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wix
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Description

Greyhound - Rich Kafka client library

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Greyhound

Maven Central Github Actions Scala/Java High-level SDK for Apache Kafka.

Greyhound

Why Greyhound?

Kafka is shipped with a Java SDK which allows developers to interact with a Kafka cluster. However, this SDK consists of somewhat low-level APIs which are difficult to use correctly. Greyhound seeks to provide a higher-level interface to Kafka and to express richer semantics such as parallel message handling or retry policies with ease.

You can read more about it on this blog post - “Building a High-level SDK for Kafka: Greyhound Unleashed

The Open-sourced version of Greyhound is still in stages of initial rollout, so APIs might not be fully stable yet.

Available APIs:

  • ZIO based API
  • Scala Futures
  • Java

Greyhound main features:

  • Declarative API - when you want to consume messages from Kafka using the consumer API provided in the Java SDK, you need to run an infinite while loop which polls for new records, execute some custom code, and commit offsets. This might be fine for simple applications, however, it's hard to get all the subtleties right - especially when you want to ensure your processing guarantees (when do you commit), handle consumer rebalances gracefully, handle errors (Either originating from Kafka or from user's code), etc. This requires specific know-how and adds a lot of boilerplate when all you want to do is process messages from a topic. Greyhound tries to abstract away these complexities by providing a simple, declarative API, and to allow the developers to focus on their business logic instead of how to access Kafka correctly.

  • Parallel message handling - A single Kafka consumer is single-threaded, and if you want to achieve parallelism with your message handling (which might be crucial for high throughput topics) you need to manually manage your threads and/or deploy more consumer instances. Greyhound automatically handles parallelizing message handling for you with automatic throttling. Also, Greyhound uses a concurrency model based on fibers (or green-threads) which are much more lightweight than JVM threads, and makes async workloads extremely efficient.

  • Consumer retries - error handling is tricky. Sometimes things fail without our control (database is temporarily down, API limit exceeded, network call timed-out, etc.) and the only thing we can do to recover is to retry the same operation after some back-off. However, we do not want to block our consumer until the back-off expires, nor do we want to retry the action in a different thread and risk losing the messages in case our process goes down. Greyhound provides a robust retry mechanism, which produces failed records to special retry topics where they will be handled later, allowing the main consumer to keep working while ensuring no messages will be lost.

  • Observability - Greyhound reports many useful metrics which are invaluable when trying to debug your system, or understand how it is operating.

Usage

Add greyhound to your build

All Greyhound modules can be found in Maven Central Repository.

See examples of how to add greyhound modules to your build (Maven, Gradle, SBT, etc...).

Basics

First let's review some basic messaging terminology:

  • Kafka maintains feeds of messages in categories called topics.
  • Processes that publish messages to a Kafka topic are called producers.
  • Processes that subscribe to topics and process the feed of published messages are called consumers.
  • Kafka is run as a cluster comprised of one or more servers, each of which is called a broker.

Scala
Future
based API

The basic Future API is less powerful than the ZIO API, but it's a quick way to get started without prior knowledge of effect systems.

import com.wixpress.dst.greyhound.core.consumer.domain.ConsumerRecord
import com.wixpress.dst.greyhound.core.producer.ProducerRecord
import com.wixpress.dst.greyhound.core.Serdes
import com.wixpress.dst.greyhound.future._
import com.wixpress.dst.greyhound.future.GreyhoundConsumer.aRecordHandler
import scala.concurrent.{Future, ExecutionContext}

val config = GreyhoundConfig(Set("localhost:9092"))

// Define your Greyhound topology val builder = GreyhoundConsumersBuilder(config) .withConsumer( GreyhoundConsumer( initialTopics = Set("some-topic"), group = "some-consumer-group", handle = aRecordHandler { new RecordHandler[Int, String] { override def handle(record: ConsumerRecord[Int, String])(implicit ec: ExecutionContext): Future[Any] = Future{ /* Your handling logic */ } } }, keyDeserializer = Serdes.IntSerde, valueDeserializer = Serdes.StringSerde, clientId = "client-id-1"))

for { // Start consuming consumers

Using a custom metrics reporter

By default, all Greyhound metrics are reported using a simple SLF4J logger. You can easily swap it for your own custom reporter like so:

import com.wixpress.dst.greyhound.core.metrics.GreyhoundMetric
import com.wixpress.dst.greyhound.future._

val runtime = GreyhoundRuntimeBuilder() .withMetricsReporter { metric: GreyhoundMetric => // Report to Prometheus / StatsD / OpenTracing etc.. } .build

val config = GreyhoundConfig(Set("boostrap-server"), runtime) val builder = GreyhoundConsumersBuilder(config) .withConsumer(..) // ...

