I'm using a single kafka topic for different types of related messages. Topic name is: apiEvents. Events are of type:
ApiUpdateEvent
EndpointUpdateEvent
TemplateUpdateEvent
One of the applications I have, consumes all these events. Moreover - I want it to consume the same event differently (twice), in two unrelated use cases.
For example, two use cases for the same event (EndpointUpdateEvent):
I'd like create a windowed time frame of 500ms and respond to an aggregation of all the events that came in this time frame - ONCE!
These same events as stated in section (1) - I want to respond to each one individually, by triggering some DB operation.
Thus, I want to write code that will be clean and maintainable and wouldn't want to throw all use cases in one big consumer with a lot of mess.
A solution I've thought about is to write a new kafka-consumer for each use case and to assign each consumer a different groupId (within the same application). That way, each business logic use case will have its own class which will handle the events in its own special way. Seems tidy enough.
May there arise any problems if I create too many consumer groups in one application?
Is there a better solution that will allow me to keep clean and divide different business logic use cases?
It sounds like you are on the right track by using separate consumer groups for different business logic use cases that will have separately managed offsets to track the individual progress. This will also align more with a microservice style architecture where different business cases may be implemented in different components.
One more consideration - And I cannot judge this just based on the information provided, but I would also think about splitting your topic into one per event type. It is not a problem for a consumer group to be subscribed to multiple topics at the same time. Whereas I believe it is less efficient to have consumers process/discard a large number of events that are irrelevant for them.
You can use Kafka Streams Processor API to consume and act on individual messages as well as window them within a specific, rolling/hopping time period
Related
I am trying to implement event sourcing/CQRS/DDD for the first time, mostly for learning purposes, where there is the idea of an event store and a message queue such as Apache Kafka, and you have events flowing from event store => Kafka Connect JDBC/Debezium CDC => Kafka.
I am wondering why there needs to be a separate event store when it sounds like its purpose can be fulfilled by Kafka itself with its main features and log compaction or configuring log retention for permanent storage. Should I store my events in a dedicated store like RDBMS to feed into Kafka or should I feed them straight into Kafka?
Much of the literature on event-sourcing and cqrs comes from the [domain driven design] community; in its earliest form, CQRS was called DDDD... Distributed domain driven design.
One of the common patterns in domain driven design is to have a domain model ensuring the integrity of the data in your durable storage, which is to say, ensuring that there are no internal contradictions...
I am wondering why there needs to be a separate event store when it sounds like its purpose can be fulfilled by Kafka itself with its main features and log compaction or configuring log retention for permanent storage.
So if we want an event stream with no internal contradictions, how do we achieve that? One way is to ensure that only a single process has permission to modify the stream. Unfortunately, that leaves you with a single point of failure -- the process dies, and everything comes to an end.
On the other hand, if you have multiple processes updating the same stream, then you have risk of concurrent writes, and data races, and contradictions being introduced because one writer couldn't yet see what the other one did.
With an RDBMS or an Event Store, we can solve this problem by using transactions, or compare and swap semantics; and attempt to extend the stream with new events is rejected if there has been a concurrent modification.
Furthermore, because of its DDD heritage, it is common for the durable store to be divided into many very fine grained partitions (aka "aggregates"). One single shopping cart might reasonably have four streams dedicated to it.
If Kafka lacks those capabilities, then it is going to be a lousy replacement for an event store. KAFKA-2260 has been open for more than four years now, so we seem to be lacking the first. From what I've been able to discern from the Kakfa literature, it isn't happy about fine grained streams either (although its been a while since I checked, perhaps things have changed).
See also: Jesper Hammarbäck writing about this 18 months ago, and reaching similar conclusions to those expressed here.
Kafka can be used as a DDD event store, but there are some complications if you do so due to the features it is missing.
Two key features that people use with event sourcing of aggregates are:
Load an aggregate, by reading the events for just that aggregate
When concurrently writing new events for an aggregate, ensure only one writer succeeds, to avoid corrupting the aggregate and breaking its invariants.
Kafka can't do either of these currently, since 1 fails since you generally need to have one stream per aggregate type (it doesn't scale to one stream per aggregate, and this wouldn't necessarily be desirable anyway), so there's no way to load just the events for one aggregate, and 2 fails since https://issues.apache.org/jira/browse/KAFKA-2260 has not been implemented.
So you have to write the system in such as way that capabilities 1 and 2 aren't needed. This can be done as follows:
Rather than invoking command handlers directly, write them to
streams. Have a command stream per aggregate type, sharded by
aggregate id (these don't need permanent retention). This ensures that you only ever process a single
command for a particular aggregate at a time.
