Frequently Asked Questions for Kafka Streams in Confluent Platform

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General

Is Kafka Streams a project separate from Kafka?

No. The Kafka Streams API, aka Kafka Streams, is a component of the Apache Kafka® open source project and is included in Kafka 0.10+ releases. The source code is available at https://github.com/apache/kafka/tree/trunk/streams.

Is Kafka Streams a proprietary library of Confluent?

No. The Kafka Streams API is a component of the Kafka open source project is included in Kafka 0.10+ releases. The source code is available at https://github.com/apache/kafka/tree/trunk/streams.

Do Kafka Streams applications run inside the Kafka brokers?

No, they don’t run inside the Kafka brokers. “Kafka Streams applications” are normal Java applications that use the Kafka Streams library.

You run these applications on client machines at the periphery of a Kafka cluster. In other words, Kafka Streams applications don’t run inside the Kafka brokers (servers) or the Kafka cluster. They’re client-side applications.

Why does my Kafka Streams application use so much memory?

If your Kafka Streams application is using a permanent state store, you must take care to close each Iterator after you’re done using it, to reclaim resouces. Not closing an Iterator can lead to OOM issues.

What are the system dependencies of Kafka Streams?

Kafka Streams has no external dependencies on systems other than Kafka.

How do I migrate my older Kafka Streams applications to the latest Confluent Platform version?

To upgrade to the latest Confluent Platform version, see the Kafka Streams Upgrade Guide.

Which versions of Kafka clusters are supported by Kafka Streams?

The following versions are supported:

 
Kafka Broker (columns)
Streams API (rows)
3.0.x / 0.10.0.x
3.1.x / 0.10.1.x and
3.2.x / 0.10.2.x
3.3.x / 0.11.0.x and
4.0.x / 1.0.x and
4.1.x / 1.1.x and
5.0.x / 2.0.x and
5.1.x / 2.1.x and
5.2.x / 2.2.x and
5.3.x / 2.3.x and
5.4.x / 2.4.x and
5.5.x / 2.5.x and
6.0.x / 2.6.x and
6.1.x / 2.7.x and
6.2.x / 2.8.x and
7.0.x / 3.0.x and
7.1.x / 3.1.x and
7.2.x / 3.2.x and
7.3.x / 3.3.x and
7.4.x / 3.4.x and
7.5.x / 3.5.x and
7.6.x / 3.6.x
3.0.x / 0.10.0.x
compatible
compatible
compatible
3.1.x / 0.10.1.x and
3.2.x / 0.10.2.x
 
compatible
compatible
3.3.x / 0.11.0.x
 
compatible with exactly-once turned
off (requires broker version
Confluent Platform 3.3.x or higher)
compatible
4.0.x / 1.0.x and
4.1.x / 1.1.x and
5.0.x / 2.0.x and
5.1.x / 2.1.x and
5.2.0 / 2.2.0 and
5.2.1 / 2.2.0
 
compatible with exactly-once turned
off (requires broker version
Confluent Platform 3.3.x or higher);
requires message format 0.10 or higher;
message headers are not supported
(requires broker version Confluent
Platform 3.3.x or higher with message
format 0.11 or higher)
compatible;
requires message format
0.10 or higher;
if message headers are
used, message format
0.11 or higher required
5.2.2 / 2.2.1 and
5.3.x / 2.3.x and
5.4.x / 2.4.x and
5.5.x / 2.5.x and
6.0.x / 2.6.x and
6.1.x / 2.7.x and
6.2.x / 2.8.x and
7.0.x / 3.0.x and
7.1.x / 3.1.x and
7.2.x / 3.2.x and
7.3.x / 3.3.x and
7.4.x / 3.4.x and
7.5.x / 3.5.x and
7.6.x / 3.6.x
   
compatible;
requires message format
0.11 or higher;
enabling exactly-once v2
requires Confluent Platform
5.4.x or higher








The Streams API is not compatible with Kafka clusters running older Kafka versions (0.7, 0.8, 0.9).

What programming languages are supported?

The Kafka Streams API is implemented in Java.

The Developer Guide provides several example applications written in Java 8+. Additionally, Kafka Streams ships with a Scala wrapper on top of Java.

Also, you can write applications in other JVM-based languages such as Kotlin or Clojure, but there’s no native support for these languages.

Why is my application re-processing data from the beginning?

Kafka remembers your application by storing consumer offsets in a special topic.

Offsets are numbers assigned to messages by the Kafka broker(s) indicating the order in which they arrived at the broker(s).

By remembering your application’s last committed offset, your application is only going to process newly arrived messages.

The configuration setting offsets.retention.minutes controls how long Kafka remembers offsets in the special topic. The default value is 10,080 minutes (7 days). The default value in older Kafka versions is 1,440 minutes (24 hours).