Java API

Greyhound also offers a Java API - a docker based quick-start Java App that demonstrates using Greyhound is available to play with.

ZIO API

Greyhound is based on the ZIO library which provides type-safe, composable asynchronous and concurrent programming environment for Scala. These docs assume the reader has basic familiarity with ZIO's core notions, like effects, managed resources etc.

Producing messages

In order to produce a messages to Kafka, you need a producer.

Producer.make
will create a producer wrapped in a
ZManaged
. You can then use it like so:
import com.wixpress.dst.greyhound.core.producer._
import com.wixpress.dst.greyhound.core.Serdes

val bootstrapServer = "localhost:9092" val config = ProducerConfig(bootstrapServer/, retryPolicy, extraProperties/)

Producer.make(config).use { producer => producer.produce( record = ProducerRecord( topic = "some-topic", value = "hello world", key = Some(1234)), keySerializer = Serdes.IntSerde, valueSerializer = Serdes.StringSerde) }

Consuming messages

To consume a topic from Kafka, We'll create a

RecordConsumer
by providing the consumer group and set of topics to subscribe to. We'll attach a
RecordHandler
to have our custom user code executed upon every record, and choose (or implement a custom)
Deserializer
to transform the byte arrays to strongly typed values.
RecordConsumer

Start a consumer by providing a Consumer Group ID, a set of topics to subscribe to (or a pattern), and the RecordHandler to execute custom code upon new individual records.
Ordering in Kafka is only guaranteed within a single partition, so Greyhound will parallelize execution by devoting a single fiber for each partition. It will also automatically pause polling for specific partitions in case handling is too slow, without affecting other partitions.

import com.wixpress.dst.greyhound.core.consumer._
import com.wixpress.dst.greyhound.core.consumer.domain._
import zio._

val group = "some-consumer-group-id" val handler: RecordHandler[Any, Nothing, Chunk[Byte], Chunk[Byte]] = ???

// Start consumer, will close on interruption val bootstrapServers = "localhost:9092" val initialTopics = Set("topic-A") RecordConsumer.make(RecordConsumerConfig(bootstrapServers, group, ConsumerSubscription.Topics(initialTopics)), handler) .useForever

// Start another consumer, this time subscribing to a topic pattern RecordConsumer.make(RecordConsumerConfig(bootstrapServers, group, ConsumerSubscription.TopicPattern("topic.*")), handler) .useForever

Record handler

A

RecordHandler[-R, +E, K, V]
describes a handling function on one or more topics. It handles records of type
ConsumerRecord[K, V]
, requires an environment of type
R
and might fail with errors of type
E
.

The

RecordHandler
is a composable building block, which means you can provide middleware record handlers that can intercept and enrich custom code without any magic involved.
You can transform your handler by using the built-in combinators like so (types can be inferred, but shown here for readability):
import java.util.UUID
import com.wixpress.dst.greyhound.core.consumer.domain.RecordHandler
import com.wixpress.dst.greyhound.core.consumer._
import com.wixpress.dst.greyhound.core.Deserializer
import com.wixpress.dst.greyhound.core.Serdes
import zio.console._
import zio._

case class EmailId(id: Int) case class EmailRequest(/.../)

// Base handler with your custom logic val emailRequestsTopic = "email-requests" val handler1: RecordHandler[Any, RuntimeException, EmailId, EmailRequest] = RecordHandler { record => // Do something with email requests... ZIO.fail(new RuntimeException("Oops!")) }

// Recover from errors val handler2: RecordHandler[Console, Nothing, EmailId, EmailRequest] = handler1.withErrorHandler { case (error, record) => putStrLn(error.getMessage) }

// Deserialize records val emailIdDeserializer: Deserializer[EmailId] = Serdes.IntSerde.map(EmailId) val emailRequestDeserializer: Deserializer[EmailRequest] = ??? val handler3: RecordHandler[Console, Nothing, Chunk[Byte], Chunk[Byte]] = handler2.withDeserializers(emailIdDeserializer, emailRequestDeserializer)

Notice that

RecordConsumer
accepts a
RecordHandler[_, _, Chunk[Byte], Chunk[Byte]]
, indicating that key and value deserializers to
Chunk[Byte]
must be applied to any handler the user provides.
You can either write a handler that accepts
Chunk[Byte]
as input for key and value, or provide deserializers to the handler and accept typed input, according to the output of the provided deserializers.

