ?>> key(K key) { ... }
/**
* @param value the value.
* @param <V> the type.
* @return a Condition that matches the value in a consumer record.
*/
public static <V> Condition<ConsumerRecord<?, V>> value(V value) { ... }
/**
* @param key the key.
* @param value the value.
* @param <K> the key type.
* @param <V> the value type.
* @return a Condition that matches the key in a consumer record.
* @since 2.2.12
*/
public static <K, V> Condition<ConsumerRecord<K, V>> keyValue(K key, V value) { ... }
/**
* @param partition the partition.
* @return a Condition that matches the partition in a consumer record.
*/
public static Condition<ConsumerRecord<?, ?>> partition(int partition) { ... }
/**
* @param value the timestamp.
* @return a Condition that matches the timestamp value in a consumer record.
*/
public static Condition<ConsumerRecord<?, ?>> timestamp(long value) {
return new ConsumerRecordTimestampCondition(TimestampType.CREATE_TIME, value);
}
/**
* @param type the type of timestamp
* @param value the timestamp.
* @return a Condition that matches the timestamp value in a consumer record.
*/
public static Condition<ConsumerRecord<?, ?>> timestamp(TimestampType type, long value) {
return new ConsumerRecordTimestampCondition(type, value);
}
4.3.10. Example
The following example brings together most of the topics covered in this chapter:
public class KafkaTemplateTests {
private static final String TEMPLATE_TOPIC = "templateTopic";
@ClassRule
public static EmbeddedKafkaRule embeddedKafka = new EmbeddedKafkaRule(1, true, TEMPLATE_TOPIC);
@Test
public void testTemplate() throws Exception {
Map<String, Object> consumerProps = KafkaTestUtils.consumerProps("testT", "false",
embeddedKafka.getEmbeddedKafka());
DefaultKafkaConsumerFactory<Integer, String> cf =
new DefaultKafkaConsumerFactory<Integer, String>(consumerProps);
ContainerProperties containerProperties = new ContainerProperties(TEMPLATE_TOPIC);
KafkaMessageListenerContainer<Integer, String> container =
new KafkaMessageListenerContainer<>(cf, containerProperties);
final BlockingQueue<ConsumerRecord<Integer, String>> records = new LinkedBlockingQueue<>();
container.setupMessageListener(new MessageListener<Integer, String>() {
@Override
public void onMessage(ConsumerRecord<Integer, String> record) {
System.out.println(record);
records.add(record);
}
});
container.setBeanName("templateTests");
container.start();
ContainerTestUtils.waitForAssignment(container,
embeddedKafka.getEmbeddedKafka().getPartitionsPerTopic());
Map<String, Object> producerProps =
KafkaTestUtils.producerProps(embeddedKafka.getEmbeddedKafka());
ProducerFactory<Integer, String> pf =
new DefaultKafkaProducerFactory<Integer, String>(producerProps);
KafkaTemplate<Integer, String> template = new KafkaTemplate<>(pf);
template.setDefaultTopic(TEMPLATE_TOPIC);
template.sendDefault("foo");
assertThat(records.poll(10, TimeUnit.SECONDS), hasValue("foo"));
template.sendDefault(0, 2, "bar");
ConsumerRecord<Integer, String> received = records.poll(10, TimeUnit.SECONDS);
assertThat(received, hasKey(2));
assertThat(received, hasPartition(0));
assertThat(received, hasValue("bar"));
template.send(TEMPLATE_TOPIC, 0, 2, "baz");
received = records.poll(10, TimeUnit.SECONDS);
assertThat(received, hasKey(2));
assertThat(received, hasPartition(0));
assertThat(received, hasValue("baz"));
}
}
The preceding example uses the Hamcrest matchers.
With AssertJ
, the final part looks like the following code:
assertThat(records.poll(10, TimeUnit.SECONDS)).has(value("foo"));
template.sendDefault(0, 2, "bar");
ConsumerRecord<Integer, String> received = records.poll(10, TimeUnit.SECONDS);
// using individual assertions
assertThat(received).has(key(2));
assertThat(received).has(value("bar"));
assertThat(received).has(partition(0));
template.send(TEMPLATE_TOPIC, 0, 2, "baz");
received = records.poll(10, TimeUnit.SECONDS);
// using allOf()
assertThat(received).has(allOf(keyValue(2, "baz"), partition(0)));
4.4. Non-Blocking Retries
This is an experimental feature and the usual rule of no breaking API changes does not apply to this feature until the experimental designation is removed. Users are encouraged to try out the feature and provide feedback via GitHub Issues or GitHub discussions. This is regarding the API only; the feature is considered to be complete, and robust. |
Achieving non-blocking retry / dlt functionality with Kafka usually requires setting up extra topics and creating and configuring the corresponding listeners.
Since 2.7 Spring for Apache Kafka offers support for that via the @RetryableTopic
annotation and RetryTopicConfiguration
class to simplify that bootstrapping.
4.4.1. How The Pattern Works
If message processing fails, the message is forwarded to a retry topic with a back off timestamp. The retry topic consumer then checks the timestamp and if it’s not due it pauses the consumption for that topic’s partition. When it is due the partition consumption is resumed, and the message is consumed again. If the message processing fails again the message will be forwarded to the next retry topic, and the pattern is repeated until a successful processing occurs, or the attempts are exhausted, and the message is sent to the Dead Letter Topic (if configured).
To illustrate, if you have a "main-topic" topic, and want to setup non-blocking retry with an exponential backoff of 1000ms with a multiplier of 2 and 4 max attempts, it will create the main-topic-retry-1000, main-topic-retry-2000, main-topic-retry-4000 and main-topic-dlt topics and configure the respective consumers. The framework also takes care of creating the topics and setting up and configuring the listeners.
By using this strategy you lose Kafka’s ordering guarantees for that topic. |
You can set the AckMode mode you prefer, but RECORD is suggested.
|
At this time this functionality doesn’t support class level @KafkaListener annotations
|
4.4.2. Back Off Delay Precision
Overview and Guarantees
All message processing and backing off is handled by the consumer thread, and, as such, delay precision is guaranteed on a best-effort basis. If one message’s processing takes longer than the next message’s back off period for that consumer, the next message’s delay will be higher than expected. Also, for short delays (about 1s or less), the maintenance work the thread has to do, such as committing offsets, may delay the message processing execution. The precision can also be affected if the retry topic’s consumer is handling more than one partition, because we rely on waking up the consumer from polling and having full pollTimeouts to make timing adjustments.
That being said, for consumers handling a single partition the message’s processing should happen under 100ms after it’s exact due time for most situations.
It is guaranteed that a message will never be processed before its due time. |
Tuning the Delay Precision
The message’s processing delay precision relies on two ContainerProperties
: ContainerProperties.pollTimeout
and ContainerProperties.idlePartitionEventInterval
.
Both properties will be automatically set in the retry topic and dlt’s ListenerContainerFactory
to one quarter of the smallest delay value for that topic, with a minimum value of 250ms and a maximum value of 5000ms.
These values will only be set if the property has its default values - if you change either value yourself your change will not be overridden.
This way you can tune the precision and performance for the retry topics if you need to.
You can have separate ListenerContainerFactory instances for the main and retry topics - this way you can have different settings to better suit your needs, such as having a higher polling timeout setting for the main topics and a lower one for the retry topics.
|
4.4.3. Configuration
Using the @RetryableTopic
annotation
To configure the retry topic and dlt for a @KafkaListener
annotated method, you just have to add the @RetryableTopic
annotation to it and Spring for Apache Kafka will bootstrap all the necessary topics and consumers with the default configurations.
