This documentation is for an out-of-date version of Apache Flink. We recommend you use the latest stable version.

Apache Kafka Connector

This connector provides access to event streams served by Apache Kafka.

Flink provides special Kafka Connectors for reading and writing data from/to Kafka topics. The Flink Kafka Consumer integrates with Flink’s checkpointing mechanism to provide exactly-once processing semantics. To achieve that, Flink does not purely rely on Kafka’s consumer group offset tracking, but tracks and checkpoints these offsets internally as well.

Please pick a package (maven artifact id) and class name for your use-case and environment. For most users, the FlinkKafkaConsumer08 (part of flink-connector-kafka) is appropriate.

Maven Dependency Supported since Consumer and
Producer Class name
Kafka version Notes
flink-connector-kafka-0.8_2.11 1.0.0 FlinkKafkaConsumer08
FlinkKafkaProducer08
0.8.x Uses the SimpleConsumer API of Kafka internally. Offsets are committed to ZK by Flink.
flink-connector-kafka-0.9_2.11 1.0.0 FlinkKafkaConsumer09
FlinkKafkaProducer09
0.9.x Uses the new Consumer API Kafka.
flink-connector-kafka-0.10_2.11 1.2.0 FlinkKafkaConsumer010
FlinkKafkaProducer010
0.10.x This connector supports Kafka messages with timestamps both for producing and consuming.
flink-connector-kafka-0.11_2.11 1.4.0 FlinkKafkaConsumer011
FlinkKafkaProducer011
0.11.x Since 0.11.x Kafka does not support scala 2.10. This connector supports Kafka transactional messaging to provide exactly once semantic for the producer.

Then, import the connector in your maven project:

<dependency>
  <groupId>org.apache.flink</groupId>
  <artifactId>flink-connector-kafka-0.8_2.11</artifactId>
  <version>1.4.2</version>
</dependency>

Note that the streaming connectors are currently not part of the binary distribution. See how to link with them for cluster execution here.

Installing Apache Kafka

  • Follow the instructions from Kafka’s quickstart to download the code and launch a server (launching a Zookeeper and a Kafka server is required every time before starting the application).
  • If the Kafka and Zookeeper servers are running on a remote machine, then the advertised.host.name setting in the config/server.properties file must be set to the machine’s IP address.

Kafka Consumer

Flink’s Kafka consumer is called FlinkKafkaConsumer08 (or 09 for Kafka 0.9.0.x versions, etc.). It provides access to one or more Kafka topics.

The constructor accepts the following arguments:

  1. The topic name / list of topic names
  2. A DeserializationSchema / KeyedDeserializationSchema for deserializing the data from Kafka
  3. Properties for the Kafka consumer. The following properties are required:
    • “bootstrap.servers” (comma separated list of Kafka brokers)
    • “zookeeper.connect” (comma separated list of Zookeeper servers) (only required for Kafka 0.8)
    • “group.id” the id of the consumer group

Example:

Properties properties = new Properties();
properties.setProperty("bootstrap.servers", "localhost:9092");
// only required for Kafka 0.8
properties.setProperty("zookeeper.connect", "localhost:2181");
properties.setProperty("group.id", "test");
DataStream<String> stream = env
	.addSource(new FlinkKafkaConsumer08<>("topic", new SimpleStringSchema(), properties));
val properties = new Properties()
properties.setProperty("bootstrap.servers", "localhost:9092")
// only required for Kafka 0.8
properties.setProperty("zookeeper.connect", "localhost:2181")
properties.setProperty("group.id", "test")
stream = env
    .addSource(new FlinkKafkaConsumer08[String]("topic", new SimpleStringSchema(), properties))
    .print()

The DeserializationSchema

The Flink Kafka Consumer needs to know how to turn the binary data in Kafka into Java/Scala objects. The DeserializationSchema allows users to specify such a schema. The T deserialize(byte[] message) method gets called for each Kafka message, passing the value from Kafka.

It is usually helpful to start from the AbstractDeserializationSchema, which takes care of describing the produced Java/Scala type to Flink’s type system. Users that implement a vanilla DeserializationSchema need to implement the getProducedType(...) method themselves.