Serializers / deserializers

Kafka doesn't know or care about your message formats when producing or consuming. The underlying protocol uses raw byte arrays to represent your messages, so it's your job to tell it how to serialize and deserialize your domain objects and custom types to/from bytes.

  • Serializer[-A]
    - takes values of type
    A
    and converts them to bytes
  • Deserializer[+A]
    - takes bytes and converts them to values of type
    A
  • Serde[A]
    is both a
    Serializer[A]
    and a
    Deserializer[A]

Transforming

Often serialization / deserialization could be created by modifying existing data types. For example, you could encode a timestamp as a

Long
if you use the epoch millis as the representation. You can use the built in combinators to transform existing deserializers:
import com.wixpress.dst.greyhound.core.{Serdes, Deserializer}
import java.time.Instant

val longDeserializer: Deserializer[Long] = Serdes.LongSerde

val instantDeserializer: Deserializer[Instant] = longDeserializer.map(millis => Instant.ofEpochMilli(millis))

You could also modify a serializer by adapting the input using the

contramap
combinator:
import com.wixpress.dst.greyhound.core.{Serdes, Serializer}
import java.time.Instant

val longSerializer: Serializer[Long] = Serdes.LongSerde

val instantSerializer: Serializer[Instant] = longSerializer.contramap(instant => instant.toEpochMilli)

Or do both simultaneously using the

inmap
combinator:
import com.wixpress.dst.greyhound.core.{Serdes, Serde}
import java.time.Instant

val longSerde: Serde[Long] = Serdes.LongSerde

val instantSerde: Serde[Instant] = longSerde.inmap(Instant.ofEpochMilli)(_.toEpochMilli)

This could be useful for your own custom domain types as well. For example, modifying a string or byte array

Serde
to represent your own types encoded as JSON.

Consumer Non-Blocking Retries

RecordConsumer
provides a built-in retry mechanism for consumer code. It is possible to create a retry policy for failed user-supplied effects. The retry mechanism is influenced by this Uber's blog post.
A retry policy is defined by a sequence of intervals indicating the back-off time between attemps. For each attempt Greyhound automatically creates a topic named:
$original_topic-[group_id]-retry-[0..n]
and subscribes to it.
When an effect fails, Greyhound either submits the record to the subsequent retry topic, adding specific headers indicating when to execute the handler for this record.
When the record is consumed via the retry topics, the record handler reads the relevant headers and potentially 'sleeps' until it is time to invoke the user code.
Notice this waiting is done in a non-blocking way, so no resources are wasted.

Usage: ```scala import com.wixpress.dst.greyhound.core.consumer._ import com.wixpress.dst.greyhound.core.consumer.domain._ import com.wixpress.dst.greyhound.core.consumer.retry._ import com.wixpress.dst.greyhound.core.producer._ import com.wixpress.dst.greyhound.core.Serdes._ import zio.duration._ import zio.ZIO

val group = "groupId" val topic = "topicY" val handler = RecordHandler { record: ConsumerRecord[String, String] => if (record.value == "OK") ZIO.unit else ZIO.fail(new RuntimeException("Failed..."))
}

val retryConfig = ZRetryConfig.nonBlockingRetry(group, 1.second, 30.seconds, 1.minute) val bootstrapServers = "localhost:9092" val topics = Set("topic-A") RecordConsumer.make( RecordConsumerConfig(bootstrapServers, group, ConsumerSubscription.Topics(topics), retryConfig = Some(retryConfig)), handler.withDeserializers(StringSerde, StringSerde) ).useForever ```

In this example the record handler fails for any input other than the string "OK", so any other record will be re-sent to the subsequent topic, until finally the record is consumed by last topic.

Configuring retries with a pattern consumer

In terms of API - there's no difference to configuring retries for a fixed set of topics. However, when configuring a consumer that subscribes to a pattern, we cannot use the same strategy for retry topics naming. This is due to the fact we don't know up front which retry topics we should subscribe to, since the original topics we're subscribing to aren't known.
The strategy for naming retry topics in this case:

__gh_pattern-retry-[group_id]-attempt-[0..n]
.
Notice the original topic name isn't part of the retry topics. This means 2 things:
1. We know upfront which topics to create and subscribe to. 2. We cannot start separate consumers with the same group id, where each subscribes to a different pattern and performs different logic. This is due to the fact that all consumers will subscribe to the same retry topics. Doing something like this will result in separate consumers 'stealing' each other's retry messages.