@RetryableTopic(kafkaTemplate = "myRetryableTopicKafkaTemplate")
@KafkaListener(topics = "my-annotated-topic", groupId = "myGroupId")
public void processMessage(MyPojo message) {
// ... message processing
}
You can specify a method in the same class to process the dlt messages by annotating it with the @DltHandler
annotation.
If no DltHandler method is provided a default consumer is created which only logs the consumption.
@DltHandler
public void processMessage(MyPojo message) {
// ... message processing, persistence, etc
}
If you don’t specify a kafkaTemplate name a bean with name retryTopicDefaultKafkaTemplate will be looked up.
If no bean is found an exception is thrown.
|
Using RetryTopicConfiguration
beans
You can also configure the non-blocking retry support by creating RetryTopicConfiguration
beans in a @Configuration
annotated class.
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, Object> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.create(template);
}
This will create retry topics and a dlt, as well as the corresponding consumers, for all topics in methods annotated with '@KafkaListener' using the default configurations. The KafkaTemplate
instance is required for message forwarding.
To achieve more fine-grained control over how to handle non-blocking retrials for each topic, more than one RetryTopicConfiguration
bean can be provided.
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.fixedBackoff(3000)
.maxAttempts(5)
.includeTopics("my-topic", "my-other-topic")
.create(template);
}
@Bean
public RetryTopicConfiguration myOtherRetryTopic(KafkaTemplate<String, MyOtherPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.exponentialBackoff(1000, 2, 5000)
.maxAttempts(4)
.excludeTopics("my-topic", "my-other-topic")
.retryOn(MyException.class)
.create(template);
}
The retry topics' and dlt’s consumers will be assigned to a consumer group with a group id that is the combination of the one with you provide in the groupId parameter of the @KafkaListener annotation with the topic’s suffix. If you don’t provide any they’ll all belong to the same group, and rebalance on a retry topic will cause an unnecessary rebalance on the main topic.
|
If the consumer is configured with an ErrorHandlingDeserializer , to handle deserilialization exceptions, it is important to configure the KafkaTemplate and its producer with a serializer that can handle normal objects as well as raw byte[] values, which result from deserialization exceptions.
The generic value type of the template should be Object .
One technique is to use the DelegatingByTypeSerializer ; an example follows:
|
@Bean
public ProducerFactory<String, Object> producerFactory() {
return new DefaultKafkaProducerFactory<>(producerConfiguration(), new StringSerializer(),
new DelegatingByTypeSerializer(Map.of(byte[].class, new ByteArraySerializer(),
MyNormalObject.class, new JsonSerializer<Object>())));
}
@Bean
public KafkaTemplate<String, Object> kafkaTemplate() {
return new KafkaTemplate<>(producerFactory());
}
4.4.4. Features
Most of the features are available both for the @RetryableTopic
annotation and the RetryTopicConfiguration
beans.
BackOff Configuration
The BackOff configuration relies on the BackOffPolicy
interface from the Spring Retry
project.
It includes:
-
Fixed Back Off
-
Exponential Back Off
-
Random Exponential Back Off
-
Uniform Random Back Off
-
No Back Off
-
Custom Back Off
@RetryableTopic(attempts = 5,
backoff = @Backoff(delay = 1000, multiplier = 2, maxDelay = 5000))
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.fixedBackoff(3000)
.maxAttempts(4)
.build();
}
You can also provide a custom implementation of Spring Retry’s SleepingBackOffPolicy
:
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.customBackOff(new MyCustomBackOffPolicy())
.maxAttempts(5)
.build();
}
The default backoff policy is FixedBackOffPolicy with a maximum of 3 attempts and 1000ms intervals. |
The first attempt counts against the maxAttempts, so if you provide a maxAttempts value of 4 there’ll be the original attempt plus 3 retries. |
Single Topic Fixed Delay Retries
If you’re using fixed delay policies such as FixedBackOffPolicy
or NoBackOffPolicy
you can use a single topic to accomplish the non-blocking retries.
This topic will be suffixed with the provided or default suffix, and will not have either the index or the delay values appended.
@RetryableTopic(backoff = @Backoff(2000), fixedDelayTopicStrategy = FixedDelayStrategy.SINGLE_TOPIC)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.fixedBackoff(3000)
.maxAttempts(5)
.useSingleTopicForFixedDelays()
.build();
}
The default behavior is creating separate retry topics for each attempt, appended with their index value: retry-0, retry-1, … |
Global timeout
You can set the global timeout for the retrying process. If that time is reached, the next time the consumer throws an exception the message goes straight to the DLT, or just ends the processing if no DLT is available.
@RetryableTopic(backoff = @Backoff(2000), timeout = 5000)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.fixedBackoff(2000)
.timeoutAfter(5000)
.build();
}
The default is having no timeout set, which can also be achieved by providing -1 as the timout value. |
Exception Classifier
You can specify which exceptions you want to retry on and which not to. You can also set it to traverse the causes to lookup nested exceptions.
@RetryableTopic(include = {MyRetryException.class, MyOtherRetryException.class}, traversingCauses = true)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
throw new RuntimeException(new MyRetryException()); // Will retry
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyOtherPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.notRetryOn(MyDontRetryException.class)
.create(template);
}
The default behavior is retrying on all exceptions and not traversing causes. |
Include and Exclude Topics
You can decide which topics will and will not be handled by a RetryTopicConfiguration
bean via the .includeTopic(String topic), .includeTopics(Collection<String> topics) .excludeTopic(String topic) and .excludeTopics(Collection<String> topics) methods.
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.includeTopics(List.of("my-included-topic", "my-other-included-topic"))
.create(template);
}
@Bean
public RetryTopicConfiguration myOtherRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.excludeTopic("my-excluded-topic")
.create(template);
}
The default behavior is to include all topics. |
Topics AutoCreation
Unless otherwise specified the framework will auto create the required topics using NewTopic
beans that are consumed by the KafkaAdmin
bean.
You can specify the number of partitions and the replication factor with which the topics will be created, and you can turn this feature off.
Note that if you’re not using Spring Boot you’ll have to provide a KafkaAdmin bean in order to use this feature. |
@RetryableTopic(numPartitions = 2, replicationFactor = 3)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@RetryableTopic(autoCreateTopics = false)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.autoCreateTopicsWith(2, 3)
.create(template);
}
@Bean
public RetryTopicConfiguration myOtherRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.doNotAutoCreateRetryTopics()
.create(template);
}
By default the topics are autocreated with one partition and a replication factor of one. |
Failure Header Management
When considering how to manage failure headers (original headers and exception headers), the framework delegates to the DeadLetterPublishingRecover
to decide whether to append or replace the headers.
By default, it explicitly sets appendOriginalHeaders
to false
and leaves stripPreviousExceptionHeaders
to the default used by the DeadLetterPublishingRecover
.
This means that only the first "original" and last exception headers are retained with the default configuration. This is to avoid creation of excessively large messages (due to the stack trace header, for example) when many retry steps are involved.
See Managing Dead Letter Record Headers for more information.
To reconfigure the framework to use different settings for these properties, replace the standard DeadLetterPublishingRecovererFactory
bean by adding a recovererCustomizer
:
@Bean(RetryTopicInternalBeanNames.DEAD_LETTER_PUBLISHING_RECOVERER_FACTORY_BEAN_NAME)
DeadLetterPublishingRecovererFactory factory(DestinationTopicResolver resolver) {
DeadLetterPublishingRecovererFactory factory = new DeadLetterPublishingRecovererFactory(resolver);
factory.setDeadLetterPublishingRecovererCustomizer(dlpr -> {
dlpr.appendOriginalHeaders(true);
dlpr.setStripPreviousExceptionHeaders(false);
});
return factory;
}
4.4.5. Topic Naming
Retry topics and DLT are named by suffixing the main topic with a provided or default value, appended by either the delay or index for that topic.