Write snapshotting code for all your aggregate types
When processing a command message, do the following:
Load the aggregate snapshot
Validate the command against it
Write the new events (or return failure)
Apply the events to the aggregate
Save a new aggregate snapshot, including the current stream offset for the event stream
Return success to the client (via a reply message perhaps)
The only other problem is handling failures (such as the snapshotting failing). This can be handled during startup of a particular command processing partition - it simply needs to replay any events since the last snapshot succeeded, and update the corresponding snapshots before resuming command processing.
Kafka Streams appears to have the features to make this very simple - you have a KStream of commands that you transform into a KTable (containing snapshots, keyed by aggregate id) and a KStream of events (and possibly another stream containing responses). Kafka allows all this to work transactionally, so there is no risk of failing to update the snapshot. It will also handle migrating partitions to new servers, etc. (automatically loading the snapshot KTable into a local RocksDB when this happens).
there is the idea of an event store and a message queue such as Apache Kafka, and you have events flowing from event store => Kafka Connect JDBC/Debezium CDC => Kafka
In the essence of DDD-flavoured event sourcing, there's no place for message queues as such. One of the DDD tactical patterns is the aggregate pattern, which serves as a transactional boundary. DDD doesn't care how the aggregate state is persisted, and usually, people use state-based persistence with relational or document databases. When applying events-based persistence, we need to store new events as one transaction to the event store in a way that we can retrieve those events later in order to reconstruct the aggregate state. Thus, to support DDD-style event sourcing, the store needs to be able to index events by the aggregate id and we usually refer to the concept of the event stream, where such a stream is uniquely identified by the aggregate identifier, and where all events are stored in order, so the stream represents a single aggregate.
Because we rarely can live with a database that only allows us to retrieve a single entity by its id, we need to have some place where we can project those events into, so we can have a queryable store. That is what your diagram shows on the right side, as materialised views. More often, it is called the read side and models there are called read-models. That kind of store doesn't have to keep snapshots of aggregates. Quite the opposite, read-models serve the purpose to represent the system state in a way that can be directly consumed by the UI/API and often it doesn't match with the domain model as such.
As mentioned in one of the answers here, the typical command handler flow is:
Load one aggregate state by id, by reading all events for that aggregate. It already requires for the event store to support that kind of load, which Kafka cannot do.
Call the domain model (aggregate root method) to perform some action.
Store new events to the aggregate stream, all or none.
If you now start to write events to the store and publish them somewhere else, you get a two-phase commit issue, which is hard to solve. So, we usually prefer using products like EventStore, which has the ability to create a catch-up subscription for all written events. Kafka supports that too. It is also beneficial to have the ability to create new event indexes in the store, linking to existing events, especially if you have several systems using one store. In EventStore it can be done using internal projections, you can also do it with Kafka streams.
I would argue that indeed you don't need any messaging system between write and read sides. The write side should allow you to subscribe to the event feed, starting from any position in the event log, so you can build your read-models.
However, Kafka only works in systems that don't use the aggregate pattern, because it is essential to be able to use events, not a snapshot, as the source of truth, although it is of course discussable. I would look at the possibility to change the way how events are changing the entity state (fixing a bug, for example) and when you use events to reconstruct the entity state, you will be just fine, snapshots will stay the same and you'll need to apply correction events to fix all the snapshots.
I personally also prefer not to be tightly coupled to any infrastructure in my domain model. In fact, my domain models have zero dependencies on the infrastructure. By bringing the snapshotting logic to Kafka streams builder, I would be immediately coupled and from my point of view it is not the best solution.
Theoretically you can use Kafka for Event Store but as many people mentioned above that you will have several restrictions, biggest of those, only able to read event with the offset in the Kafka but no other criteria.
For this reason they are Frameworks there dealing with the Event Sourcing and CQRS part of the problem.
Kafka is only part of the toolchain which provides you the capability of replaying events and back pressure mechanism that are protecting you from overload.
If you want to see how all fits together, I have a blog about it
This is easy for projections that subscribe to all events from the stream, you just keep version of the last event applied on your read model. But what do you do when projection is composite of multiple streams? Do you keep version of each stream that is partaking in the projection. But then what about the gaps, if you are not subscribing to all events? At most you can assert that version is greater than the last one. How do others deal with this? Do you respond to every event and bump up version(s)?
For the EventStore, I would suggest using the $all stream as the default stream for any read-model subscription.
