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EventFlow is a basic CQRS+ES framework designed to be easy to use.
Have a look at our getting started guide, the do’s and don’ts and the FAQ.
- CQRS+ES framework
- Async/await first: Every part of EventFlow is written using async/await.
- Highly configurable and extendable
- Easy to use
- No use of threads or background workers making it "web friendly"
- Cancellation: All methods that does IO work or might delay execution (due to
retries), takes a
CancellationToken
argument to allow you to cancel the operation
- Complete: Shows a complete example on how to use EventFlow with in-memory event store and read models in a relatively few lines of code
- Shipping: To get a more complete example of how EventFlow could be used, have a look at the shipping example found here in the code base. The example is based on the shipping example from the book "Domain-Driven Design - Tackling Complexity in the Heart of Software" by Eric Evans. Its in-progress, but should provide inspiration on how to use EventFlow on a larger scale. If you have ideas and/or comments, create a pull request or an issue
- Racetimes: Shows some features of EventFlow that are not covered in the complete example. It features entities, a read model for an entity, delete on read models, specifications and snapshots.
Here is a list of the EventFlow concepts. Use the links to navigate to the documentation.
- Aggregates: Domains object that guarantees the consistency of changes being made within each aggregate
- Command bus and commands: Entry point for all command/operation execution.
- Event store:
Storage of the event stream for aggregates. Currently there is support for
these storage types.
- In-memory - only for test
- Files - only for test
- Microsoft SQL Server
- Entity Framework Core
- SQLite
- PostgreSQL
- EventStore - home page
- Subscribers: Listeners that act on specific domain events. Useful if an specific action needs to be triggered after a domain event has been committed.
- Read models:
Denormalized representation of aggregate events optimized for reading fast.
Currently there is support for these read model storage types.
- Elasticsearch
- In-memory - only for test
- Microsoft SQL Server
- Entity Framework Core
- SQLite
- PostgreSQL
- Snapshots:
Instead of reading the entire event stream every single time, a snapshot can
be created every so often that contains the aggregate state. EventFlow
supports upgrading existing snapshots, which is useful for long-lived
aggregates. Snapshots in EventFlow are opt-in and EventFlow has support for
- In-memory - only for test
- Microsoft SQL Server
- Entity Framework Core
- SQLite
- PostgreSQL
- Sagas: Also known as process managers, coordinates and routes messages between bounded contexts and aggregates
- Queries: Value objects that represent a query without specifying how its executed, that is let to a query handler
- Jobs: Perform scheduled tasks at a later time, e.g. publish a command. EventFlow provides support for these job schedulers
- Event upgrade: As events committed to the event store is never changed, EventFlow uses the concept of event upgraders to deprecate events and replace them with new during aggregate load.
- Event publishing: Sometimes you want other applications or services to consume and act on domains. For this EventFlow supports event publishing.
- RabbitMQ
- Metadata: Additional information for each aggregate event, e.g. the IP of the user behind the event being emitted. EventFlow ships with several providers ready to use used.
- Value objects: Data containing classes used to validate and hold domain data, e.g. a username or e-mail.
- Customize: Almost every single part of EventFlow can be swapped with a custom implementation through the embedded IoC container.
Here's a complete example on how to use the default in-memory event store along with an in-memory read model.
The example consists of the following classes, each shown below
ExampleAggregate
: The aggregate rootExampleId
: Value object representing the identity of the aggregate rootExampleEvent
: Event emitted by the aggregate rootExampleCommand
: Value object defining a command that can be published to the aggregate rootExampleCommandHandler
: Command handler which EventFlow resolves using its IoC container and defines how the command specific is applied to the aggregate rootExampleReadModel
: In-memory read model providing easy access to the current state
Note: This example is part of the EventFlow test suite, so checkout the code and give it a go.
[Test]
public async Task Example()
{
// We wire up EventFlow with all of our classes. Instead of adding events,
// commands, etc. explicitly, we could have used the the simpler
// AddDefaults(Assembly) instead.