For accessing both the key and value of the Kafka message, the KeyedDeserializationSchema has the following deserialize method ` T deserialize(byte[] messageKey, byte[] message, String topic, int partition, long offset)`.

For convenience, Flink provides the following schemas:

  1. TypeInformationSerializationSchema (and TypeInformationKeyValueSerializationSchema) which creates a schema based on a Flink’s TypeInformation. This is useful if the data is both written and read by Flink. This schema is a performant Flink-specific alternative to other generic serialization approaches.

  2. JsonDeserializationSchema (and JSONKeyValueDeserializationSchema) which turns the serialized JSON into an ObjectNode object, from which fields can be accessed using objectNode.get(“field”).as(Int/String/…)(). The KeyValue objectNode contains a “key” and “value” field which contain all fields, as well as an optional “metadata” field that exposes the offset/partition/topic for this message.

When encountering a corrupted message that cannot be deserialized for any reason, there are two options - either throwing an exception from the deserialize(...) method which will cause the job to fail and be restarted, or returning null to allow the Flink Kafka consumer to silently skip the corrupted message. Note that due to the consumer’s fault tolerance (see below sections for more details), failing the job on the corrupted message will let the consumer attempt to deserialize the message again. Therefore, if deserialization still fails, the consumer will fall into a non-stop restart and fail loop on that corrupted message.

Kafka Consumers Start Position Configuration

The Flink Kafka Consumer allows configuring how the start position for Kafka partitions are determined.

Example:

final StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();

FlinkKafkaConsumer08<String> myConsumer = new FlinkKafkaConsumer08<>(...);
myConsumer.setStartFromEarliest();     // start from the earliest record possible
myConsumer.setStartFromLatest();       // start from the latest record
myConsumer.setStartFromGroupOffsets(); // the default behaviour

DataStream<String> stream = env.addSource(myConsumer);
...
val env = StreamExecutionEnvironment.getExecutionEnvironment()

val myConsumer = new FlinkKafkaConsumer08[String](...)
myConsumer.setStartFromEarliest()      // start from the earliest record possible
myConsumer.setStartFromLatest()        // start from the latest record
myConsumer.setStartFromGroupOffsets()  // the default behaviour

val stream = env.addSource(myConsumer)
...

All versions of the Flink Kafka Consumer have the above explicit configuration methods for start position.

  • setStartFromGroupOffsets (default behaviour): Start reading partitions from the consumer group’s (group.id setting in the consumer properties) committed offsets in Kafka brokers (or Zookeeper for Kafka 0.8). If offsets could not be found for a partition, the auto.offset.reset setting in the properties will be used.
  • setStartFromEarliest() / setStartFromLatest(): Start from the earliest / latest record. Under these modes, committed offsets in Kafka will be ignored and not used as starting positions.

You can also specify the exact offsets the consumer should start from for each partition:

Map<KafkaTopicPartition, Long> specificStartOffsets = new HashMap<>();
specificStartOffsets.put(new KafkaTopicPartition("myTopic", 0), 23L);
specificStartOffsets.put(new KafkaTopicPartition("myTopic", 1), 31L);
specificStartOffsets.put(new KafkaTopicPartition("myTopic", 2), 43L);

myConsumer.setStartFromSpecificOffsets(specificStartOffsets);
val specificStartOffsets = new java.util.HashMap[KafkaTopicPartition, java.lang.Long]()
specificStartOffsets.put(new KafkaTopicPartition("myTopic", 0), 23L)
specificStartOffsets.put(new KafkaTopicPartition("myTopic", 1), 31L)
specificStartOffsets.put(new KafkaTopicPartition("myTopic", 2), 43L)

myConsumer.setStartFromSpecificOffsets(specificStartOffsets)

The above example configures the consumer to start from the specified offsets for partitions 0, 1, and 2 of topic myTopic. The offset values should be the next record that the consumer should read for each partition. Note that if the consumer needs to read a partition which does not have a specified offset within the provided offsets map, it will fallback to the default group offsets behaviour (i.e. setStartFromGroupOffsets()) for that particular partition.

