DEV Community

Isa Levine
Isa Levine

Posted on • Updated on

How To Build an Event Sourcing Pattern in Rails from Scratch

All code from this demo can be found in this GitHub repo:
https://github.com/isalevine/event-sourcing-user-app

To Recap: What is Event Sourcing?

Event Sourcing is a system design pattern that emphasizes recording changes to data via immutable events.

In other words: every time your data changes, you save an event to your database with the details.

Those events never change or go away. That way, you have a permanent, unchanging history of how your data reached its current state!

What this article covers

We will primarily be working off of Kickstarter's event sourcing example.

To create our Event pattern, we’ll take the following steps:

  • Get our Rails app up and running
    • User model and controller
    • PostgreSQL for our database
  • Set up our environment to test our Events
    • Postico to inspect our database
    • Insomnia for REST client
  • Add our Events pattern
    • What is an Event, and what Event data will we store in the database?
    • The BaseEvent that other Event classes will inherit from
    • Events::User::Created
    • Events::User::Destroyed

Getting our Rails app up and running

Let’s go ahead and create our new Rails app

We’ll set the database to PostgreSQL with --database=postgresql and skip tests with --skip-test, as we will be adding RSpec manually later.

rails new event-sourcing-user-app --database=postgresql --skip-test

Let’s add our User model

Our User model will have several fields:

  • name String,
  • email String,
  • password_digest String (for bcrypt)
  • deleted Boolean (remember, part of event sourcing is that we never delete data—instead, we will flag certain Users as being deleted, and scope our queries appropriately)
    • this field also needs to be null: false, and be set to default: false

We’ll start this with Rails one-liner:

rails g model User name email password_digest deleted:boolean

And inside the new migration, tweak the t.boolean :deleted to be null: false and default: false:

# db/migrate/20200502025357_create_users.rb

class CreateUsers < ActiveRecord::Migration[6.0]
  def change
    create_table :users do |t|
      t.string :name
      t.string :email
      t.string :password_digest
      t.boolean :deleted, null: false, default: false

      t.timestamps
    end
  end
end

Add a User controller and routes

Our User controller needs to have two actions, a create and destroy action, to handle the Events we want to make.

Let’s create our controller manually, since we don’t need any views to be generated. In app/controllers, create a users_controller and add def create and def destroy actions:

# app/controllers/users_controller.rb

class UsersController < ApplicationController
  def create
  end

  def destroy
  end
end

Since we are not implementing auth yet, we’ll also add a skip_before_action hook to make testing our code easier:

# app/controllers/users_controller.rb

class UsersController < ApplicationController
  skip_before_action :verify_authenticity_token, only: [:create, :destroy]

  def create
  end

  def destroy
  end
end

Next, let’s manually add a POST and DELETE route that will go to the create and destroy actions in our controller:

# config/routes.rb

Rails.application.routes.draw do
  post 'users/create', to: 'users#create'
  delete 'users/destroy', to: 'users#destroy'
end

Run rails routes in your console to see that the routes are set up correctly:

[13:29:44] (master) event-sourcing-user-app
// ♥ rails routes 

Prefix           Verb     URI Pattern                 Controller#Action
users_create     POST     /users/create(.:format)     users#create
users_destroy    DELETE   /users/destroy(.:format)    users#destroy

Run database migrations

Now, let’s create our databases and run our migrations in the usual two-step:

rails db:create
rails db:migrate

Setting up our environment to test our Events

Set up Postico to view our PostgreSQL database

If you’re not familiar with Postico, it’s a a database management tool and viewer for PostgreSQL with a great free trial.

Download and install from their website, and open it up. Go ahead and hit Connect to in the localhost using its default settings:

Postico's main page

From here, click the localhost button at the top to go to a list of available databases:

Postico landing page inside localhost

And now, we should be able to select our development database:

Postico page listing available databases

Select our users table:

Postico page inside development database, showing users table

And, hurray—there’s our User model, with its four fields:

Postico users table

Set up Insomnia to send HTTP requests

Likewise, if you’re not familiar with Insomnia, it’s a tool for sending HTTP requests to test RESTful APIs. We’ll be using Insomnia Core.

Download, install, and open it up:

Insomnia Core main page

Create a folder for our project, event-sourcing-user-app:

Insomnia showing new project folder

Let’s create our first request. We’ll make it a POST request, which we’ll user for a create User route:

Insomnia showing new request being set to POST

And lastly, we’ll set the target URL to localhost:3000/users/create for testing later:

Insomnia showing target URL for Create User request

Yay, now Insomnia’s ready to go! We’ll just need to fill out the body of our request with a hash once we have our Events created.

Testing the create action with byebug and Insomnia

You can test out the routes by adding a byebug to the controller action:

# app/controllers/users_controller.rb

def create
  byebug
end

Fire up rails s, and send a POST request to localhost:3000/users/create in Insomnia. In your console, you will see byebug session:

screenshot showing Insomnia request, and console inside a byebug session

Great, we can see our route working as expected!