Examples:
"my-topic" → "my-topic-retry-0", "my-topic-retry-1", …, "my-topic-dlt"
"my-other-topic" → "my-topic-myRetrySuffix-1000", "my-topic-myRetrySuffix-2000", …, "my-topic-myDltSuffix".
Retry Topics and Dlt Suffixes
You can specify the suffixes that will be used by the retry and dlt topics.
@RetryableTopic(retryTopicSuffix = "-my-retry-suffix", dltTopicSuffix = "-my-dlt-suffix")
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyOtherPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.retryTopicSuffix("-my-retry-suffix")
.dltTopicSuffix("-my-dlt-suffix")
.create(template);
}
The default suffixes are "-retry" and "-dlt", for retry topics and dlt respectively. |
Appending the Topic’s Index or Delay
You can either append the topic’s index or delay values after the suffix.
@RetryableTopic(topicSuffixingStrategy = TopicSuffixingStrategy.SUFFIX_WITH_INDEX_VALUE)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<String, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.suffixTopicsWithIndexValues()
.create(template);
}
The default behavior is to suffix with the delay values, except for fixed delay configurations with multiple topics, in which case the topics are suffixed with the topic’s index. |
Custom naming strategies
More complex naming strategies can be accomplished by registering a bean that implements RetryTopicNamesProviderFactory
. The default implementation is SuffixingRetryTopicNamesProviderFactory
and a different implementation can be registered in the following way:
@Bean
public RetryTopicNamesProviderFactory myRetryNamingProviderFactory() {
return new CustomRetryTopicNamesProviderFactory();
}
As an example the following implementation, in addition to the standard suffix, adds a prefix to retry/dl topics names:
public class CustomRetryTopicNamesProviderFactory implements RetryTopicNamesProviderFactory {
@Override
public RetryTopicNamesProvider createRetryTopicNamesProvider(
DestinationTopic.Properties properties) {
if(properties.isMainEndpoint()) {
return new SuffixingRetryTopicNamesProvider(properties);
}
else {
return new SuffixingRetryTopicNamesProvider(properties) {
@Override
public String getTopicName(String topic) {
return "my-prefix-" + super.getTopicName(topic);
}
};
}
}
}
4.4.6. Dlt Strategies
The framework provides a few strategies for working with DLTs. You can provide a method for DLT processing, use the default logging method, or have no DLT at all. Also you can choose what happens if DLT processing fails.
Dlt Processing Method
You can specify the method used to process the Dlt for the topic, as well as the behavior if that processing fails.
To do that you can use the @DltHandler
annotation in a method of the class with the @RetryableTopic
annotation(s).
Note that the same method will be used for all the @RetryableTopic
annotated methods within that class.
@RetryableTopic
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@DltHandler
public void processMessage(MyPojo message) {
// ... message processing, persistence, etc
}
The DLT handler method can also be provided through the RetryTopicConfigurationBuilder.dltHandlerMethod(String, String) method, passing as arguments the bean name and method name that should process the DLT’s messages.
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.dltProcessor("myCustomDltProcessor", "processDltMessage")
.create(template);
}
@Component
public class MyCustomDltProcessor {
private final MyDependency myDependency;
public MyCustomDltProcessor(MyDependency myDependency) {
this.myDependency = myDependency;
}
public void processDltMessage(MyPojo message) {
// ... message processing, persistence, etc
}
}
If no DLT handler is provided, the default RetryTopicConfigurer.LoggingDltListenerHandlerMethod is used. |
Starting with version 2.8, if you don’t want to consume from the DLT in this application at all, including by the default handler (or you wish to defer consumption), you can control whether or not the DLT container starts, independent of the container factory’s autoStartup
property.
When using the @RetryableTopic
annotation, set the autoStartDltHandler
property to false
; when using the configuration builder, use .autoStartDltHandler(false)
.
You can later start the DLT handler via the KafkaListenerEndpointRegistry
.
DLT Failure Behavior
Should the DLT processing fail, there are two possible behaviors available: ALWAYS_RETRY_ON_ERROR
and FAIL_ON_ERROR
.
In the former the record is forwarded back to the DLT topic so it doesn’t block other DLT records' processing. In the latter the consumer ends the execution without forwarding the message.
@RetryableTopic(dltProcessingFailureStrategy =
DltStrategy.FAIL_ON_ERROR)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.dltProcessor(MyCustomDltProcessor.class, "processDltMessage")
.doNotRetryOnDltFailure()
.create(template);
}
The default behavior is to ALWAYS_RETRY_ON_ERROR .
|
Starting with version 2.8, ALWAYS_RETRY_ON_ERROR will NOT route a record back to the DLT if the record causes a fatal exception to be thrown,
such as a DeserializationException because, generally, such exceptions will always be thrown.
|
Exceptions that are considered fatal are
-
DeserializationException
-
MessageConversionException
-
ConversionException
-
MethodArgumentResolutionException
-
NoSuchMethodException
-
ClassCastException
You can add exceptions to and remove exceptions from this list using methods on the DeadLetterPublishingRecovererFactory
bean.
Configuring No DLT
The framework also provides the possibility of not configuring a DLT for the topic. In this case after retrials are exhausted the processing simply ends.
@RetryableTopic(dltProcessingFailureStrategy =
DltStrategy.NO_DLT)
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.doNotConfigureDlt()
.create(template);
}
4.4.7. Specifying a ListenerContainerFactory
By default the RetryTopic configuration will use the provided factory from the @KafkaListener
annotation, but you can specify a different one to be used to create the retry topic and dlt listener containers.
The provided factory will be configured for the retry topic functionality, so you should not use the same factory for both retrying and non-retrying topics. You can however share the same factory between many retry topic configurations. |
For the @RetryableTopic
annotation you can provide the factory’s bean name, and using the RetryTopicConfiguration
bean you can either provide the bean name or the instance itself.
@RetryableTopic(listenerContainerFactory = "my-retry-topic-factory")
@KafkaListener(topics = "my-annotated-topic")
public void processMessage(MyPojo message) {
// ... message processing
}
@Bean
public RetryTopicConfiguration myRetryTopic(KafkaTemplate<Integer, MyPojo> template,
ConcurrentKafkaListenerContainerFactory<Integer, MyPojo> factory) {
return RetryTopicConfigurationBuilder
.newInstance()
.listenerFactory(factory)
.create(template);
}
@Bean
public RetryTopicConfiguration myOtherRetryTopic(KafkaTemplate<Integer, MyPojo> template) {
return RetryTopicConfigurationBuilder
.newInstance()
.listenerFactory("my-retry-topic-factory")
.create(template);
}
4.4.8. Changing KafkaBackOffException Logging Level
When a message in the retry topic is not due for consumption, a KafkaBackOffException
is thrown. Such exceptions are logged by default at DEBUG
level, but you can change this behavior by setting an error handler customizer in the ListenerContainerFactoryConfigurer
in a @Configuration
class.