It may seem like an implementation detail - but it's important to proceed with the last part in mind.

Consumer Blocking Retries

In case the consumer needs to process messages in-order, a blocking retry configuration is available.

When retry configuration is setup this way, the user provided handler code will be retried on the same message according to the provided intervals. There are several different options when configuring blocking retries: * finiteBlockingRetry * infiniteBlockingRetry * exponentialBackoffBlockingRetry * blockingFollowedByNonBlockingRetry

import com.wixpress.dst.greyhound.core.consumer._
import com.wixpress.dst.greyhound.core.consumer.domain._
import com.wixpress.dst.greyhound.core.consumer.retry._
import com.wixpress.dst.greyhound.core.producer._
import com.wixpress.dst.greyhound.core.Serdes._
import zio.duration._
import zio.ZIO

val group = "groupId" val topic = "topicY" val handler = RecordHandler { record: ConsumerRecord[String, String] => if (record.value == "OK") ZIO.unit else ZIO.fail(new RuntimeException("Failed..."))
}

val retryConfig = ZRetryConfig.finiteBlockingRetry(1.second, 30.seconds, 1.minute) val bootstrapServers = "localhost:9092" val topics = Set("topic-A") RecordConsumer.make( RecordConsumerConfig(bootstrapServers, group, ConsumerSubscription.Topics(topics), retryConfig = Some(retryConfig)), handler.withDeserializers(StringSerde, StringSerde) ).useForever

In order to avoid a lag build-up between producer and consumer for the partition on which a message is failing to process, there is a consumer API call to skip retrying for that partition:

import com.wixpress.dst.greyhound.core.consumer._

RecordConsumer.make( RecordConsumerConfig(...), handler ).flatMap(consumer => consumer.setBlockingState(IgnoreOnceFor(TopicPartition("topic-A", 0))))

Producing via local disk

Greyhound offers a producer which writes records to local disk before it flushes them to Kafka. With this approach there will be definitely be some extra latency, but during longer outages records will be safely stored locally before they can be flushed.

import com.wixpress.dst.greyhound.core.producer._
import com.wixpress.dst.greyhound.core.producer.buffered._
import com.wixpress.dst.greyhound.core.producer.buffered.buffers._
import zio.duration._
import zio._

def producer: RManaged[ZEnv with GreyhoundMetrics, LocalBufferProducer[Any]] = for { producer p.produce(record) .flatMap(_.kafkaResult .await .tap(res => zio.console.putStrLn(res.toString)) .fork ) }

Notice that the effect of producing completes when the record has been persisted to Disk. The effect results with a promise that fulfils with the Kafka produce metadata.

The producer will retry flushing failed records to Kafka in an interval defined by

retryInterval
config, until they expire according to
giveUpAfter
config. Upon resource close, it will block until all records are flushed, limited to
shutdownFlushTimeout
config.

Use the

strategy
config to define how the producer flushes records to Kafka:
ProduceStrategy.Sync(concurrency: Int)
ProduceStrategy.Async(batchSize: Int, concurrency: Int)
ProduceStrategy.Unordered(batchSize: Int, concurrency: Int)

All of the strategies create N fibers (defined by

concurrency: Int
), grouped by keys or partitions, and each fiber is responsible for flushing a range of targets (so there's no ordering or synchronization between different fibers).
*
ProduceStrategy.Sync
is the slowest strategy: it does not produce a record on a given key before the previous record has been acknowledged by Kafka. It will retry each record individually until successful, before continuing to the next record.
*
ProduceStrategy.Async
will produce a batch of records and wait for them all to complete. If some failed, it will retry the failures until successful.
*
ProduceStrategy.Unordered
is the same as Async, only it tries to produce to Kafka directly in the event of a local disk failure to append records.

Testing

Use the embedded Kafka to test your app: ```scala import com.wixpress.dst.greyhound.testkit._

ManagedKafka.make(ManagedKafkaConfig(kafkaPort = 9092, zooKeeperPort = 2181)).use { kafka => // Start producing and consuming messages, // configure broker address on producers and consumers to localhost:9092

// outside of this scope Kafka will be shutdown. } ```

This will start a real Kafka broker and Zookeeper instance on defined ports. Use those ports to access Kafka within the managed scope.

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