Note that these start position configuration methods do not affect the start position when the job is automatically restored from a failure or manually restored using a savepoint. On restore, the start position of each Kafka partition is determined by the offsets stored in the savepoint or checkpoint (please see the next section for information about checkpointing to enable fault tolerance for the consumer).

Kafka Consumers and Fault Tolerance

With Flink’s checkpointing enabled, the Flink Kafka Consumer will consume records from a topic and periodically checkpoint all its Kafka offsets, together with the state of other operations, in a consistent manner. In case of a job failure, Flink will restore the streaming program to the state of the latest checkpoint and re-consume the records from Kafka, starting from the offsets that were stored in the checkpoint.

The interval of drawing checkpoints therefore defines how much the program may have to go back at most, in case of a failure.

To use fault tolerant Kafka Consumers, checkpointing of the topology needs to be enabled at the execution environment:

final StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
env.enableCheckpointing(5000); // checkpoint every 5000 msecs
val env = StreamExecutionEnvironment.getExecutionEnvironment()
env.enableCheckpointing(5000) // checkpoint every 5000 msecs

Also note that Flink can only restart the topology if enough processing slots are available to restart the topology. So if the topology fails due to loss of a TaskManager, there must still be enough slots available afterwards. Flink on YARN supports automatic restart of lost YARN containers.

If checkpointing is not enabled, the Kafka consumer will periodically commit the offsets to Zookeeper.

Kafka Consumers Topic and Partition Discovery

Partition discovery

The Flink Kafka Consumer supports discovering dynamically created Kafka partitions, and consumes them with exactly-once guarantees. All partitions discovered after the initial retrieval of partition metadata (i.e., when the job starts running) will be consumed from the earliest possible offset.

By default, partition discovery is disabled. To enable it, set a non-negative value for flink.partition-discovery.interval-millis in the provided properties config, representing the discovery interval in milliseconds.

Limitation When the consumer is restored from a savepoint from Flink versions prior to Flink 1.3.x, partition discovery cannot be enabled on the restore run. If enabled, the restore would fail with an exception. In this case, in order to use partition discovery, please first take a savepoint in Flink 1.3.x and then restore again from that.

Topic discovery

At a higher-level, the Flink Kafka Consumer is also capable of discovering topics, based on pattern matching on the topic names using regular expressions. See the below for an example:

final StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();

Properties properties = new Properties();
properties.setProperty("bootstrap.servers", "localhost:9092");
properties.setProperty("group.id", "test");

FlinkKafkaConsumer011<String> myConsumer = new FlinkKafkaConsumer011<>(
    java.util.regex.Pattern.compile("test-topic-[0-9]"),
    new SimpleStringSchema(),
    properties);

DataStream<String> stream = env.addSource(myConsumer);
...
val env = StreamExecutionEnvironment.getExecutionEnvironment()

val properties = new Properties()
properties.setProperty("bootstrap.servers", "localhost:9092")
properties.setProperty("group.id", "test")

val myConsumer = new FlinkKafkaConsumer08[String](
  java.util.regex.Pattern.compile("test-topic-[0-9]"),
  new SimpleStringSchema,
  properties)

val stream = env.addSource(myConsumer)
...

In the above example, all topics with names that match the specified regular expression (starting with test-topic- and ending with a single digit) will be subscribed by the consumer when the job starts running.

To allow the consumer to discover dynamically created topics after the job started running, set a non-negative value for flink.partition-discovery.interval-millis. This allows the consumer to discover partitions of new topics with names that also match the specified pattern.

Kafka Consumers Offset Committing Behaviour Configuration

The Flink Kafka Consumer allows configuring the behaviour of how offsets are committed back to Kafka brokers (or Zookeeper in 0.8). Note that the Flink Kafka Consumer does not rely on the committed offsets for fault tolerance guarantees. The committed offsets are only a means to expose the consumer’s progress for monitoring purposes.

The way to configure offset commit behaviour is different, depending on whether or not checkpointing is enabled for the job.