For example, to change the logging level to WARN you might add:
@Bean(name = RetryTopicInternalBeanNames.LISTENER_CONTAINER_FACTORY_CONFIGURER_NAME)
public ListenerContainerFactoryConfigurer listenerContainer(KafkaConsumerBackoffManager kafkaConsumerBackoffManager,
DeadLetterPublishingRecovererFactory deadLetterPublishingRecovererFactory,
@Qualifier(RetryTopicInternalBeanNames
.INTERNAL_BACKOFF_CLOCK_BEAN_NAME) Clock clock) {
ListenerContainerFactoryConfigurer configurer = new ListenerContainerFactoryConfigurer(kafkaConsumerBackoffManager, deadLetterPublishingRecovererFactory, clock);
configurer.setErrorHandlerCustomizer(commonErrorHandler -> ((DefaultErrorHandler) commonErrorHandler).setLogLevel(KafkaException.Level.WARN));
return configurer;
}
5. Tips, Tricks and Examples
5.1. Manually Assigning All Partitions
Let’s say you want to always read all records from all partitions (such as when using a compacted topic to load a distributed cache), it can be useful to manually assign the partitions and not use Kafka’s group management. Doing so can be unwieldy when there are many partitions, because you have to list the partitions. It’s also an issue if the number of partitions changes over time, because you would have to recompile your application each time the partition count changes.
The following is an example of how to use the power of a SpEL expression to create the partition list dynamically when the application starts:
@KafkaListener(topicPartitions = @TopicPartition(topic = "compacted",
partitions = "#{@finder.partitions('compacted')}"),
partitionOffsets = @PartitionOffset(partition = "*", initialOffset = "0")))
public void listen(@Header(KafkaHeaders.RECEIVED_MESSAGE_KEY) String key, String payload) {
...
}
@Bean
public PartitionFinder finder(ConsumerFactory<String, String> consumerFactory) {
return new PartitionFinder(consumerFactory);
}
public static class PartitionFinder {
private final ConsumerFactory<String, String> consumerFactory;
public PartitionFinder(ConsumerFactory<String, String> consumerFactory) {
this.consumerFactory = consumerFactory;
}
public String[] partitions(String topic) {
try (Consumer<String, String> consumer = consumerFactory.createConsumer()) {
return consumer.partitionsFor(topic).stream()
.map(pi -> "" + pi.partition())
.toArray(String[]::new);
}
}
}
Using this in conjunction with ConsumerConfig.AUTO_OFFSET_RESET_CONFIG=earliest
will load all records each time the application is started.
You should also set the container’s AckMode
to MANUAL
to prevent the container from committing offsets for a null
consumer group.
Howewever, starting with version 2.5.5, as shown above, you can apply an initial offset to all partitions; see Explicit Partition Assignment for more information.
5.2. Examples of Kafka Transactions with Other Transaction Managers
The following Spring Boot application is an example of chaining database and Kafka transactions.
The listener container starts the Kafka transaction and the @Transactional
annotation starts the DB transaction.
The DB transaction is committed first; if the Kafka transaction fails to commit, the record will be redelivered so the DB update should be idempotent.
@SpringBootApplication
public class Application {
public static void main(String[] args) {
SpringApplication.run(Application.class, args);
}
@Bean
public ApplicationRunner runner(KafkaTemplate<String, String> template) {
return args -> template.executeInTransaction(t -> t.send("topic1", "test"));
}
@Bean
public DataSourceTransactionManager dstm(DataSource dataSource) {
return new DataSourceTransactionManager(dataSource);
}
@Component
public static class Listener {
private final JdbcTemplate jdbcTemplate;
private final KafkaTemplate<String, String> kafkaTemplate;
public Listener(JdbcTemplate jdbcTemplate, KafkaTemplate<String, String> kafkaTemplate) {
this.jdbcTemplate = jdbcTemplate;
this.kafkaTemplate = kafkaTemplate;
}
@KafkaListener(id = "group1", topics = "topic1")
@Transactional("dstm")
public void listen1(String in) {
this.kafkaTemplate.send("topic2", in.toUpperCase());
this.jdbcTemplate.execute("insert into mytable (data) values ('" + in + "')");
}
@KafkaListener(id = "group2", topics = "topic2")
public void listen2(String in) {
System.out.println(in);
}
}
@Bean
public NewTopic topic1() {
return TopicBuilder.name("topic1").build();
}
@Bean
public NewTopic topic2() {
return TopicBuilder.name("topic2").build();
}
}
spring.datasource.url=jdbc:mysql://localhost/integration?serverTimezone=UTC
spring.datasource.username=root
spring.datasource.driver-class-name=com.mysql.cj.jdbc.Driver
spring.kafka.consumer.auto-offset-reset=earliest
spring.kafka.consumer.enable-auto-commit=false
spring.kafka.consumer.properties.isolation.level=read_committed
spring.kafka.producer.transaction-id-prefix=tx-
#logging.level.org.springframework.transaction=trace
#logging.level.org.springframework.kafka.transaction=debug
#logging.level.org.springframework.jdbc=debug
create table mytable (data varchar(20));
For producer-only transactions, transaction synchronization works:
@Transactional("dstm")
public void someMethod(String in) {
this.kafkaTemplate.send("topic2", in.toUpperCase());
this.jdbcTemplate.execute("insert into mytable (data) values ('" + in + "')");
}
The KafkaTemplate
will synchronize its transaction with the DB transaction and the commit/rollback occurs after the database.
If you wish to commit the Kafka transaction first, and only commit the DB transaction if the Kafka transaction is successful, use nested @Transactional
methods:
@Transactional("dstm")
public void someMethod(String in) {
this.jdbcTemplate.execute("insert into mytable (data) values ('" + in + "')");
sendToKafka(in);
}
@Transactional("kafkaTransactionManager")
public void sendToKafka(String in) {
this.kafkaTemplate.send("topic2", in.toUpperCase());
}
5.3. Customizing the JsonSerializer and JsonDeserializer
The serializer and deserializer support a number of cusomizations using properties, see JSON for more information.
The kafka-clients
code, not Spring, instantiates these objects, unless you inject them directly into the consumer and producer factories.
If you wish to configure the (de)serializer using properties, but wish to use, say, a custom ObjectMapper
, simply create a subclass and pass the custom mapper into the super
constructor. For example:
public class CustomJsonSerializer extends JsonSerializer<Object> {
public CustomJsonSerializer() {
super(customizedObjectMapper());
}
private static ObjectMapper customizedObjectMapper() {
ObjectMapper mapper = JacksonUtils.enhancedObjectMapper();
mapper.disable(SerializationFeature.WRITE_DATES_AS_TIMESTAMPS);
return mapper;
}
}
6. Other Resources
In addition to this reference documentation, we recommend a number of other resources that may help you learn about Spring and Apache Kafka.
Appendix A: Override Spring Boot Dependencies
When using Spring for Apache Kafka in a Spring Boot application, the Apache Kafka dependency versions are determined by Spring Boot’s dependency management.
If you wish to use a different version of kafka-clients
or kafka-streams
, and use the embedded kafka broker for testing, you need to override their version used by Spring Boot dependency management and add two test
artifacts for Apache Kafka.
There is a bug in Apache Kafka 3.0.0 when running the embedded broker on Microsoft Windows KAFKA-13391.
To use the embedded broker on Windows, you need to downgrade the Apache Kafka version to 2.8.1 until 3.0.1 is available.