I have used the category stream that essentially produces the snapshot of a given entity type but I stopped doing so since read-models serve a different purpose.
It might be not desirable to use the $all stream as it might also get events, which aren't domain events. Integration events could be an example. In this case, adding some attributes either to event contracts or to the metadata might help to create an internal (JS) projection that will create a special all stream for domain events, or any event category in that regard, where you can subscribe to. You can also use a negative condition, for example, filter out all system events and those that have the original stream name starting with Integration.
As well as processing messages in the correct order, you also have the problem of resuming a projection after it is restarted - how do you ensure you start from the right place when you restart?
The simplest option is to use an event store or message broker that both guarantees order and provides some kind of global stream position field (such as a global event number or an ordered timestamp with a disambiguating component such as MongoDB's Timestamp type). Event stores where you pull the events directly from the store (such as eventstore.org or homegrown ones built on a database) tend to guarantee this. Also, some message brokers like Apache Kafka guarantee ordering (again, this is pull-based). You want at-least-once ordered delivery, ideally.
This approach limits write scalability (reads scale fine, using read replicas) - you can shard your streams across multiple event store instances in various ways, then you have to track the position on a per-shard basis, which adds some complexity.
If you don't have these ordering, delivery and position guarantees, your life is much harder, and it may be hard to make the system completely reliable. You can:
Hold onto messages for a while after receiving them, before processing them, to allow other ones to arrive
Have code to detect missing or out-of-order messages. As you mention, this only works if you receive all events with a global sequence number or if you track all stream version numbers, and even then it isn't reliable in all cases.
For each individual stream, you keep things in order by fetching them from a data store that knows the correct order. A way of thinking of this is that your query the data store, and you get a Document Message back.
It may help to review Greg Young's Polyglot Data talk.
As for synchronization of events in multiple streams; a thing that you need to recognize is that events in different streams are inherently concurrent.
You can get some loose coordination between different streams if you have happens-before data encoded into your messages. "Event B happened in response to Event A, therefore A happened-before B". That gets you a partial ordering.
If you really do need a total ordering of everything everywhere, then you'll need to be looking into patterns like Lamport Clocks.
I want to use Lagom to build a data processing pipeline. The first step in this pipeline is a service using a Twitter client to supscribe to a stream of Twitter messages. For each new message I want to persist the message in Cassandra.
What I dont understand is given I model my Aggregare root as a List of TwitterMessages for example, after running for some time this aggregare root will be several gigabytes in size. There is no need to store all the TwitterMessages in memory since the goal of this one service is just to persist each incomming message and then publish the message out to Kafka for the next service to process.
How would I model my aggregate root as Persistent Entitie for a stream of messages without it consuming unlimited resources? Are there any example code showing this usage if Lagom?
Event sourcing is a good default go to, but not the right solution for everything. In your case it may not be the right approach. Firstly, do you need the Tweets persisted, or is it ok to publish them directly to Kafka?
Assuming you need them persisted, aggregates should store in memory whatever they need to validate incoming commands and generate new events. From what you've described, your aggregate doesn't need any data to do that, so your aggregate would not be a list of Twitter messages, rather, it could just be NotUsed. Each time it gets a command it emits a new event for that Tweet. The thing here is, it's not really an aggregate, because you're not aggregating any state, you're just emitting events in response to commands with no invariants or anything. And so, you're not really using the Lagom persistent entity API for what it was made to be used for. Nevertheless, it may make sense to use it in this way anyway, it's a high level API that comes with a few useful things, including the streaming functionality. But there are also some gotchas that you should be aware of, you put all your Tweets in one entity, you limit your throughput to what one core on one node can do sequentially at a time. So maybe you could expect to handle 20 tweets a second, if you ever expect it to ever be more than that, then you're using the wrong approach, and you'll need to at a minimum distribute your tweets across multiple entities.
The other approach would be to simply store the messages directly in Cassandra yourself, and then publish directly to Kafka after doing that. This would be a lot simpler, a lot less mechanics involved, and it should scale very nicely, just make sure you choose your partition key columns in Cassandra wisely - I'd probably partition by user id.
I am using Kafka for Event Sourcing and I am interested in implementing sagas using Kafka.
Any best practices on how to do this? The Commander pattern mentioned here seems close to the architecture I am trying to build but sagas are not mentioned anywhere in the presentation.
This talk from this year's DDD eXchange is the best resource I came across wrt Process Manager/Saga pattern in event-driven/CQRS systems:
https://skillsmatter.com/skillscasts/9853-long-running-processes-in-ddd
(requires registering for a free account to view)
The demo shown there lives on github: https://github.com/flowing/flowing-retail
I've given it a spin and I quite like it. I do recommend watching the video first to set the stage.