Now, we’re ready to build our event pattern!

What is an Event?

In our event sourcing system, each Event will be a Rails model that stores information about changes to our data.

Our goal is to build two events:

  • Events::User::Created — this will record:
    • payload: a hash containing the name, email, and password params to create the User
    • user_id: the created User’s id, used in its belongs_to relationship
    • event_type: a String to show that this user_event is the ”Created” type
    • timestamps
  • Events::User::Destroyed — this will record:
    • payload: a hash containing the id for the User to be flagged as deleted
    • user_id: the target User’s id, used in its belongs_to relationship
    • event_type: a String to show that this user_event is the ”Destroyed” type
    • timestamps

When our Rails app creates or destroys a User, this will also trigger creating a new Event.

These events will be saved to our database, and will be immutable to serve as a permanent log of changes.

Since we might end up having a lot of User-related events, we’re also including the event_type field on our User events so we can store them all in one user_events table—and easily add more later!

The Events::BaseEvent

Our events will be built through inheritance. At the top of the chain, we will define Events::BaseEvent where a lot of the event functionality will live.

Since all of our events will be Rails models, go ahead and create a new /events directory inside app/models.

Now, we can create our BaseEvent:

# app/models/events/base_event.rb

class Events::BaseEvent < ActiveRecord::Base
end

abstract_class

Since the BaseEvent only exists for inheritance, we can make it an abstract_class so Rails knows not to try to load any records for it:

# app/models/events/base_event.rb

class Events::BaseEvent < ActiveRecord::Base
  self.abstract_class = true
end

apply(aggregate) and apply_and_persist

Each event will have to define its own apply method. This method will accept an aggregate—another model, in our case a User—and update its attributes.
(The term aggregate comes from the Kickstarter event sourcing system, and you can read more about it here. Basically, aggregates are models that receive changes via events.)

On BaseEvent, we’ll simply raise a NotImplementedError. This will enforce us having to define it explicitly on each event, thus overriding the error via inheritance.

The BaseEvent will also have a before_create hook that calls apply_and_persist. This will call apply, then save! the update to the database.
(It will also set the event’s aggregate_id, specifically for Created events where the id doesn’t exist until after save! is called.)

Let’s look at the code we’ll add:

# app/models/events/base_event.rb

before_create :apply_and_persist

def apply(aggregate)
  raise NotImplementedError
end

private def apply_and_persist
  # Lock the database row! (OK because we're in an ActiveRecord callback chain transaction)
  aggregate.lock! if aggregate.persisted?

  # Apply!
  self.aggregate = apply(aggregate)

  #Persist!
  aggregate.save!

  # Update aggregate_id with id from newly created User
  self.aggregate_id = aggregate.id if aggregate_id.nil?
end

after_initialize and event_type

No matter what kind of event we instantiate, there are a couple attributes we want to set right away:

  • event_type — every Event needs to be explicitly categorized for when it’s stored in the user_events table as a BaseEvent record
  • payload — since we always expect payload to be accessible as a hash (and stored in our PostgreSQL database as JSON), we’ll add a ||= operator to set it to {} if the event accepts no params

So, we’ll add an after_initialize hook to set those attributes:

# app/models/events/base_event.rb

after_initialize do
  self.event_type = event_type
  self.payload ||= {}
end

def event_type
  self.attributes["event_type"] || self.class.to_s.split("::").last
end

Above, we define event_type to quickly access its own type via attributes if loaded from our database—or upon first creation, deducing its type from the Event class’s name.

self.payload_attributes(*attributes)

In each Event class we create, we want the option to define possible payload_attributes we want to record.

On BaseEvent, self.payload_attributes will create the getters and setters for our payload fields:

# app/models/events/base_event.rb

def self.payload_attributes(*attributes)
  @payload_attributes ||= []

  attributes.map(&:to_s).each do |attribute|
    @payload_attributes << attribute unless @payload_attributes.include?(attribute)

    define_method attribute do
      self.payload ||= {}
      self.payload[attribute]
    end

    define_method "#{attribute}=" do |argument|
      self.payload ||= {}
      self.payload[attribute] = argument
    end
  end

  @payload_attributes
end

Ultimately, this will let us define attributes like this at the top of each new Event class: payload_attributes :name, :email, :password

find_or_build_aggregate

We want our events to be aware of their aggregates—in our case, the target User—and be able to either look it up, or create a new one.