When using 2.8.1, you also need to exclude zookeeper dependency from spring-kafka-test .
|
<properties>
<kafka.version>2.8.1</kafka.version>
</properties>
<dependency>
<groupId>org.springframework.kafka</groupId>
<artifactId>spring-kafka</artifactId>
</dependency>
<!-- optional - only needed when using kafka-streams -->
<dependency>
<groupId>org.apache.kafka</groupId>
<artifactId>kafka-streams</artifactId>
</dependency>
<dependency>
<groupId>org.springframework.kafka</groupId>
<artifactId>spring-kafka-test</artifactId>
<scope>test</scope>
<!-- needed if downgrading to Apache Kafka 2.8.1 -->
<exclusions>
<exclusion>
<groupId>org.apache.zookeeper</groupId>
<artifactId>zookeeper</artifactId>
</exclusion>
</exclusions>
</dependency>
<dependency>
<groupId>org.apache.kafka</groupId>
<artifactId>kafka-clients</artifactId>
<classifier>test</classifier>
<scope>test</scope>
<version>${kafka.version}</version>
</dependency>
<dependency>
<groupId>org.apache.kafka</groupId>
<artifactId>kafka_2.13</artifactId>
<classifier>test</classifier>
<scope>test</scope>
<version>${kafka.version}</version>
</dependency>
ext['kafka.version'] = '2.8.1'
dependencies {
implementation 'org.springframework.kafka:spring-kafka'
implementation "org.apache.kafka:kafka-streams" // optional - only needed when using kafka-streams
testImplementation ('org.springframework.kafka:spring-kafka-test') {
// needed if downgrading to Apache Kafka 2.8.1
exclude group: 'org.apache.zookeeper', module: 'zookeeper'
}
testImplementation "org.apache.kafka:kafka-clients:${kafka.version}:test"
testImplementation "org.apache.kafka:kafka_2.13:${kafka.version}:test"
}
The test scope dependencies are only needed if you are using the embedded Kafka broker in tests.
Appendix B: Change History
B.1. Changes between 2.6 and 2.7
B.1.1. Kafka Client Version
This version requires the 2.7.0 kafka-clients
.
It is also compatible with the 2.8.0 clients, since version 2.7.1; see Override Spring Boot Dependencies.
B.1.2. Non-Blocking Delayed Retries Using Topics
This significant new feature is added in this release. When strict ordering is not important, failed deliveries can be sent to another topic to be consumed later. A series of such retry topics can be configured, with increasing delays. See Non-Blocking Retries for more information.
B.1.3. Listener Container Changes
The onlyLogRecordMetadata
container property is now true
by default.
A new container property stopImmediate
is now available.
See Listener Container Properties for more information.
Error handlers that use a BackOff
between delivery attempts (e.g. SeekToCurrentErrorHandler
and DefaultAfterRollbackProcessor
) will now exit the back off interval soon after the container is stopped, rather than delaying the stop.
See After-rollback Processor and [seek-to-current] for more information.
Error handlers and after rollback processors that extend FailedRecordProcessor
can now be configured with one or more RetryListener
s to receive information about retry and recovery progress.
See See After-rollback Processor, [seek-to-current], and [recovering-batch-eh] for more information.
The RecordInterceptor
now has additional methods called after the listener returns (normally, or by throwing an exception).
It also has a sub-interface ConsumerAwareRecordInterceptor
.
In addition, there is now a BatchInterceptor
for batch listeners.
See Message Listener Containers for more information.
B.1.4. @KafkaListener
Changes
You can now validate the payload parameter of @KafkaHandler
methods (class-level listeners).
See @KafkaListener
@Payload
Validation for more information.
You can now set the rawRecordHeader
property on the MessagingMessageConverter
and BatchMessagingMessageConverter
which causes the raw ConsumerRecord
to be added to the converted Message<?>
.
This is useful, for example, if you wish to use a DeadLetterPublishingRecoverer
in a listener error handler.
See Listener Error Handlers for more information.
You can now modify @KafkaListener
annotations during application initialization.
See @KafkaListener
Attribute Modification for more information.
B.1.5. DeadLetterPublishingRecover
Changes
Now, if both the key and value fail deserialization, the original values are published to the DLT.
Previously, the value was populated but the key DeserializationException
remained in the headers.
There is a breaking API change, if you subclassed the recoverer and overrode the createProducerRecord
method.
In addition, the recoverer verifies that the partition selected by the destination resolver actually exists before publishing to it.
See Publishing Dead-letter Records for more information.
B.1.6. ChainedKafkaTransactionManager
is Deprecated
See Transactions for more information.
B.1.7. ReplyingKafkaTemplate
Changes
There is now a mechanism to examine a reply and fail the future exceptionally if some condition exists.
Support for sending and receiving spring-messaging
Message<?>
s has been added.
See Using ReplyingKafkaTemplate
for more information.
B.1.8. Kafka Streams Changes
By default, the StreamsBuilderFactoryBean
is now configured to not clean up local state.
See Configuration for more information.
B.1.9. KafkaAdmin
Changes
New methods createOrModifyTopics
and describeTopics
have been added.
KafkaAdmin.NewTopics
has been added to facilitate configuring multiple topics in a single bean.
See Configuring Topics for more information.
B.1.10. MessageConverter
Changes
It is now possible to add a spring-messaging
SmartMessageConverter
to the MessagingMessageConverter
, allowing content negotiation based on the contentType
header.
See Spring Messaging Message Conversion for more information.
B.1.11. Sequencing @KafkaListener
s
See Starting @KafkaListener
s in Sequence for more information.
B.1.12. ExponentialBackOffWithMaxRetries
A new BackOff
implementation is provided, making it more convenient to configure the max retries.
See ExponentialBackOffWithMaxRetries
Implementation for more information.
B.1.13. Conditional Delegating Error Handlers
These new error handlers can be configured to delegate to different error handlers, depending on the exception type. See Delegating Error Handler for more information.
B.2. Changes between 2.5 and 2.6
B.2.2. Listener Container Changes
The default EOSMode
is now BETA
.
See Exactly Once Semantics for more information.
Various error handlers (that extend FailedRecordProcessor
) and the DefaultAfterRollbackProcessor
now reset the BackOff
if recovery fails.
In addition, you can now select the BackOff
to use based on the failed record and/or exception.
See [seek-to-current], [recovering-batch-eh], Publishing Dead-letter Records and After-rollback Processor for more information.
You can now configure an adviceChain
in the container properties.
See Listener Container Properties for more information.
When the container is configured to publish ListenerContainerIdleEvent
s, it now publishes a ListenerContainerNoLongerIdleEvent
when a record is received after publishing an idle event.
See Application Events and Detecting Idle and Non-Responsive Consumers for more information.
B.2.3. @KafkaListener Changes
When using manual partition assignment, you can now specify a wildcard for determining which partitions should be reset to the initial offset.
In addition, if the listener implements ConsumerSeekAware
, onPartitionsAssigned()
is called after the manual assignment.
(Also added in version 2.5.5).
See Explicit Partition Assignment for more information.
Convenience methods have been added to AbstractConsumerSeekAware
to make seeking easier.
See Seeking to a Specific Offset for more information.
B.2.4. ErrorHandler Changes
Subclasses of FailedRecordProcessor
(e.g. SeekToCurrentErrorHandler
, DefaultAfterRollbackProcessor
, RecoveringBatchErrorHandler
) can now be configured to reset the retry state if the exception is a different type to that which occurred previously with this record.
See [seek-to-current], After-rollback Processor, [recovering-batch-eh] for more information.
B.2.5. Producer Factory Changes
You can now set a maximum age for producers after which they will be closed and recreated. See Transactions for more information.
You can now update the configuration map after the DefaultKafkaProducerFactory
has been created.
This might be useful, for example, if you have to update SSL key/trust store locations after a credentials change.
See Using DefaultKafkaProducerFactory
for more information.
B.3. Changes between 2.4 and 2.5
This section covers the changes made from version 2.4 to version 2.5. For changes in earlier version, see Change History.
B.3.1. Consumer/Producer Factory Changes
The default consumer and producer factories can now invoke a callback whenever a consumer or producer is created or closed. Implementations for native Micrometer metrics are provided. See Factory Listeners for more information.
You can now change bootstrap server properties at runtime, enabling failover to another Kafka cluster. See Connecting to Kafka for more information.