If your application is stopped, which means that it hasn’t connected to the Kafka cluster for awhile, you could end up in a situation where you start reprocessing data on application restart because the broker(s) have deleted the offsets in the meantime.

The actual startup behavior depends on your auto.offest.reset configuration that can be set to “earliest”, “latest”, or “none”.

To avoid this problem, it’s recommended to increase offsets.retention.minutes to an appropriately large value.

Scalability

Maximum parallelism of my application? Maximum number of app instances I can run?

Slightly simplified, the maximum parallelism at which your application may run is determined by the maximum number of partitions of the input topic(s) the application is reading from in its processing topology. The number of input partitions determines how many stream tasks Kafka Streams creates for the application, and the number of stream tasks is the upper bound on the application’s parallelism.

For example, imagine your application is reading from an input topic that has 5 partitions. How many app instances can you run?

The short answer is that you can run up to 5 instances of this application, because the application’s maximum parallelism is 5. If you run more than 5 app instances, the “excess” app instances launch successfully but remain idle. If one of the busy instances goes down, one of the idle instances will resume the former’s work.

Here’s the more detailed answer for this example.

  • 5 stream tasks are created, and each of these processes one of the input partitions. It’s actually the number of stream tasks that determines the maximum parallelism of an application. The number of input partitions is simply the main parameter from which the number of stream tasks is computed.

Now that you know the application’s theoretical maximum parallelism, the next question is how to actually run the application at its maximum parallelism? To do so, you must ensure that all 5 stream tasks are running in parallel, which means that there should be 5 processing threads, with each thread executing one task.

There are several options at your disposal:

  • Option 1 is to scale horizontally (scaling out): You run five single-threaded instances of your application, each of which executes one thread/task (i.e., num.stream.threads is set to 1; see optional configuration parameters). This option is used, for example, when you have many low-powered machines for running the app instances.
  • Option 2 is to scale vertically (scaling up): You run a single multi-threaded instance of your application that executes all threads/tasks (i.e., num.stream.threads is set to 5). This option is useful, for example, when you have a very powerful machine to run the app instance.
  • Option 3 combines options 1 and 2: You run multiple instances of your application, each of which is running multiple threads. This option is used, for example, when your application runs at large scale. Here, you may even chose to run multiple app instances per machine.

Processing

How should I retain my Kafka Streams application’s processing results from being cleaned up?

As with any Kafka topics, you can set the log.retention.ms, log.retention.minutes and log.retention.hours configs on the broker side for the sink topics to indicate how long processing results written to those topics are retained. Brokers determine whether to cleanup old data by comparing the record’s associated timestamp with the current system time.

For the window or session states, their retention policy can also be set in your code by using the Materialized#withRetention() method, which will be honored by the Kafka Streams library by comparing stored records’ timestamps with the current system time. Key-value state stores don’t have retention policy, as their updates are retained forever.

By default, Kafka Streams applications don’t modify the resultant record’s timestamp from its original source topics. In other words, if processing an event record at some time in the past, for example, during a bootstrapping phase that’s processing accumulated old data, resulted in one or more records as well as state updates, the resulting records or state updates would also be reflected at the same time in the past as indicated by their associated timestamps. If the timestamp is older than the retention threshold compared with the current system time, they will be cleaned up soon after they’ve been written to Kafka topics or state stores.

You can optionally let the Kafka Streams application code to modify the resulting record’s timestamp in version 5.1.x and beyond (see 5.1 Upgrade Guide for details), but pay attention to its semantic implications: processing an event as of some time would actually result in a result for a different time.

Accessing record metadata such as topic, partition, and offset information?

Record metadata is accessible through the Processor API. It’s also accessible indirectly through the DSL, because of its Processor API integration.

With the Processor API, you can access record metadata through a ProcessorContext. You can store a reference to the context in an instance field of your processor during Processor#init(), and then query the processor context within Processor#process(), for example. This is also true for Transformer. The context is updated automatically to match the record that’s currently being processed, which means that methods such as ProcessorContext#partition() always return the current record’s metadata.

Some caveats apply when calling the processor context within scheduled punctuate() function. See the Javadocs for details.

If you use the DSL combined with a custom Transformer, for example, you could transform an input record’s value to also include partition and offset metadata, and subsequent DSL operations such as map or filter could then leverage this information.

Difference between map, peek, foreach in the DSL?