  • Checkpointing disabled: if checkpointing is disabled, the Flink Kafka Consumer relies on the automatic periodic offset committing capability of the internally used Kafka clients. Therefore, to disable or enable offset committing, simply set the enable.auto.commit (or auto.commit.enable for Kafka 0.8) / auto.commit.interval.ms keys to appropriate values in the provided Properties configuration.

  • Checkpointing enabled: if checkpointing is enabled, the Flink Kafka Consumer will commit the offsets stored in the checkpointed states when the checkpoints are completed. This ensures that the committed offsets in Kafka brokers is consistent with the offsets in the checkpointed states. Users can choose to disable or enable offset committing by calling the setCommitOffsetsOnCheckpoints(boolean) method on the consumer (by default, the behaviour is true). Note that in this scenario, the automatic periodic offset committing settings in Properties is completely ignored.

Kafka Consumers and Timestamp Extraction/Watermark Emission

In many scenarios, the timestamp of a record is embedded (explicitly or implicitly) in the record itself. In addition, the user may want to emit watermarks either periodically, or in an irregular fashion, e.g. based on special records in the Kafka stream that contain the current event-time watermark. For these cases, the Flink Kafka Consumer allows the specification of an AssignerWithPeriodicWatermarks or an AssignerWithPunctuatedWatermarks.

You can specify your custom timestamp extractor/watermark emitter as described here, or use one from the predefined ones. After doing so, you can pass it to your consumer in the following way:

Properties properties = new Properties();
properties.setProperty("bootstrap.servers", "localhost:9092");
// only required for Kafka 0.8
properties.setProperty("zookeeper.connect", "localhost:2181");
properties.setProperty("group.id", "test");

FlinkKafkaConsumer08<String> myConsumer =
    new FlinkKafkaConsumer08<>("topic", new SimpleStringSchema(), properties);
myConsumer.assignTimestampsAndWatermarks(new CustomWatermarkEmitter());

DataStream<String> stream = env
	.addSource(myConsumer)
	.print();
val properties = new Properties()
properties.setProperty("bootstrap.servers", "localhost:9092")
// only required for Kafka 0.8
properties.setProperty("zookeeper.connect", "localhost:2181")
properties.setProperty("group.id", "test")

val myConsumer = new FlinkKafkaConsumer08[String]("topic", new SimpleStringSchema(), properties)
myConsumer.assignTimestampsAndWatermarks(new CustomWatermarkEmitter())
stream = env
    .addSource(myConsumer)
    .print()

Internally, an instance of the assigner is executed per Kafka partition. When such an assigner is specified, for each record read from Kafka, the extractTimestamp(T element, long previousElementTimestamp) is called to assign a timestamp to the record and the Watermark getCurrentWatermark() (for periodic) or the Watermark checkAndGetNextWatermark(T lastElement, long extractedTimestamp) (for punctuated) is called to determine if a new watermark should be emitted and with which timestamp.

Note: If a watermark assigner depends on records read from Kafka to advance its watermarks (which is commonly the case), all topics and partitions need to have a continuous stream of records. Otherwise, the watermarks of the whole application cannot advance and all time-based operations, such as time windows or functions with timers, cannot make progress. A single idle Kafka partition causes this behavior. A Flink improvement is planned to prevent this from happening (see FLINK-5479: Per-partition watermarks in FlinkKafkaConsumer should consider idle partitions). In the meanwhile, a possible workaround is to send heartbeat messages to all consumed partitions that advance the watermarks of idle partitions.

Kafka Producer

Flink’s Kafka Producer is called FlinkKafkaProducer011 (or 010 for Kafka 0.10.0.x versions, etc.). It allows writing a stream of records to one or more Kafka topics.