B.3.2. StreamsBuilderFactoryBean
Changes
The factory bean can now invoke a callback whenever a KafkaStreams
created or destroyed.
An Implementation for native Micrometer metrics is provided.
See KafkaStreams Micrometer Support for more information.
B.3.4. Class/Package Changes
SeekUtils
has been moved from the o.s.k.support
package to o.s.k.listener
.
B.3.5. Delivery Attempts Header
There is now an option to to add a header which tracks delivery attempts when using certain error handlers and after rollback processors. See Delivery Attempts Header for more information.
B.3.6. @KafkaListener Changes
Default reply headers will now be populated automatically if needed when a @KafkaListener
return type is Message<?>
.
See Reply Type Message<?> for more information.
The KafkaHeaders.RECEIVED_MESSAGE_KEY
is no longer populated with a null
value when the incoming record has a null
key; the header is omitted altogether.
@KafkaListener
methods can now specify a ConsumerRecordMetadata
parameter instead of using discrete headers for metadata such as topic, partition, etc.
See Consumer Record Metadata for more information.
B.3.7. Listener Container Changes
The assignmentCommitOption
container property is now LATEST_ONLY_NO_TX
by default.
See Listener Container Properties for more information.
The subBatchPerPartition
container property is now true
by default when using transactions.
See Transactions for more information.
A new RecoveringBatchErrorHandler
is now provided.
See [recovering-batch-eh] for more information.
Static group membership is now supported. See Message Listener Containers for more information.
When incremental/cooperative rebalancing is configured, if offsets fail to commit with a non-fatal RebalanceInProgressException
, the container will attempt to re-commit the offsets for the partitions that remain assigned to this instance after the rebalance is completed.
The default error handler is now the SeekToCurrentErrorHandler
for record listeners and RecoveringBatchErrorHandler
for batch listeners.
See Container Error Handlers for more information.
You can now control the level at which exceptions intentionally thrown by standard error handlers are logged. See Container Error Handlers for more information.
The getAssignmentsByClientId()
method has been added, making it easier to determine which consumers in a concurrent container are assigned which partition(s).
See Listener Container Properties for more information.
You can now suppress logging entire ConsumerRecord
s in error, debug logs etc.
See onlyLogRecordMetadata
in Listener Container Properties.
B.3.8. KafkaTemplate Changes
The KafkaTemplate
can now maintain micrometer timers.
See Monitoring for more information.
The KafkaTemplate
can now be configured with ProducerConfig
properties to override those in the producer factory.
See Using KafkaTemplate
for more information.
A RoutingKafkaTemplate
has now been provided.
See Using RoutingKafkaTemplate
for more information.
You can now use KafkaSendCallback
instead of ListenerFutureCallback
to get a narrower exception, making it easier to extract the failed ProducerRecord
.
See Using KafkaTemplate
for more information.
B.3.9. Kafka String Serializer/Deserializer
New ToStringSerializer
/StringDeserializer
s as well as an associated SerDe
are now provided.
See String serialization for more information.
B.3.10. JsonDeserializer
The JsonDeserializer
now has more flexibility to determine the deserialization type.
See Using Methods to Determine Types for more information.
B.3.11. Delegating Serializer/Deserializer
The DelegatingSerializer
can now handle "standard" types, when the outbound record has no header.
See Delegating Serializer and Deserializer for more information.
B.3.12. Testing Changes
The KafkaTestUtils.consumerProps()
helper record now sets ConsumerConfig.AUTO_OFFSET_RESET_CONFIG
to earliest
by default.
See JUnit for more information.
B.4. Changes between 2.3 and 2.4
B.4.1. Kafka Client Version
This version requires the 2.4.0 kafka-clients
or higher and supports the new incremental rebalancing feature.
B.4.2. ConsumerAwareRebalanceListener
Like ConsumerRebalanceListener
, this interface now has an additional method onPartitionsLost
.
Refer to the Apache Kafka documentation for more information.
Unlike the ConsumerRebalanceListener
, The default implementation does not call onPartitionsRevoked
.
Instead, the listener container will call that method after it has called onPartitionsLost
; you should not, therefore, do the same when implementing ConsumerAwareRebalanceListener
.
See the IMPORTANT note at the end of Rebalancing Listeners for more information.
B.4.3. GenericErrorHandler
The isAckAfterHandle()
default implementation now returns true by default.
B.4.4. KafkaTemplate
The KafkaTemplate
now supports non-transactional publishing alongside transactional.
See KafkaTemplate
Transactional and non-Transactional Publishing for more information.
B.4.5. AggregatingReplyingKafkaTemplate
The releaseStrategy
is now a BiConsumer
.
It is now called after a timeout (as well as when records arrive); the second parameter is true
in the case of a call after a timeout.
See Aggregating Multiple Replies for more information.
B.4.6. Listener Container
The ContainerProperties
provides an authorizationExceptionRetryInterval
option to let the listener container to retry after any AuthorizationException
is thrown by the KafkaConsumer
.
See its JavaDocs and Using KafkaMessageListenerContainer
for more information.
B.4.7. @KafkaListener
The @KafkaListener
annotation has a new property splitIterables
; default true.
When a replying listener returns an Iterable
this property controls whether the return result is sent as a single record or a record for each element is sent.
See Forwarding Listener Results using @SendTo
for more information
Batch listeners can now be configured with a BatchToRecordAdapter
; this allows, for example, the batch to be processed in a transaction while the listener gets one record at a time.
With the default implementation, a ConsumerRecordRecoverer
can be used to handle errors within the batch, without stopping the processing of the entire batch - this might be useful when using transactions.
See Transactions with Batch Listeners for more information.
B.4.8. Kafka Streams
The StreamsBuilderFactoryBean
accepts a new property KafkaStreamsInfrastructureCustomizer
.
This allows configuration of the builder and/or topology before the stream is created.
See Spring Management for more information.
B.5. Changes Between 2.2 and 2.3
This section covers the changes made from version 2.2 to version 2.3.
B.5.1. Tips, Tricks and Examples
A new chapter Tips, Tricks and Examples has been added. Please submit GitHub issues and/or pull requests for additional entries in that chapter.
B.5.3. Class/Package Changes
TopicPartitionInitialOffset
is deprecated in favor of TopicPartitionOffset
.
B.5.4. Configuration Changes
Starting with version 2.3.4, the missingTopicsFatal
container property is false by default.
When this is true, the application fails to start if the broker is down; many users were affected by this change; given that Kafka is a high-availability platform, we did not anticipate that starting an application with no active brokers would be a common use case.
B.5.5. Producer and Consumer Factory Changes
The DefaultKafkaProducerFactory
can now be configured to create a producer per thread.
You can also provide Supplier<Serializer>
instances in the constructor as an alternative to either configured classes (which require no-arg constructors), or constructing with Serializer
instances, which are then shared between all Producers.
See Using DefaultKafkaProducerFactory
for more information.
The same option is available with Supplier<Deserializer>
instances in DefaultKafkaConsumerFactory
.
See Using KafkaMessageListenerContainer
for more information.
B.5.6. Listener Container Changes
Previously, error handlers received ListenerExecutionFailedException
(with the actual listener exception as the cause
) when the listener was invoked using a listener adapter (such as @KafkaListener
s).
Exceptions thrown by native GenericMessageListener
s were passed to the error handler unchanged.
Now a ListenerExecutionFailedException
is always the argument (with the actual listener exception as the cause
), which provides access to the container’s group.id
property.
Because the listener container has it’s own mechanism for committing offsets, it prefers the Kafka ConsumerConfig.ENABLE_AUTO_COMMIT_CONFIG
to be false
.
It now sets it to false automatically unless specifically set in the consumer factory or the container’s consumer property overrides.