The three methods map, peek, and foreach are quite similar to each other. In some sense, peek and foreach are but variants of map. An important reason for explicit support of all three is that it allows a developer to clearly communicate the intent of an operation:

  • map: “When I use map, my intent is to modify the input stream and continue processing the (modified) output, i.e. I want to create an output stream that contains the modified data so that I can perform additional operations on the modified data.”
  • foreach: “When I use foreach, my intent is to cause some side effects based on the (unmodified) input stream and then I want to terminate the processing.” That’s why foreach returns void and thus is labeled as a terminal operation.
  • peek: “When I use peek, my intent is to cause some side effects based on the (unmodified) input data and then I want to continue the processing of the (unmodified) input data.”

See also the Java 8 documentation on java.util.Stream, which supports map, peek, and foreach operations, too.

How to avoid data repartitioning if you know it’s not required?

Kafka Streams inserts a repartitioning step if a key-based operation like aggregation or join is preceded by a key changing operation like selectKey(), map, or flatMap().

It is generally preferable to use mapValues() and flatMapValues() as they ensure the key has not been modified and thus, the repartitioning step can be omitted.

Often, users want to get read-only access to the key while modifying the value. For this case, you can call mapValues() with a ValueMapperWithKey instead of using the map() operator. The XxxWithKey extension is available for multiple operators.

There are special cases for which you want to modify the key in a way that you know that the partitioning is preserved and thus repartitioning is actually not required. For these cases, it’s sometimes possible, to apply the key changing operation after the aggregation to avoid the repartitioning step. You can apply this strategy if the original and modified key result in the same “groups of data”.

Finally, you can always fall back to the Processor API and do a custom aggregation via process(), transform() or transformValues(). Those operations do not automatically trigger a repartitioning step even if the key might have been modified in a previous operation.

Serdes config method

If you implement a custom Serde and specify this Serde in the config properties, and if this class implements org.apache.kafka.common.Configurable, Serde#configure(...) will be called automatically and your code should forward this call to the corresponding serializer and deserializer. The serdes that are provided by the library implement this pattern already.

If you manually call new to create a Serde and pass in this Serde via a method call, you must manually call configure(...) for the library and custom Serdes.

Tip

Manually call configure() immediately after you have created the Serde object so that this step is not forgotten.

How can I replace RocksDB with a different store?

There is no global setting to replace RocksDB. However, you can set a custom store for each operator individually. For example aggregate() (and other operators with an internal store) has an overload that accepts a Materialized that enables specifying a KeyValueBytesStoreSupplier. You can use those overloads to provide a supplier that returns a different store that replaces RocksDB for the corresponding operator.

Note: if you want to replace RocksDB in every operator, you need to provide a different XxxByteStoreSupplier for each operator.

Next to a RocksDB-based state store, the Kafka Streams API also ships with an in-memory store. This in-memory store will be backed by a changelog topic and is fully fault-tolerant. You can get an in-memory supplier via:

KeyValueBytesStoreSupplier inMemoryStoreSupplier = Stores.inMemoryKeyValueStore("myStoreName-mustBeUniqueForEachOperator");
Materialized materialized = Materialized.as(inMemoryStoreSupplier);

You can disable fault-tolerance for the in-memory store by an additional call to Materialized#disableLogging() before passing it to aggregate() (or any other operator), too.

If you want to plug-in any other third party store, you must implement the StoreSupplier and StateStore interfaces. The StateStore interface is for the actual integration code of the third party store into Kafka Streams. The StoreSupplier interface returns a new instance of your implemented store on each call of get().

Note: if you integrate a third party store, it is your sole responsibility to take care of fault-tolerance. There will be no store backup via a changelog topic out-of-the-box, but you will need to implement it by yourself if required.

Can I use NFS or network based storage to store my RocksDB?

Because disk performance has a direct impact on RocksDB’s performance, Confluent recommends locating this directory on a local disk and discourages configuring it to a remote network-based location like NFS or HDFS. This is because writing to remote disks is usually slower. Also, high availability isn’t a requirement for in-flight state. If high disk throughput is required, local SSD disks are preferred.

Failure and exception handling

Handling corrupted records and deserialization errors (“poison pill records”)?

You might experience that some of the incoming records from your Kafka Streams application are corrupted, or that the serializer/deserializer might be incorrect or buggy, or cannot handle all record types. These types of records are referred to as “poison pills”.

You can use the org.apache.kafka.streams.errors.DeserializationExceptionHandler interface to customize how to handle such poison pill records. The library also includes multiple implementations that represent the common handling patterns:

Option 1: Log the error and shut down the application

LogAndFailExceptionHandler implements DeserializationExceptionHandler and is the default setting in Kafka Streams. It handles any encountered deserialization exceptions by logging the error and throwing a fatal error to stop your Streams application. If your application is configured to use LogAndFailExceptionHandler, then an instance of your application will fail-fast when it encounters a corrupted record by terminating itself.