Example:

DataStream<String> stream = ...;

FlinkKafkaProducer011<String> myProducer = new FlinkKafkaProducer011<String>(
        "localhost:9092",            // broker list
        "my-topic",                  // target topic
        new SimpleStringSchema());   // serialization schema

// versions 0.10+ allow attaching the records' event timestamp when writing them to Kafka;
// this method is not available for earlier Kafka versions
myProducer.setWriteTimestampToKafka(true);

stream.addSink(myProducer);
val stream: DataStream[String] = ...

val myProducer = new FlinkKafkaProducer011[String](
        "localhost:9092",         // broker list
        "my-topic",               // target topic
        new SimpleStringSchema)   // serialization schema

// versions 0.10+ allow attaching the records' event timestamp when writing them to Kafka;
// this method is not available for earlier Kafka versions
myProducer.setWriteTimestampToKafka(true)

stream.addSink(myProducer)

The above examples demonstrate the basic usage of creating a Flink Kafka Producer to write streams to a single Kafka target topic. For more advanced usages, there are other constructor variants that allow providing the following:

  • Providing custom properties: The producer allows providing a custom properties configuration for the internal KafkaProducer. Please refer to the Apache Kafka documentation for details on how to configure Kafka Producers.
  • Custom partitioner: To assign records to specific partitions, you can provide an implementation of a FlinkKafkaPartitioner to the constructor. This partitioner will be called for each record in the stream to determine which exact partition of the target topic the record should be sent to. Please see Kafka Producer Partitioning Scheme for more details.
  • Advanced serialization schema: Similar to the consumer, the producer also allows using an advanced serialization schema called KeyedSerializationSchema, which allows serializing the key and value separately. It also allows to override the target topic, so that one producer instance can send data to multiple topics.

Kafka Producer Partitioning Scheme

By default, if a custom partitioner is not specified for the Flink Kafka Producer, the producer will use a FlinkFixedPartitioner that maps each Flink Kafka Producer parallel subtask to a single Kafka partition (i.e., all records received by a sink subtask will end up in the same Kafka partition).

A custom partitioner can be implemented by extending the FlinkKafkaPartitioner class. All Kafka versions’ constructors allow providing a custom partitioner when instantiating the producer. Note that the partitioner implementation must be serializable, as they will be transferred across Flink nodes. Also, keep in mind that any state in the partitioner will be lost on job failures since the partitioner is not part of the producer’s checkpointed state.

It is also possible to completely avoid using and kind of partitioner, and simply let Kafka partition the written records by their attached key (as determined for each record using the provided serialization schema). To do this, provide a null custom partitioner when instantiating the producer. It is important to provide null as the custom partitioner; as explained above, if a custom partitioner is not specified the FlinkFixedPartitioner is used instead.

Kafka Producers and Fault Tolerance

Kafka 0.8

Before 0.9 Kafka did not provide any mechanisms to guarantee at-least-once or exactly-once semantics.

Kafka 0.9 and 0.10

With Flink’s checkpointing enabled, the FlinkKafkaProducer09 and FlinkKafkaProducer010 can provide at-least-once delivery guarantees.

Besides enabling Flink’s checkpointing, you should also configure the setter methods setLogFailuresOnly(boolean) and setFlushOnCheckpoint(boolean) appropriately.

  • setLogFailuresOnly(boolean): by default, this is set to false. Enabling this will let the producer only log failures instead of catching and rethrowing them. This essentially accounts the record to have succeeded, even if it was never written to the target Kafka topic. This must be disabled for at-least-once.
  • setFlushOnCheckpoint(boolean): by default, this is set to false. With this enabled, Flink’s checkpoints will wait for any on-the-fly records at the time of the checkpoint to be acknowledged by Kafka before succeeding the checkpoint. This ensures that all records before the checkpoint have been written to Kafka. This must be enabled for at-least-once.

In conclusion, to configure the Kafka producer to have at-least-once guarantees for versions 0.9 and 0.10, setLogFailureOnly must be set to false and setFlushOnCheckpoint must be set to true.

Note: By default, the number of retries is set to “0”. This means that when setLogFailuresOnly is set to false, the producer fails immediately on errors, including leader changes. The value is set to “0” by default to avoid duplicate messages in the target topic that are caused by retries. For most production environments with frequent broker changes, we recommend setting the number of retries to a higher value.

Note: There is currently no transactional producer for Kafka, so Flink can not guarantee exactly-once delivery into a Kafka topic.