Although the approach shown is message-bus agnostic, the demo uses Kafka for the Process Manager to send commands to and listen to events from other bounded contexts. It does not use Kafka Streams but I don't see why it couldn't be plugged into a Kafka Streams topology and become part of the broader architecture like the one depicted in the Commander presentation you referenced.
I hope to investigate this further for our own needs, so please feel free to start a thread on the Kafka users mailing list, that's a good place to collaborate on such patterns.
Hope that helps :-)
I would like to add something here about sagas and Kafka.
In general
In general Kafka is a tad different than a normal queue. It's especially good in scaling. And this actually can cause some complications.
One of the means to accomplish scaling, Kafka uses partitioning of the data stream. Data is placed in partitions, which can be consumed at its own rate, independent of the other partitions of the same topic. Here is some info on it: how-choose-number-topics-partitions-kafka-cluster. I'll come back on why this is important.
The most common ways to ensure the order within Kafka are:
Use 1 partition for the topic
Use a partition message key to "assign" the message to a topic
In both scenarios your chronologically dependent messages need to stream through the same topic.
Also, as #pranjal thakur points out, make sure the delivery method is set to "exactly once", which has a performance impact but ensures you will not receive the messages multiple times.
The caveat
Now, here's the caveat: When changing the amount of partitions the message distribution over the partitions (when using a key) will be changed as well.
In normal conditions this can be handled easily. But if you have a high traffic situation, the migration toward a different number of partitions can result in a moment in time in which a saga-"flow" is handled over multiple partitions and the order is not guaranteed at that point.
It's up to you whether this will be an issue in your scenario.
Here are some questions you can ask to determine if this applies to your system:
What will happen if you somehow need to migrate/copy data to a new system, using Kafka?(high traffic scenario)
Can you send your data to 1 topic?
What will happen after a temporary outage of your saga service? (low availability scenario/high traffic scenario)
What will happen when you need to replay a bunch of messages?(high traffic scenario)
What will happen if we need to increase the partitions?(high traffic scenario/outage & recovery scenario)
The alternative
If you're thinking of setting up a saga, based on steps, like a state machine, I would challenge you to rethink your design a bit.
I'll give an example:
Lets consider a booking-a-hotel-room process:
Simplified, it might consist of the following steps:
Handle room reserved (incoming event)
Handle room payed (incoming event)
Send acknowledgement of the booking (after payed and some processing)
Now, if your saga is not able to handle the payment if the reservation hasn't come in yet, then you are relying on the order of events.
In this case you should ask yourself: when will this break?
If you conclude you want to avoid the chronological dependency; consider a system without a saga, or a saga which does not depend on the order of events - i.e.: accepting all messages, even when it's not their turn yet in the process.
Some examples:
aggregators
Modeled as business process: parallel gateways (parallel process flows)
Do note in such a setup it is even more crucial that every action has got an implemented compensating action (rollback action).
I know this is often hard to accomplish; but, if you start small, you might start to like it :-)
We're trying to build a platform using microservices that communicate async over kafka.
It would seem natural, the way i understood it, to have 1 topic per aggregate type in each microservice. So a microservice implementing user registration would publish user related events into the topic "users".
Other microservices would listen to events created from the "users" microservices and implement their own logic and fill their DBs accordingly. The problem is that other microservices might not be interested in all the events generated by the user microservice but rather a subset of these events, like UserCreated only (without UsernameChanged... for example).
Using RabbitMq is easy since event handlers are invoked based on message type.
Did you ever implement message based routing/filtering over kafka?
Should we consume all the messages, deserialize them and ignore unneeded ones by the consumer? (sounds like an overhead)
Should we forward these topics to storm and redirect these messages to consumer targeted topics? (sounds like an overkill and un-scalable)
Using partitions doesn't seem logical as a routing mechanism
Use a different topic for each of the standard object actions: Create, Read, Update, and Delete, with a naming convention like "UserCreated", "UserRead", etc. If you think about it, you will likely have a different schema for the objects in each. Created will require a valid object; Read will require some kind of filter; Update you might want to handle incremental updates (add 10 to a specific field, etc).
If the different actions have different schemas it makes deserialization difficult. If you're in a loosey-goosey language like JavaScript, ok -- no big deal. But a strictly typed language like Scala and having different schemas in this same topic is problematic.
It'll also solve you're problem -- you can listen for exactly the types of actions you want, no more, not less.