Properties streamsSettings = new Properties();
streamsSettings.put(
  StreamsConfig.DEFAULT_DESERIALIZATION_EXCEPTION_HANDLER_CLASS_CONFIG,
  LogAndFailExceptionHandler.class.getName()
);

Option 2: Skip corrupted records and log the error

LogAndContinueExceptionHandler is an alternative implementation of DeserializationExceptionHandler. Your application will log an ERROR message whenever it encounters a corrupted record, skip the processing of that record, and continue processing the next record. The rate of skipped records is recorded in a processor-node level metric named skippedDueToDeserializationError. For a full list of metrics that you can use for monitoring and alerting, see the documentation).

Properties streamsSettings = new Properties();
streamsSettings.put(
  StreamsConfig.DEFAULT_DESERIALIZATION_EXCEPTION_HANDLER_CLASS_CONFIG,
  LogAndContinueExceptionHandler.class.getName()
);

Option 3: Quarantine corrupted records (dead letter queue)

You can provide your own DeserializationExceptionHandler implementation. For example, you can choose to forward corrupt records into a quarantine topic (think: a “dead letter queue”) for further processing. To do this, use the Producer API to write a corrupted record directly to the quarantine topic. The drawback of this approach is that “manual” writes are side effects that are invisible to the Kafka Streams runtime library, so they do not benefit from the end-to-end processing guarantees of the Streams API.

Code example:

public class SendToDeadLetterQueueExceptionHandler implements DeserializationExceptionHandler {
    KafkaProducer<byte[], byte[]> dlqProducer;
    String dlqTopic;

    @Override
    public DeserializationHandlerResponse handle(final ProcessorContext context,
                                                 final ConsumerRecord<byte[], byte[]> record,
                                                 final Exception exception) {

        log.warn("Exception caught during Deserialization, sending to the dead queue topic; " +
                  "taskId: {}, topic: {}, partition: {}, offset: {}",
                  context.taskId(), record.topic(), record.partition(), record.offset(),
                  exception);

        dlqProducer.send(new ProducerRecord<>(dlqTopic, null, record.timestamp(), record.key(), record.value()));

        return DeserializationHandlerResponse.CONTINUE;
    }

    @Override
    public void configure(final Map<String, ?> configs) {
        dlqProducer = .. // get a producer from the configs map
        dlqTopic = .. // get the topic name from the configs map
    }
}

Properties streamsSettings = new Properties();
streamsSettings.put(
  StreamsConfig.DEFAULT_DESERIALIZATION_EXCEPTION_HANDLER_CLASS_CONFIG,
  SendToDeadLetterQueueExceptionHandler.class.getName()
);

Option 4: Interpret corrupted records as a sentinel value

You can also implement a custom serde to handle corrupt records internally rather than relying on DeserializationExceptionHandler settings. For example, you can implement a org.apache.kafka.common.serialization.Deserializer that, instead of throwing an exception, returns a “special-purpose” record that acts as sentinel record of your choice (e.g. null). This allows downstream processors of your application to recognize and handle such sentinel records accordingly whenever deserialization fails.

Code example:

public class ExceptionHandlingDeserializer implements Deserializer<MyObject> {

    public void configure(Map<String, ?> configs, boolean isKey) {
        // nothing to do
    }

    public MyObject deserialize(String topic, byte[] data) {
        try {
            // Attempt deserialization
            MyObject deserializedValue = deserialize(topic, data)

            // Ok, the record is valid (not corrupted).
            return deserializedValue;
        } catch (SerializationException e) {
            log.warn("Exception caught during Deserialization: {}", e.getMessage());

            // return the sentinel record upon corrupted data
            return null;
        }
    }

    public void close() {
        // nothing to do
    }
}

Important

Be careful when returning null: null record values have special semantics for tables, where they are interpreted as tombstones that will cause the deletion of record keys from the table.

Once your custom serde is implemented, you can either configure your application to use it as the default key and/or value serde, or use it explicitly when calling API methods such as KStream#to(), or both.

Interactive Queries

Handling InvalidStateStoreException: “the state store may have migrated to another instance”?

When attempting to access a local state store, you may run into an error such as the following:

org.apache.kafka.streams.errors.InvalidStateStoreException: the state store, my-key-value-store, may have migrated to another instance.
    at org.apache.kafka.streams.state.internals.StreamThreadStateStoreProvider.stores(StreamThreadStateStoreProvider.java:49)
    at org.apache.kafka.streams.state.internals.QueryableStoreProvider.getStore(QueryableStoreProvider.java:55)
    at org.apache.kafka.streams.KafkaStreams.store(KafkaStreams.java:699)

Typically this happens for two reasons:

  • The local KafkaStreams instance is not yet ready (i.e., not yet in runtime state RUNNING, see Run-time Status Information) and thus its local state stores cannot be queried yet.
  • The local KafkaStreams instance is ready (e.g. in runtime state RUNNING), but the particular state store was just migrated to another instance behind the scenes. This may notably happen during the startup phase of a distributed application or when you are adding/removing application instances.