The ackOnError
property is now false
by default.
See [seek-to-current] for more information.
It is now possible to obtain the consumer’s group.id
property in the listener method.
See Obtaining the Consumer group.id
for more information.
The container has a new property recordInterceptor
allowing records to be inspected or modified before invoking the listener.
A CompositeRecordInterceptor
is also provided in case you need to invoke multiple interceptors.
See Message Listener Containers for more information.
The ConsumerSeekAware
has new methods allowing you to perform seeks relative to the beginning, end, or current position and to seek to the first offset greater than or equal to a time stamp.
See Seeking to a Specific Offset for more information.
A convenience class AbstractConsumerSeekAware
is now provided to simplify seeking.
See Seeking to a Specific Offset for more information.
The ContainerProperties
provides an idleBetweenPolls
option to let the main loop in the listener container to sleep between KafkaConsumer.poll()
calls.
See its JavaDocs and Using KafkaMessageListenerContainer
for more information.
When using AckMode.MANUAL
(or MANUAL_IMMEDIATE
) you can now cause a redelivery by calling nack
on the Acknowledgment
.
See Committing Offsets for more information.
Listener performance can now be monitored using Micrometer Timer
s.
See Monitoring for more information.
The containers now publish additional consumer lifecycle events relating to startup. See Application Events for more information.
Transactional batch listeners can now support zombie fencing. See Transactions for more information.
The listener container factory can now be configured with a ContainerCustomizer
to further configure each container after it has been created and configured.
See Container factory for more information.
B.5.7. ErrorHandler Changes
The SeekToCurrentErrorHandler
now treats certain exceptions as fatal and disables retry for those, invoking the recoverer on first failure.
The SeekToCurrentErrorHandler
and SeekToCurrentBatchErrorHandler
can now be configured to apply a BackOff
(thread sleep) between delivery attempts.
Starting with version 2.3.2, recovered records' offsets will be committed when the error handler returns after recovering a failed record.
See [seek-to-current] for more information.
The DeadLetterPublishingRecoverer
, when used in conjunction with an ErrorHandlingDeserializer
, now sets the payload of the message sent to the dead-letter topic, to the original value that could not be deserialized.
Previously, it was null
and user code needed to extract the DeserializationException
from the message headers.
See Publishing Dead-letter Records for more information.
B.5.8. TopicBuilder
A new class TopicBuilder
is provided for more convenient creation of NewTopic
@Bean
s for automatic topic provisioning.
See Configuring Topics for more information.
B.5.9. Kafka Streams Changes
You can now perform additional configuration of the StreamsBuilderFactoryBean
created by @EnableKafkaStreams
.
See Streams Configuration for more information.
A RecoveringDeserializationExceptionHandler
is now provided which allows records with deserialization errors to be recovered.
It can be used in conjunction with a DeadLetterPublishingRecoverer
to send these records to a dead-letter topic.
See Recovery from Deserialization Exceptions for more information.
The HeaderEnricher
transformer has been provided, using SpEL to generate the header values.
See Header Enricher for more information.
The MessagingTransformer
has been provided.
This allows a Kafka streams topology to interact with a spring-messaging component, such as a Spring Integration flow.
See MessagingTransformer
and See [Calling a Spring Integration Flow from a KStream
] for more information.
B.5.10. JSON Component Changes
Now all the JSON-aware components are configured by default with a Jackson ObjectMapper
produced by the JacksonUtils.enhancedObjectMapper()
.
The JsonDeserializer
now provides TypeReference
-based constructors for better handling of target generic container types.
Also a JacksonMimeTypeModule
has been introduced for serialization of org.springframework.util.MimeType
to plain string.
See its JavaDocs and Serialization, Deserialization, and Message Conversion for more information.
A ByteArrayJsonMessageConverter
has been provided as well as a new super class for all Json converters, JsonMessageConverter
.
Also, a StringOrBytesSerializer
is now available; it can serialize byte[]
, Bytes
and String
values in ProducerRecord
s.
See Spring Messaging Message Conversion for more information.
The JsonSerializer
, JsonDeserializer
and JsonSerde
now have fluent APIs to make programmatic configuration simpler.
See the javadocs, Serialization, Deserialization, and Message Conversion, and Streams JSON Serialization and Deserialization for more informaion.
B.5.11. ReplyingKafkaTemplate
When a reply times out, the future is completed exceptionally with a KafkaReplyTimeoutException
instead of a KafkaException
.
Also, an overloaded sendAndReceive
method is now provided that allows specifying the reply timeout on a per message basis.
B.5.12. AggregatingReplyingKafkaTemplate
Extends the ReplyingKafkaTemplate
by aggregating replies from multiple receivers.
See Aggregating Multiple Replies for more information.
B.5.13. Transaction Changes
You can now override the producer factory’s transactionIdPrefix
on the KafkaTemplate
and KafkaTransactionManager
.
See transactionIdPrefix
for more information.
B.5.14. New Delegating Serializer/Deserializer
The framework now provides a delegating Serializer
and Deserializer
, utilizing a header to enable producing and consuming records with multiple key/value types.
See Delegating Serializer and Deserializer for more information.
B.5.15. New Retrying Deserializer
The framework now provides a delegating RetryingDeserializer
, to retry serialization when transient errors such as network problems might occur.
See Retrying Deserializer for more information.
B.6. Changes Between 2.1 and 2.2
B.6.2. Class and Package Changes
The ContainerProperties
class has been moved from org.springframework.kafka.listener.config
to org.springframework.kafka.listener
.
The AckMode
enum has been moved from AbstractMessageListenerContainer
to ContainerProperties
.
The setBatchErrorHandler()
and setErrorHandler()
methods have been moved from ContainerProperties
to both AbstractMessageListenerContainer
and AbstractKafkaListenerContainerFactory
.
B.6.3. After Rollback Processing
A new AfterRollbackProcessor
strategy is provided.
See After-rollback Processor for more information.
B.6.4. ConcurrentKafkaListenerContainerFactory
Changes
You can now use the ConcurrentKafkaListenerContainerFactory
to create and configure any ConcurrentMessageListenerContainer
, not only those for @KafkaListener
annotations.
See Container factory for more information.
B.6.5. Listener Container Changes
A new container property (missingTopicsFatal
) has been added.
See Using KafkaMessageListenerContainer
for more information.
A ConsumerStoppedEvent
is now emitted when a consumer stops.
See Thread Safety for more information.
Batch listeners can optionally receive the complete ConsumerRecords<?, ?>
object instead of a List<ConsumerRecord<?, ?>
.
See Batch Listeners for more information.
The DefaultAfterRollbackProcessor
and SeekToCurrentErrorHandler
can now recover (skip) records that keep failing, and, by default, does so after 10 failures.
They can be configured to publish failed records to a dead-letter topic.
Starting with version 2.2.4, the consumer’s group ID can be used while selecting the dead letter topic name.
See After-rollback Processor, [seek-to-current], and Publishing Dead-letter Records for more information.
The ConsumerStoppingEvent
has been added.
See Application Events for more information.
The SeekToCurrentErrorHandler
can now be configured to commit the offset of a recovered record when the container is configured with AckMode.MANUAL_IMMEDIATE
(since 2.2.4).
See [seek-to-current] for more information.
B.6.6. @KafkaListener Changes
You can now override the concurrency
and autoStartup
properties of the listener container factory by setting properties on the annotation.
You can now add configuration to determine which headers (if any) are copied to a reply message.
See @KafkaListener
Annotation for more information.
You can now use @KafkaListener
as a meta-annotation on your own annotations.
See @KafkaListener
as a Meta Annotation for more information.