Attention: Depending on your Kafka configuration, even after Kafka acknowledges writes you can still experience data loss. In particular keep in mind the following Kafka settings:
  • acks
  • log.flush.interval.messages
  • log.flush.interval.ms
  • log.flush.*
Default values for the above options can easily lead to data loss. Please refer to Kafka documentation for more explanation.

Kafka 0.11

With Flink’s checkpointing enabled, the FlinkKafkaProducer011 can provide exactly-once delivery guarantees.

Besides enabling Flink’s checkpointing, you can also choose three different modes of operating chosen by passing appropriate semantic parameter to the FlinkKafkaProducer011:

  • Semantic.NONE: Flink will not guarantee anything. Produced records can be lost or they can be duplicated.
  • Semantic.AT_LEAST_ONCE (default setting): similar to setFlushOnCheckpoint(true) in FlinkKafkaProducer010. This guarantees that no records will be lost (although they can be duplicated).
  • Semantic.EXACTLY_ONCE: uses Kafka transactions to provide exactly-once semantic. Whenever you write to Kafka using transactions, do not forget about setting desired isolation.level (read_committed or read_uncommitted - the latter one is the default value) for any application consuming records from Kafka.
Attention: Depending on your Kafka configuration, even after Kafka acknowledges writes you can still experience data losses. In particular keep in mind about following properties in Kafka config:
  • acks
  • log.flush.interval.messages
  • log.flush.interval.ms
  • log.flush.*
Default values for the above options can easily lead to data loss. Please refer to the Kafka documentation for more explanation.
Caveats

Semantic.EXACTLY_ONCE mode relies on the ability to commit transactions that were started before taking a checkpoint, after recovering from the said checkpoint. If the time between Flink application crash and completed restart is larger then Kafka’s transaction timeout there will be data loss (Kafka will automatically abort transactions that exceeded timeout time). Having this in mind, please configure your transaction timeout appropriately to your expected down times.

Kafka brokers by default have transaction.max.timeout.ms set to 15 minutes. This property will not allow to set transaction timeouts for the producers larger then it’s value. FlinkKafkaProducer011 by default sets the transaction.timeout.ms property in producer config to 1 hour, thus transaction.max.timeout.ms should be increased before using the Semantic.EXACTLY_ONCE mode.

In read_committed mode of KafkaConsumer, any transactions that were not finished (neither aborted nor completed) will block all reads from the given Kafka topic past any un-finished transaction. In other words after following sequence of events:

  1. User started transaction1 and written some records using it
  2. User started transaction2 and written some further records using it
  3. User committed transaction2

Even if records from transaction2 are already committed, they will not be visible to the consumers until transaction1 is committed or aborted. This has two implications:

  • First of all, during normal working of Flink applications, user can expect a delay in visibility of the records produced into Kafka topics, equal to average time between completed checkpoints.
  • Secondly in case of Flink application failure, topics into which this application was writing, will be blocked for the readers until the application restarts or the configured transaction timeout time will pass. This remark only applies for the cases when there are multiple agents/applications writing to the same Kafka topic.

Note: Semantic.EXACTLY_ONCE mode uses a fixed size pool of KafkaProducers per each FlinkKafkaProducer011 instance. One of each of those producers is used per one checkpoint. If the number of concurrent checkpoints exceeds the pool size, FlinkKafkaProducer011 will throw an exception and will fail the whole application. Please configure max pool size and max number of concurrent checkpoints accordingly.

Note: Semantic.EXACTLY_ONCE takes all possible measures to not leave any lingering transactions that would block the consumers from reading from Kafka topic more then it is necessary. However in the event of failure of Flink application before first checkpoint, after restarting such application there is no information in the system about previous pool sizes. Thus it is unsafe to scale down Flink application before first checkpoint completes, by factor larger then FlinkKafkaProducer011.SAFE_SCALE_DOWN_FACTOR.

Since Apache Kafka 0.10+, Kafka’s messages can carry timestamps, indicating the time the event has occurred (see “event time” in Apache Flink) or the time when the message has been written to the Kafka broker.

The FlinkKafkaConsumer010 will emit records with the timestamp attached, if the time characteristic in Flink is set to TimeCharacteristic.EventTime (StreamExecutionEnvironment.setStreamTimeCharacteristic(TimeCharacteristic.EventTime)).