There are a couple of ways to prevent running into InvalidStateStoreException, but keep in mind that, in any case, you are working with information that is valid only for a particular point in time – state stores may be migrated at any time behind the scenes, so your application should accept the fact that access to local state stores will come and go.

The simplest approach is to guard against InvalidStateStoreException when calling KafkaStreams#store():

// Example: Wait until the store of type T is queryable.  When it is, return a reference to the store.
public static <T> T waitUntilStoreIsQueryable(final String storeName,
                                              final QueryableStoreType<T> queryableStoreType,
                                              final KafkaStreams streams) throws InterruptedException {
  while (true) {
    try {
      return streams.store(storeName, queryableStoreType);
    } catch (InvalidStateStoreException ignored) {
      // store not yet ready for querying
      Thread.sleep(100);
    }
  }
}

An end-to-end example is available at ValidateStateWithInteractiveQueriesLambdaIntegrationTest.

Security

Application fails when running against a secured Kafka cluster?

When your application processes data from a secured Kafka cluster, you may run into error messages such as:

> Could not create internal topics: Could not create topic: <NAME OF TOPIC> due to Cluster authorization failed”

Make sure that the principal running your application has the ACL --cluster --operation Create set so that the application has the permissions to create internal topics.

Troubleshooting and debugging

Easier to interpret Java stacktraces?

When you write Kafka Streams applications, you often create chains of method calls such as the following:

// Code all on one line.  Unfortunately, this is bad practice when it comes to stacktraces.
myStream.map(...).filter(...).groupByKey(...).count(...);

Now if your code happens to trigger a runtime error, the Java stacktrace may not be very helpful because the JVM provides only line-number information about where an error occurred (“NullPointerException at line 123”). So, to pick the example above, you may deduce that some operation in the map/filter/countByKey chain failed, but the stacktrace will not tell you where exactly in the affected line.

A simple trick is to split your method chains across multiple lines, so that the row number returned by the stacktrace will more easily identify the actual culprit:

// Split the same code across multiple lines to benefit from more actionable stacktraces.
myStream
  .map(...)
  .filter(...)
  .groupByKey(...)
  .count(...);

Visualizing topologies?

You can visualize a topology of a Kafka Streams application by accessing its TopologyDescription. A TopologyDescription contains static information (i.e., not runtime information) about the processing graph, i.e., all nodes, (global) stores, and how nodes or stores are connected to each other. For each node detailed information about node-name, input/output topics (for sources and sinks) etc are available. Additionally, nodes are grouped in sub-topology (i.e., groups of nodes that are only connected via topics).

// for DSL
StreamsBuilder builder = new StreamsBuilder();
Topology topology = builder.build();
// for Processor API
Topology topology = new Topology();

TopologyDescription description = topology.describe();

// Get sub-topologies
Set<Subtopology> subtopologies = description.subtopologies();
// You can also get all nodes of a sub-topology (can be a `Source`, `Processor`, or `Sink`)
// All nodes have a name and a set of predecessors as well as successors
// Source and Sink also have input/output topic information
// Processor can have stores attached
// Each subtopology has a unique ID
Subtopology subtopology = ...
Set<Node> nodes = subtopology.nodes();
// access node informaton...

// You can also get information about global stores
// a GlobalStore has a source topic and an `Processor`
Set<GlobalStore> globalStores = description.globalStores();
// access global store informaton...

// Or simply print all information at once
System.out.println(description);

Printing the TopologyDescription for WordCountLambdaExample would look as follows:

Sub-topologies:
  Sub-topology: 0
    Processor: KSTREAM-FILTER-0000000005(stores: []) --> KSTREAM-SINK-0000000004 <-- KSTREAM-KEY-SELECT-0000000002
    Processor: KSTREAM-KEY-SELECT-0000000002(stores: []) --> KSTREAM-FILTER-0000000005 <-- KSTREAM-FLATMAPVALUES-0000000001
    Processor: KSTREAM-FLATMAPVALUES-0000000001(stores: []) --> KSTREAM-KEY-SELECT-0000000002 <-- KSTREAM-SOURCE-0000000000
    Source: KSTREAM-SOURCE-0000000000(topics: inputTopic) --> KSTREAM-FLATMAPVALUES-0000000001
    Sink: KSTREAM-SINK-0000000004(topic: Counts-repartition) <-- KSTREAM-FILTER-0000000005
  Sub-topology: 1
    Source: KSTREAM-SOURCE-0000000006(topics: Counts-repartition) --> KSTREAM-AGGREGATE-0000000003
    Processor: KTABLE-TOSTREAM-0000000007(stores: []) --> KSTREAM-SINK-0000000008 <-- KSTREAM-AGGREGATE-0000000003
    Sink: KSTREAM-SINK-0000000008(topic: outputTopic) <-- KTABLE-TOSTREAM-0000000007
    Processor: KSTREAM-AGGREGATE-0000000003(stores: [Counts]) --> KTABLE-TOSTREAM-0000000007 <-- KSTREAM-SOURCE-0000000006
Global Stores:
  none

