eGo

eGo is a minimal library that help build event-sourcing and CQRS application through a simple interface, and it allows developers to describe their commands, events and states are defined using google protocol buffers. Under the hood, ego leverages Go-Akt to scale out and guarantee performant, reliable persistence.

Features

Domain Entity/Aggregate Root

The aggregate root is crucial for maintaining data consistency, especially in distributed systems. It defines how to handle the various commands (requests to perform actions) that are always directed at the aggregate root. In eGo commands sent the aggregate root are processed in order. When a command is processed, it may result in the generation of events, which are then stored in an event store. Every event persisted has a revision number and timestamp that can help track it. The aggregate root in eGo is responsible for defining how to handle events that are the result of command handlers. The end result of events handling is to build the new state of the aggregate root. When running in cluster mode, aggregate root are sharded.

• Commands handler: The command handlers define how to handle each incoming command, which validations must be applied, and finally, which events will be persisted if any. When there is no event to be persisted a nil can be returned as a no-op. Command handlers are the meat of the event sourced actor. They encode the business rules of your event sourced actor and act as a guardian of the Aggregate consistency. The command handler must first validate that the incoming command can be applied to the current model state. Any decision should be solely based on the data passed in the commands and the state of the Behavior. In case of successful validation, one or more events expressing the mutations are persisted. Once the events are persisted, they are applied to the state producing a new valid state.
• Events handler: The event handlers are used to mutate the state of the Aggregate by applying the events to it. Event handlers must be pure functions as they will be used when instantiating the Aggregate and replaying the event store.

To define an Aggregate Root, one needs to:

1. the state of the aggregate root using google protocol buffers message
2. the various commands that will be handled by the aggregate root
3. the various events that are result of the command handlers and that will be handled by the aggregate root to return the new state of the aggregate root
4. implements the EntityBehavior[T State] interface where T is the generated golang struct of the prior defined aggregate root state.

Events Stream

Every event handled by Aggregate Root are pushed to an events stream. That enables real-time processing of events without having to interact with the events store

Projection

One can add a projection to the eGo engine to help build a read model. Projections in eGo rely on an offset store to track how far they have consumed events persisted by the write model. The offset used in eGo is a timestamp-based offset.

Events Store

One can implement a custom events store. See EventsStore. eGo comes packaged with two events store:

• Postgres: Schema can be found here
• Memory (for testing purpose only)

Offsets Store

One can implement a custom offsets store. See OffsetStore. eGo comes packaged with two offset store:

• Postgres: Schema can be found here
• Memory (for testing purpose only)

Cluster

The cluster mode heavily relies on Go-Akt clustering.

Examples

Check the examples

Installation

go get github.com/tochemey/ego

Sample

package main

import (
	"context"
	"errors"
	"log"
	"os"
	"os/signal"
	"syscall"

	"github.com/google/uuid"
	"github.com/tochemey/ego"
	"github.com/tochemey/ego/eventstore/memory"
	samplepb "github.com/tochemey/ego/example/pbs/sample/pb/v2"
	"google.golang.org/protobuf/proto"
)

func main() {
	// create the go context
	ctx := context.Background()
	// create the event store
	eventStore := memory.NewEventsStore()
	// create the ego engine
	e := ego.NewEngine("Sample", eventStore)
	// start ego engine
	_ = e.Start(ctx)
	// create a persistence id
	entityID := uuid.NewString()
	// create an entity behavior with a given id
	behavior := NewAccountBehavior(entityID)
	// create an entity
	entity, _ := ego.NewEntity[*samplepb.Account](ctx, behavior, e)

	// send some commands to the pid
	var command proto.Message
	// create an account
	command = &samplepb.CreateAccount{
		AccountId:      entityID,
		AccountBalance: 500.00,
	}
	// send the command to the entity. Please don't ignore the error in production grid code
	account, _, _ := entity.SendCommand(ctx, command)

	log.Printf("current balance: %v", account.GetAccountBalance())

	// send another command to credit the balance
	command = &samplepb.CreditAccount{
		AccountId: entityID,
		Balance:   250,
	}
	account, _, _ = entity.SendCommand(ctx, command)
	log.Printf("current balance: %v", account.GetAccountBalance())

	// capture ctrl+c
	interruptSignal := make(chan os.Signal, 1)
	signal.Notify(interruptSignal, os.Interrupt, syscall.SIGINT, syscall.SIGTERM)
	<-interruptSignal

	// stop the ego engine
	_ = e.Stop(ctx)
	os.Exit(0)
}

// AccountBehavior implements EntityBehavior
type AccountBehavior struct {
	id string
}

// make sure that AccountBehavior is a true persistence behavior
var _ ego.EntityBehavior[*samplepb.Account] = &AccountBehavior{}

// NewAccountBehavior creates an instance of AccountBehavior
func NewAccountBehavior(id string) *AccountBehavior {
	return &AccountBehavior{id: id}
}

// ID returns the id
func (a *AccountBehavior) ID() string {
	return a.id
}

// InitialState returns the initial state
func (a *AccountBehavior) InitialState() *samplepb.Account {
	return new(samplepb.Account)
}

// HandleCommand handles every command that is sent to the persistent behavior
func (a *AccountBehavior) HandleCommand(_ context.Context, command ego.Command, _ *samplepb.Account) (events []ego.Event, err error) {
	switch cmd := command.(type) {
	case *samplepb.CreateAccount:
		// TODO in production grid app validate the command using the prior state
		return []ego.Event{
			&samplepb.AccountCreated{
				AccountId:      cmd.GetAccountId(),
				AccountBalance: cmd.GetAccountBalance(),
			},
		}, nil

	case *samplepb.CreditAccount:
		// TODO in production grid app validate the command using the prior state
		return []ego.Event{
			&samplepb.AccountCredited{
				AccountId:      cmd.GetAccountId(),
				AccountBalance: cmd.GetBalance(),
			},
		}, nil

	default:
		return nil, errors.New("unhandled command")
	}
}

// HandleEvent handles every event emitted
func (a *AccountBehavior) HandleEvent(_ context.Context, event ego.Event, priorState *samplepb.Account) (state *samplepb.Account, err error) {
	switch evt := event.(type) {
	case *samplepb.AccountCreated:
		return &samplepb.Account{
			AccountId:      evt.GetAccountId(),
			AccountBalance: evt.GetAccountBalance(),
		}, nil

	case *samplepb.AccountCredited:
		bal := priorState.GetAccountBalance() + evt.GetAccountBalance()
		return &samplepb.Account{
			AccountId:      evt.GetAccountId(),
			AccountBalance: bal,
		}, nil

	default:
		return nil, errors.New("unhandled event")
	}
}

Contribution

Contributions are welcome! The project adheres to Semantic Versioning and Conventional Commits. This repo uses Earthly.

There are two ways you can become a contributor:

1. Request to become a collaborator, and then you can just open pull requests against the repository without forking it.
2. Follow these steps

• Fork the repository
• Create a feature branch
• Set your docker credentials on your fork using the following secret names: DOCKER_USER and DOCKER_PASS
• Submit a pull request

Test & Linter

Prior to submitting a pull request, please run:

earthly +test