Akka Stream Kafka vs Kafka Streams
I am currently working with Akka Stream Kafka to interact with kafka and I was wonderings what were the differences with Kafka Streams.
I know that the Akka based approach implements the reactive specifications and handles back-pressure, functionality that kafka streams seems to be lacking.
What would be the advantage of using kafka streams over akka streams kafka?
Solution 1:
Your question is very general, so I'll give a general answer from my point of view.
First, I've got two usage scenario:
- cases where I'm reading data from kafka, processing it and writing some output back to kafka, for these I'm using kafka streams exclusively.
- cases where either the data source or sink is not kafka, for those I'm using akka streams.
This already allows me to answer the part about back-pressure: for the 1st scenario above, there is a back-pressure mechanism in kafka streams.
Let's now only focus on the first scenario described above. Let's see what I would loose if I decided to stop using Kafka streams:
- some of my stream processors stages need a persistent (distributed) state store, kafka streams provides it for me. It is something that akka streams doesn't provide.
- scaling, kafka streams automatically balances the load as soon as a new instance of a stream processor is started, or as soon as one gets killed. This works inside the same JVM, as well as on other nodes: scaling up and out. This is not provided by akka streams.
Those are the biggest differences that matter to me, I'm hoping that it makes sense to you!
Solution 2:
The big advantage of Akka Stream over Kafka Streams would be the possibility to implement very complex processing graphs that can be cyclic with fan in/out and feedback loop. Kafka streams only allows acyclic graph if I am not wrong. It would be very complicated to implement cyclic processing graph on top of Kafka streams
Solution 3:
Found this article to give a good summary of distributed design concerns that Kafka Streams
provides (complements Akka Streams
).
https://www.beyondthelines.net/computing/kafka-streams/
message ordering: Kafka maintains a sort of append only log where it stores all the messages, Each message has a sequence id also known as its offset. The offset is used to indicate the position of a message in the log. Kafka streams uses these message offsets to maintain ordering.
partitioning: Kafka splits a topic into partitions and each partition is replicated among different brokers. The partitioning allows to spread the load and replication makes the application fault-tolerant (if a broker is down the data are still available). That’s good for data partitioning but we also need to distribute the processes in a similar way. Kafka Streams uses the processor topology that relies on Kafka group management. This is the same group management that is used by the Kafka consumer to distribute load evenly among brokers (This work is mainly managed by the brokers).
Fault tolerance: data replication ensures data fault tolerance. Group management has fault tolerance built-in as it redistributes the workload among remaining live broker instances.
State management: Kafka streams provides a local storage backed up by a kafka change-log topic which uses log compaction (keeps only latest value for a given key).Kafka log compaction
Reprocessing: When starting a new version of the app, we can reprocess the logs from the start to compute new state then redirect the traffic the new instance and shutdown old application.
Time management: “Stream data is never complete and can always arrive out-of-order” therefore one must distinguish the event time vs processed time and handle it correctly.
Author also says "Using this change-log topic Kafka Stream is able to maintain a “table view” of the application state."
My take is that this applies mostly to an enterprise application where the "application state" is ... small.
For a data science application working with "big data", the "application state" produced by a combination of data munging, machine learning models and business logic to orchestrate all of this will likely not be managed well with Kafka Streams
.
Also, am thinking that using a "pure functional event sourcing runtime" like https://github.com/notxcain/aecor will help make the mutations explicit and separate the application logic from the technology used to manage the persistent form of the state through the principled management of state mutation and IO "effects" (functional programming).
In other words the business logic does not become tangled with the Kafka
apis.
Solution 4:
Akka Streams emerged as a dataflow-centric abstraction for the Akka Actors model. These are high-performance library built for the JVM and specially designed for general-purpose microservices.
Whereas as long as Kafka Streams is concerned, these are client libraries used to process unbounded data. They are used to read data from Kafka topics, then process it, and write the results to new topics.