Older releases

For releases prior to Confluent Platform 4.0.x, you can visualise the internal topology of a Kafka Streams application by calling the KafkaStreams#toString() method:

KafkaStreams streams = new KafkaStreams(topology, config);
// Start the Kafka Streams threads
streams.start();
// Print the internal topology to stdout
System.out.println(streams.toString());

An example topology for WordCountLambdaExample that is output from this call is shown below. All sources, sinks, and their backing topics, as well as all intermediate nodes and their state stores are collected and printed:

KafkaStreams processID: 5fe8281e-d756-42ec-8a92-111e4af3d4ca
    StreamsThread appId: wordcount-lambda-integration-test
    StreamsThread clientId: wordcount-lambda-integration-test-5fe8281e-d756-42ec-8a92-111e4af3d4ca
    StreamsThread threadId: wordcount-lambda-integration-test-5fe8281e-d756-42ec-8a92-111e4af3d4ca-StreamThread-1
    Active tasks:
        Running:
            StreamsTask taskId: 0_0
                ProcessorTopology:
                    KSTREAM-SOURCE-0000000000:
                        topics:        [inputTopic]
                        children:    [KSTREAM-FLATMAPVALUES-0000000001]
                    KSTREAM-FLATMAPVALUES-0000000001:
                        children:    [KSTREAM-KEY-SELECT-0000000002]
                    KSTREAM-KEY-SELECT-0000000002:
                        children:    [KSTREAM-FILTER-0000000005]
                    KSTREAM-FILTER-0000000005:
                        children:    [KSTREAM-SINK-0000000004]
                    KSTREAM-SINK-0000000004:
                        topic:        wordcount-lambda-integration-test-Counts-repartition
                Partitions [inputTopic-0]
            StreamsTask taskId: 1_0
                ProcessorTopology:
                    KSTREAM-SOURCE-0000000006:
                        topics:        [wordcount-lambda-integration-test-Counts-repartition]
                        children:    [KSTREAM-AGGREGATE-0000000003]
                    KSTREAM-AGGREGATE-0000000003:
                        states:        [Counts]
                        children:    [KTABLE-TOSTREAM-0000000007]
                    KTABLE-TOSTREAM-0000000007:
                        children:    [KSTREAM-SINK-0000000008]
                    KSTREAM-SINK-0000000008:
                        topic:        outputTopic
                Partitions [wordcount-lambda-integration-test-Counts-repartition-0]

            Suspended:
            Restoring:
            New:
        Standby tasks:
            Running:
            Suspended:
            Restoring:
            New:

Note that KafkaStreams#toString() returns more information than TopologyDescription, for example, the tasks currently assigned to each of the running stream threads. Starting in 4.0.x such runtime information is retrievable via the KafkaStreams#localThreadsMetadata() API, and as a result KafkaStreams#toString() is deprecated.

Inspecting streams and tables?

To inspect the records of a stream or a table, you can call the KStream#print() method. For a KTable you can inspect changes to it by getting a KTable’s changelog stream via KTable#toStream(). You can use print() to print the elements to STDOUT as shown below or you can write into a file via Printed.toFile("fileName").

Here is an example that uses KStream#print(Printed.toSysOut()):

import java.util.concurrent.TimeUnit;
KStream<String, Long> left = ...;
KStream<String, Long> right = ...;

// Java 8+ example, using lambda expressions
KStream<String, String> joined = left
    .join(right,
      (leftValue, rightValue) -> leftValue + " --> " + rightValue, /* ValueJoiner */
      JoinWindows.of(Duration.ofMinutes(5)),
      Joined.with(
        Serdes.String(), /* key */
        Serdes.Long(),   /* left value */
        Serdes.Long()))   /* right value */
    .print(Printed.toSysOut());

The output would be the records after the join; e.g., if we were joining two records with the same key K and values V1 and V2, then what is printed on the console would be K, V1 --> V2 as shown for some sample data below:

alice, 5 --> 7
bob, 234 --> 19
charlie, 9 --> 10

If you want to inspect the content of a KTable’s internal store, you can use Kafka Streams Interactive Queries for Confluent Platform.