The Kafka consumer does not emit watermarks. To emit watermarks, the same mechanisms as described above in “Kafka Consumers and Timestamp Extraction/Watermark Emission” using the assignTimestampsAndWatermarks method are applicable.

There is no need to define a timestamp extractor when using the timestamps from Kafka. The previousElementTimestamp argument of the extractTimestamp() method contains the timestamp carried by the Kafka message.

A timestamp extractor for a Kafka consumer would look like this:

public long extractTimestamp(Long element, long previousElementTimestamp) {
    return previousElementTimestamp;
}

The FlinkKafkaProducer010 only emits the record timestamp, if setWriteTimestampToKafka(true) is set.

FlinkKafkaProducer010.FlinkKafkaProducer010Configuration config = FlinkKafkaProducer010.writeToKafkaWithTimestamps(streamWithTimestamps, topic, new SimpleStringSchema(), standardProps);
config.setWriteTimestampToKafka(true);

Kafka Connector metrics

Flink’s Kafka connectors provide some metrics through Flink’s metrics system to analyze the behavior of the connector. The producers export Kafka’s internal metrics through Flink’s metric system for all supported versions. The consumers export all metrics starting from Kafka version 0.9. The Kafka documentation lists all exported metrics in its documentation.

In addition to these metrics, all consumers expose the current-offsets and committed-offsets for each topic partition. The current-offsets refers to the current offset in the partition. This refers to the offset of the last element that we retrieved and emitted successfully. The committed-offsets is the last committed offset.

The Kafka Consumers in Flink commit the offsets back to Zookeeper (Kafka 0.8) or the Kafka brokers (Kafka 0.9+). If checkpointing is disabled, offsets are committed periodically. With checkpointing, the commit happens once all operators in the streaming topology have confirmed that they’ve created a checkpoint of their state. This provides users with at-least-once semantics for the offsets committed to Zookeeper or the broker. For offsets checkpointed to Flink, the system provides exactly once guarantees.

The offsets committed to ZK or the broker can also be used to track the read progress of the Kafka consumer. The difference between the committed offset and the most recent offset in each partition is called the consumer lag. If the Flink topology is consuming the data slower from the topic than new data is added, the lag will increase and the consumer will fall behind. For large production deployments we recommend monitoring that metric to avoid increasing latency.

Enabling Kerberos Authentication (for versions 0.9+ and above only)

Flink provides first-class support through the Kafka connector to authenticate to a Kafka installation configured for Kerberos. Simply configure Flink in flink-conf.yaml to enable Kerberos authentication for Kafka like so:

  1. Configure Kerberos credentials by setting the following -
    • security.kerberos.login.use-ticket-cache: By default, this is true and Flink will attempt to use Kerberos credentials in ticket caches managed by kinit. Note that when using the Kafka connector in Flink jobs deployed on YARN, Kerberos authorization using ticket caches will not work. This is also the case when deploying using Mesos, as authorization using ticket cache is not supported for Mesos deployments.
    • security.kerberos.login.keytab and security.kerberos.login.principal: To use Kerberos keytabs instead, set values for both of these properties.
  2. Append KafkaClient to security.kerberos.login.contexts: This tells Flink to provide the configured Kerberos credentials to the Kafka login context to be used for Kafka authentication.

Once Kerberos-based Flink security is enabled, you can authenticate to Kafka with either the Flink Kafka Consumer or Producer by simply including the following two settings in the provided properties configuration that is passed to the internal Kafka client:

  • Set security.protocol to SASL_PLAINTEXT (default NONE): The protocol used to communicate to Kafka brokers. When using standalone Flink deployment, you can also use SASL_SSL; please see how to configure the Kafka client for SSL here.
  • Set sasl.kerberos.service.name to kafka (default kafka): The value for this should match the sasl.kerberos.service.name used for Kafka broker configurations. A mismatch in service name between client and server configuration will cause the authentication to fail.

For more information on Flink configuration for Kerberos security, please see here. You can also find here further details on how Flink internally setups Kerberos-based security.

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