using (var resolver = EventFlowOptions.New
.AddEvents(typeof(ExampleEvent))
.AddCommands(typeof(ExampleCommand))
.AddCommandHandlers(typeof(ExampleCommandHandler))
.UseInMemoryReadStoreFor<ExampleReadModel>()
.CreateResolver())
{
// Create a new identity for our aggregate root
var exampleId = ExampleId.New;
// Resolve the command bus and use it to publish a command
var commandBus = resolver.Resolve<ICommandBus>();
await commandBus.PublishAsync(
new ExampleCommand(exampleId, 42), CancellationToken.None)
.ConfigureAwait(false);
// Resolve the query handler and use the built-in query for fetching
// read models by identity to get our read model representing the
// state of our aggregate root
var queryProcessor = resolver.Resolve<IQueryProcessor>();
var exampleReadModel = await queryProcessor.ProcessAsync(
new ReadModelByIdQuery<ExampleReadModel>(exampleId), CancellationToken.None)
.ConfigureAwait(false);
// Verify that the read model has the expected magic number
exampleReadModel.MagicNumber.Should().Be(42);
}
}
// The aggregate root
public class ExampleAggregate : AggregateRoot<ExampleAggregate, ExampleId>,
IEmit<ExampleEvent>
{
private int? _magicNumber;
public ExampleAggregate(ExampleId id) : base(id) { }
// Method invoked by our command
public void SetMagicNumer(int magicNumber)
{
if (_magicNumber.HasValue)
throw DomainError.With("Magic number already set");
Emit(new ExampleEvent(magicNumber));
}
// We apply the event as part of the event sourcing system. EventFlow
// provides several different methods for doing this, e.g. state objects,
// the Apply method is merely the simplest
public void Apply(ExampleEvent aggregateEvent)
{
_magicNumber = aggregateEvent.MagicNumber;
}
}
// Represents the aggregate identity (ID)
public class ExampleId : Identity<ExampleId>
{
public ExampleId(string value) : base(value) { }
}
// A basic event containing some information
public class ExampleEvent : AggregateEvent<ExampleAggregate, ExampleId>
{
public ExampleEvent(int magicNumber)
{
MagicNumber = magicNumber;
}
public int MagicNumber { get; }
}
// Command for update magic number
public class ExampleCommand : Command<ExampleAggregate, ExampleId>
{
public ExampleCommand(
ExampleId aggregateId,
int magicNumber)
: base(aggregateId)
{
MagicNumber = magicNumber;
}
public int MagicNumber { get; }
}
// Command handler for our command
public class ExampleCommandHandler
: CommandHandler<ExampleAggregate, ExampleId, ExampleCommand>
{
public override Task ExecuteAsync(
ExampleAggregate aggregate,
ExampleCommand command,
CancellationToken cancellationToken)
{
aggregate.SetMagicNumer(command.MagicNumber);
return Task.FromResult(0);
}
}
// Read model for our aggregate
public class ExampleReadModel : IReadModel,
IAmReadModelFor<ExampleAggregate, ExampleId, ExampleEvent>
{
public int MagicNumber { get; private set; }
public void Apply(
IReadModelContext context,
IDomainEvent<ExampleAggregate, ExampleId, ExampleEvent> domainEvent)
{
MagicNumber = domainEvent.AggregateEvent.MagicNumber;
}
}
EventFlow is still under development, especially the parts regarding how read models are re-populated.
EventFlow is currently used in production environments and performs very well, but it need to mature before key APIs are stable.
EventFlow is greatly opinionated, but its possible to create new implementations for almost every part of EventFlow by registering a different implementation of an interface.
Many of the technical design decisions in EventFlow is based on articles. This section lists some of them. If you have a link with a relevant article, please share it by creating an issue with the link.
- Domain-Driven Design
- General CQRS+ES
- CQRS Journey by Microsoft published by Microsoft
- An In-Depth Look At CQRS by Mike Mogosanu
- CQRS, Task Based UIs, Event Sourcing agh! by Greg Young
- Busting some CQRS myths by Jimmy Bogard
- CQRS applied by Gabriel Schenker
- DDD Decoded - Entities and Value Objects Explained
- Eventual consistency
- Why not to implement "unit of work" in DDD
- Unit Of Work is the new Singleton by Mike Mogosanu
- The Unit of Work and Transactions In Domain Driven Design by Mike Mogosanu
EventFlow has several tests that verify that its able to use the systems it integrates with correctly.
- Elasticsearch: Elasticsearch run as Docker Windows Container. if use in local, requires its environment and
docker-compose
tool, and executePS> up_integration-test-env.ps1
- EventStore: EventStore is same as the above
- RabbitMQ: RabbitMQ is same as the above
- MSSQL: Microsoft SQL Server is required to be running
- RabbitMQ: Set an environment variable named
RABBITMQ_URL
with the URL for the RabbitMQ instance you would like to use. - EntityFramework: Microsoft SQL Server and PostgreSQL is required to be running
- PostgreSQL: PostgreSQL is required to be running
There's a Vagrant box with both Elasticsearch and RabbitMQ you can use here.
Alternatively you can skip the NUnit tests marked with the integration
category.
- Contributors
- JetBrains: OSS licenses
- olholm: Current logo
- iconmonstr: First logo
- JC008: License for Navicat Essentials for SQLite
The MIT License (MIT)
Copyright (c) 2015-2018 Rasmus Mikkelsen
Copyright (c) 2015-2018 eBay Software Foundation
https://github.com/eventflow/EventFlow
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of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
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