Invalid Timestamp Exception

If you get an exception similar to the one shown below, there are multiple possible causes:

Exception in thread "StreamThread-1" org.apache.kafka.streams.errors.StreamsException: Input record {...} has invalid (negative) timestamp. \
        Possibly because a pre-0.10 producer client was used to write this record to Kafka without embedding a timestamp, \
        or because the input topic was created before upgrading the Kafka cluster to 0.10+. \
        Use a different TimestampExtractor to process this data.
  at org.apache.kafka.streams.processor.FailOnInvalidTimestamp.onInvalidTimestamp(FailOnInvalidTimestamp.java:62)

This error means that the timestamp extractor of your Kafka Streams application failed to extract a valid timestamp from a record. Typically, this points to a problem with the record (e.g., the record does not contain a timestamp at all), but it could also indicate a problem or bug in the timestamp extractor used by the application.

When does a record not contain a valid timestamp?

  • If you are using the default FailOnInvalidTimestamp timestamp extractor, it is most likely that your records do not carry an embedded timestamp (embedded record timestamps were introduced in Kafka’s message format in Kafka 0.10). This might happen, if for example, you consume a topic that is written by old Kafka producer clients (i.e., version 0.9 or earlier) or by third-party producer clients. Another situation where this may happen is after upgrading your Kafka cluster from 0.8 or 0.9 to 0.10, where all the data that was generated with 0.8 or 0.9 does not include the 0.10 message timestamps. You can consider using an alternative timestamp extractor like UsePartitionTimeOnInvalidTimestamp or LogAndSkipOnInvalidTimestamp, both of which handle negative timestamps more gracefully. See Kafka Streams Developer Guide: Timestamp Extractor for details.
  • If you are using a custom timestamp extractor, make sure that your extractor is properly handling invalid (negative) timestamps, where “properly” depends on the semantics of your application. For example, you can return a default timestamp or an estimated timestamp if you cannot extract a valid timestamp directly from the record.
  • You can also switch from event-time processing to processing-time semantics via WallclockTimestampExtractor; whether such a fallback is an appropriate response to this situation depends on your use case.

However, as a first step you should identify and fix the root cause for why such problematic records were written to Kafka in the first place. In a second step you may consider applying workarounds as described above when dealing with such records. Another option is to regenerate the records with correct timestamps and write them to a new Kafka topic.

When the timestamp extractor causes the problem?

In this situation you should debug and fix the erroneous extractor. If the extractor is built into Kafka, report the bug to the Kafka developer mailing list at dev@kafka.apache.org (see instructions at https://kafka.apache.org/contact); in the meantime, you may write a custom timestamp extractor that fixes the problem and configure your application to use that extractor for the time being.

Why do I get an IllegalStateException when accessing record metadata?

If you attach a new Processor/Transformer/ValueTransformer to your topology using a corresponding supplier, you need to make sure that the supplier returns a new instance each time get() is called. If you return the same object, a single Processor/Transformer/ValueTransformer would be shared over multiple tasks resulting in an IllegalStateException with error message "This should not happen as topic() should only be called while a record is processed" (depending on the method you are calling it could also be partition(), offset(), or timestamp() instead of topic()).

Why is punctuate() not called?

If you scheduled the punctuate() function based on event-time (i.e. PunctuationType.STREAM_TIME), then this function is triggered not based on wall-clock-time but purely data-driven (i.e., driven by internally tracked event-time). The event-time is derived from the extracted record timestamps provided by the used TimestampExtractor.

For example, let’s assume you scheduled a punctuate() function every 10 seconds based on PunctuationType.STREAM_TIME. If you were to process a stream of 60 records with consecutive timestamps from 1 (first record) to 60 seconds (last record), then punctuate() would be called 6 times – regardless of the time required to actually process those records; i.e., punctuate() would be called 6 times no matter whether processing these 60 records would take a second, a minute, or an hour.

Attention

Event-time is only advanced if all input partitions over all input topics have new data (with newer timestamps) available. If at least one partition does not have any new data available, event-time will not be advanced and thus punctuate() will not be triggered. This behavior is independent of the configured timestamp extractor, i.e., using WallclockTimestampExtractor does not enable wall-clock triggering of punctuate().