It is now easier to configure a Validator
for @Payload
validation.
See @KafkaListener
@Payload
Validation for more information.
You can now specify kafka consumer properties directly on the annotation; these will override any properties with the same name defined in the consumer factory (since version 2.2.4). See Annotation Properties for more information.
B.6.7. Header Mapping Changes
Headers of type MimeType
and MediaType
are now mapped as simple strings in the RecordHeader
value.
Previously, they were mapped as JSON and only MimeType
was decoded.
MediaType
could not be decoded.
They are now simple strings for interoperability.
Also, the DefaultKafkaHeaderMapper
has a new addToStringClasses
method, allowing the specification of types that should be mapped by using toString()
instead of JSON.
See Message Headers for more information.
B.6.8. Embedded Kafka Changes
The KafkaEmbedded
class and its KafkaRule
interface have been deprecated in favor of the EmbeddedKafkaBroker
and its JUnit 4 EmbeddedKafkaRule
wrapper.
The @EmbeddedKafka
annotation now populates an EmbeddedKafkaBroker
bean instead of the deprecated KafkaEmbedded
.
This change allows the use of @EmbeddedKafka
in JUnit 5 tests.
The @EmbeddedKafka
annotation now has the attribute ports
to specify the port that populates the EmbeddedKafkaBroker
.
See Testing Applications for more information.
B.6.9. JsonSerializer/Deserializer Enhancements
You can now provide type mapping information by using producer and consumer properties.
New constructors are available on the deserializer to allow overriding the type header information with the supplied target type.
The JsonDeserializer
now removes any type information headers by default.
You can now configure the JsonDeserializer
to ignore type information headers by using a Kafka property (since 2.2.3).
See Serialization, Deserialization, and Message Conversion for more information.
B.6.10. Kafka Streams Changes
The streams configuration bean must now be a KafkaStreamsConfiguration
object instead of a StreamsConfig
object.
The StreamsBuilderFactoryBean
has been moved from package …core
to …config
.
The KafkaStreamBrancher
has been introduced for better end-user experience when conditional branches are built on top of KStream
instance.
See Apache Kafka Streams Support and Configuration for more information.
B.6.11. Transactional ID
When a transaction is started by the listener container, the transactional.id
is now the transactionIdPrefix
appended with <group.id>.<topic>.<partition>
.
This change allows proper fencing of zombies, as described here.
B.7. Changes Between 2.0 and 2.1
B.7.1. Kafka Client Version
This version requires the 1.0.0 kafka-clients
or higher.
The 1.1.x client is supported natively in version 2.2.
B.7.2. JSON Improvements
The StringJsonMessageConverter
and JsonSerializer
now add type information in Headers
, letting the converter and JsonDeserializer
create specific types on reception, based on the message itself rather than a fixed configured type.
See Serialization, Deserialization, and Message Conversion for more information.
B.7.3. Container Stopping Error Handlers
Container error handlers are now provided for both record and batch listeners that treat any exceptions thrown by the listener as fatal/ They stop the container. See Handling Exceptions for more information.
B.7.4. Pausing and Resuming Containers
The listener containers now have pause()
and resume()
methods (since version 2.1.3).
See Pausing and Resuming Listener Containers for more information.
B.7.5. Stateful Retry
Starting with version 2.1.3, you can configure stateful retry. See Stateful Retry for more information.
B.7.6. Client ID
Starting with version 2.1.1, you can now set the client.id
prefix on @KafkaListener
.
Previously, to customize the client ID, you needed a separate consumer factory (and container factory) per listener.
The prefix is suffixed with -n
to provide unique client IDs when you use concurrency.
B.7.7. Logging Offset Commits
By default, logging of topic offset commits is performed with the DEBUG
logging level.
Starting with version 2.1.2, a new property in ContainerProperties
called commitLogLevel
lets you specify the log level for these messages.
See Using KafkaMessageListenerContainer
for more information.
B.7.8. Default @KafkaHandler
Starting with version 2.1.3, you can designate one of the @KafkaHandler
annotations on a class-level @KafkaListener
as the default.
See @KafkaListener
on a Class for more information.
B.7.9. ReplyingKafkaTemplate
Starting with version 2.1.3, a subclass of KafkaTemplate
is provided to support request/reply semantics.
See Using ReplyingKafkaTemplate
for more information.
B.7.10. ChainedKafkaTransactionManager
Version 2.1.3 introduced the ChainedKafkaTransactionManager
.
(It is now deprecated).
B.7.11. Migration Guide from 2.0
See the 2.0 to 2.1 Migration guide.
B.8. Changes Between 1.3 and 2.0
B.8.1. Spring Framework and Java Versions
The Spring for Apache Kafka project now requires Spring Framework 5.0 and Java 8.
B.8.2. @KafkaListener
Changes
You can now annotate @KafkaListener
methods (and classes and @KafkaHandler
methods) with @SendTo
.
If the method returns a result, it is forwarded to the specified topic.
See Forwarding Listener Results using @SendTo
for more information.
B.8.3. Message Listeners
Message listeners can now be aware of the Consumer
object.
See Message Listeners for more information.
B.8.4. Using ConsumerAwareRebalanceListener
Rebalance listeners can now access the Consumer
object during rebalance notifications.
See Rebalancing Listeners for more information.
B.9. Changes Between 1.2 and 1.3
B.9.1. Support for Transactions
The 0.11.0.0 client library added support for transactions.
The KafkaTransactionManager
and other support for transactions have been added.
See Transactions for more information.
B.9.2. Support for Headers
The 0.11.0.0 client library added support for message headers.
These can now be mapped to and from spring-messaging
MessageHeaders
.
See Message Headers for more information.
B.9.3. Creating Topics
The 0.11.0.0 client library provides an AdminClient
, which you can use to create topics.
The KafkaAdmin
uses this client to automatically add topics defined as @Bean
instances.
B.9.4. Support for Kafka Timestamps
KafkaTemplate
now supports an API to add records with timestamps.
New KafkaHeaders
have been introduced regarding timestamp
support.
Also, new KafkaConditions.timestamp()
and KafkaMatchers.hasTimestamp()
testing utilities have been added.
See Using KafkaTemplate
, @KafkaListener
Annotation, and Testing Applications for more details.
B.9.5. @KafkaListener
Changes
You can now configure a KafkaListenerErrorHandler
to handle exceptions.
See Handling Exceptions for more information.
By default, the @KafkaListener
id
property is now used as the group.id
property, overriding the property configured in the consumer factory (if present).
Further, you can explicitly configure the groupId
on the annotation.
Previously, you would have needed a separate container factory (and consumer factory) to use different group.id
values for listeners.
To restore the previous behavior of using the factory configured group.id
, set the idIsGroup
property on the annotation to false
.
B.9.6. @EmbeddedKafka
Annotation
For convenience, a test class-level @EmbeddedKafka
annotation is provided, to register KafkaEmbedded
as a bean.
See Testing Applications for more information.
B.9.7. Kerberos Configuration
Support for configuring Kerberos is now provided. See JAAS and Kerberos for more information.
B.11. Changes Between 1.0 and 1.1
B.11.2. Batch Listeners
Listeners can be configured to receive the entire batch of messages returned by the consumer.poll()
operation, rather than one at a time.
B.11.4. Initial Offset
When explicitly assigning partitions, you can now configure the initial offset relative to the current position for the consumer group, rather than absolute or relative to the current end.
B.11.5. Seek
You can now seek the position of each topic or partition. You can use this to set the initial position during initialization when group management is in use and Kafka assigns the partitions. You can also seek when an idle container is detected or at any arbitrary point in your application’s execution. See Seeking to a Specific Offset for more information.