Scala: compile error “no type parameter”, “Java-defined trait is invariant in type T”

When using Scala without the Scala wrapper, you may occasionally run into a Scala compiler error similar to the following:

Error:(156, 8) no type parameters for method leftJoin:
    (x$1: org.apache.kafka.streams.kstream.KTable[String,VT],
     x$2: org.apache.kafka.streams.kstream.ValueJoiner[_ >: Long, _ >: VT, _ <: VR])
    org.apache.kafka.streams.kstream.KStream[String,VR]
exist so that it can be applied to arguments
    (org.apache.kafka.streams.kstream.KTable[String,String],
     org.apache.kafka.streams.kstream.ValueJoiner[Long,String,(String, Long)] with Serializable)
 --- because ---
argument expression's type is not compatible with formal parameter type;
 found   : org.apache.kafka.streams.kstream.ValueJoiner[Long,String,(String, Long)] with Serializable
 required: org.apache.kafka.streams.kstream.ValueJoiner[_ >: Long, _ >: ?VT, _ <: ?VR]
Note: Long <: Any (and org.apache.kafka.streams.kstream.ValueJoiner[Long,String,(String, Long)]
      with Serializable <: org.apache.kafka.streams.kstream.ValueJoiner[Long,String,(String, Long)]),
      but Java-defined trait ValueJoiner is invariant in type V1.
You may wish to investigate a wildcard type such as `_ <: Any`. (SLS 3.2.10)
Note: String <: Any (and org.apache.kafka.streams.kstream.ValueJoiner[Long,String,(String, Long)]
      with Serializable <: org.apache.kafka.streams.kstream.ValueJoiner[Long,String,(String, Long)]),
      but Java-defined trait ValueJoiner is invariant in type V2.
You may wish to investigate a wildcard type such as `_ <: Any`. (SLS 3.2.10)

The root cause of this problem is Scala-Java interoperability – the Kafka Streams API is implemented in Java, but your application is written in Scala. Notably, this problem is caused by how the type systems of Java and Scala interact. Generic wildcards in Java, for example, are often causing such Scala issues.

It is recommended to use the Scala wrapper to avoid this issue. If this is not possible, you must declare types explicitly in your Scala application in order for the code to compile. For example, you may need to break a single statement that chains multiple DSL operations into multiple statements, where each statement explicitly declares the respective return types. The StreamToTableJoinScalaIntegrationTest demonstrates how the types of return variables are explicitly declared.

How can I convert a KStream to a KTable without an aggregation step?

If you want to convert a derived KStream (i.e., a KSTream that is not read from a Kafka topic) into a KTable you have three options.

Option 2: Write KStream to Kafka, read back as KTable

You can write the KStream into a Kafka topic and read it back as a KTable. As per our general recommendation, you should manually pre-create this topic to ensure it has the correct number of partitions, topic settings, and so on.

StreamsBuilder builder = new StreamsBuilder();
KStream<String, Long> stream = ...; // some computation that creates the derived KStream

// You should manually create the dummy topic before starting your application.
//
// Also, because you want to read the topic back as a KTable, you might want to enable
// log compaction for this topic to align the topic's cleanup policy with KTable semantics.
stream.to("dummy-topic", Produced.with(Serdes.String(), Serdes.Long()));
KTable<String, Long> table = builder.table("dummy-topic", Consumed.with(Serdes.String(), Serdes.Long()));

This is the simplest approach with regard to the code. However, it has the disadvantages that (a) you need to manage an additional topic and that (b) it results in additional network traffic because data is written to and re-read from Kafka.

Option 3: Perform a dummy aggregation

As an alternative to option 2, you can choose to create a dummy aggregation step:

StreamsBuilder builder = new StreamsBuilder();
KStream<String, Long> stream = ...; // some computation that creates the derived KStream

// Java 8+ example, using lambda expressions
KTable<String, Long> table = stream.groupByKey().reduce(
    (aggValue, newValue) -> newValue);

This approach is somewhat more complex with regard to the code compared to option 2 but has the advantage that (a) no manual topic management is required and (b) re-reading the data from Kafka is not necessary.

In option 3, Kafka Streams will create an internal changelog topic to back up the KTable for fault tolerance. Thus, both approaches require some additional storage in Kafka and result in additional network traffic. Overall, it’s a trade-off between slightly more complex code in option 3 versus manual topic management in option 2.

RocksDB behavior in 1-core environments

There is a known issue with RocksDB when running in environments with just one CPU core. In some scenarios, the symptom is that the application’s performance might be very slow or unresponsive.

The workaround is to set a particular RocksDB configuration using the RocksDB config setter as follows:

 public static class CustomRocksDBConfig implements RocksDBConfigSetter {
   @Override
   public void setConfig(final String storeName, final Options options, final Map<String, Object> configs) {
      // Workaround: We must ensure that the parallelism is set to >= 2.
      int compactionParallelism = Math.max(Runtime.getRuntime().availableProcessors(), 2);
      // Set number of compaction threads (but not flush threads).
      options.setIncreaseParallelism(compactionParallelism);
   }
 }

Properties streamsSettings = new Properties();
streamsConfig.put(StreamsConfig.ROCKSDB_CONFIG_SETTER_CLASS_CONFIG, CustomRocksDBConfig.class);

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