We’ll add a before_validation hook (which gets called really early in the .create lifecycle) which will either look up or create the aggregate, based on whether a user_id is supplied in the event’s initializing arguments:

# app/models/events/base_event.rb

before_validation :find_or_build_aggregate

private def find_or_build_aggregate
  self.aggregate = find_aggregate if aggregate_id.present?
  self.aggregate = build_aggregate if self.aggregate.nil?
end

def find_aggregate
  klass = aggregate_name.to_s.classify.constantize
  klass.find(aggregate_id)
end

def build_aggregate
  public_send "build_#{aggregate_name}"
end

aggregate setters, getters, and get-its-namers

To round out our events’ functionality, we’ll want some setters and getters—as well as methods to easily return its type or class name:

  • aggregate=(model) and aggregate will set and get the User our event targets
  • aggregate_id=(id) and aggregate_id will map to the user_id field on our user_events table
  • self.aggregate_name gives the Event class awareness of its belongs_to relationship’s target class (#=> User)
  • delegate :aggregate_name, to: :class will return a Symbol of the aggregate’s class name (#=> :user)
  • def event_klass will convert our Event class’s ::BaseEvent namespace into its appropriate event type (#=> Events::User::Created)
# app/models/events/base_event.rb

def aggregate=(model)
  public_send "#{aggregate_name}=", model
end

def aggregate
  public_send aggregate_name
end

def aggregate_id=(id)
  public_send "#{aggregate_name}_id=", id
end

def aggregate_id
  public_send "#{aggregate_name}_id"
end

def self.aggregate_name
  inferred_aggregate = reflect_on_all_associations(:belongs_to).first
  raise "Events must belong to an aggregate" if inferred_aggregate.nil?
  inferred_aggregate.name
end

delegate :aggregate_name, to: :class

def event_klass
  klass = self.class.to_s.split("::")
  klass[-1] = event_type
  klass.join('::').constantize
end

Okay, let’s see the whole Events::BaseEvent!

# app/models/events/base_event.rb

# Kickstarter code reference:
# https://github.com/pcreux/event-sourcing-rails-todo-app-demo/blob/master/app/models/lib/base_event.rb

class Events::BaseEvent < ActiveRecord::Base
  before_validation :find_or_build_aggregate
  before_create :apply_and_persist

  self.abstract_class = true

  def apply(aggregate)
    raise NotImplementedError
  end

  after_initialize do
    self.event_type = event_type
    self.payload ||= {}
  end

  def self.payload_attributes(*attributes)
    @payload_attributes ||= []

    attributes.map(&:to_s).each do |attribute|
      @payload_attributes << attribute unless @payload_attributes.include?(attribute)

      define_method attribute do
        self.payload ||= {}
        self.payload[attribute]
      end

      define_method "#{attribute}=" do |argument|
        self.payload ||= {}
        self.payload[attribute] = argument
      end
    end

    @payload_attributes
  end

  private def find_or_build_aggregate
    self.aggregate = find_aggregate if aggregate_id.present?
    self.aggregate = build_aggregate if self.aggregate.nil?
  end

  def find_aggregate
    klass = aggregate_name.to_s.classify.constantize
    klass.find(aggregate_id)
  end

  def build_aggregate
    public_send "build_#{aggregate_name}"
  end

  private def apply_and_persist
    # Lock the database row! (OK because we're in an ActiveRecord callback chain transaction)
    aggregate.lock! if aggregate.persisted?

    # Apply!
    self.aggregate = apply(aggregate)

    #Persist!
    aggregate.save!
    self.aggregate_id = aggregate.id if aggregate_id.nil?
  end

  def aggregate=(model)
    public_send "#{aggregate_name}=", model
  end

  def aggregate
    public_send aggregate_name
  end

  def aggregate_id=(id)
    public_send "#{aggregate_name}_id=", id
  end

  def aggregate_id
    public_send "#{aggregate_name}_id"
  end

  def self.aggregate_name
    inferred_aggregate = reflect_on_all_associations(:belongs_to).first
    raise "Events must belong to an aggregate" if inferred_aggregate.nil?
    inferred_aggregate.name
  end

  delegate :aggregate_name, to: :class

  def event_type
    self.attributes["event_type"] || self.class.to_s.split("::").last
  end

  def event_klass
    klass = self.class.to_s.split("::")
    klass[-1] = event_type
    klass.join('::').constantize
  end

end

The user_events table, and the Events::User::BaseEvent

We previously mentioned that we will be storing multiple types of User-related events in a single user_events table.

To accomplish this and allow us to easily add more events later, we will create an Events::User::BaseEvent which will tell all events in the Events::User:: namespace to save to the user_events table. We will also define a belongs_to relationship with a User here.

user_events table

Let’s go ahead and create our user_events table in our database.

Kickstarter’s event sourcing example describes that each aggregate (User) has an event table (user_events). These event tables will have a similar schema—we will tweak them slightly to match our verbiage:

Each Aggregate (ex: subscriptions) has an Event table associated to it (ex: subscription_events).

All events related to an aggregate are stored in the same table. All events tables have a similar schema:
id, aggregate_id, type, data (json), metadata (json), created_at

A few things we’ll tweak for our code:

  • aggregate_id will be replaced by user_id
  • type will be replaced by event_type (just to be more explicit)
  • data will be replaced by payload, and will still be type JSON
  • metadata will not be included at this time, since our events are relatively simple
  • created_at will not be included, since we will simply rely on ActiveRecord’s default timestamps

We will create our user_events table with a Rails migration:

rails g migration CreateUserEvents

This will create our migration with a create_table block set up for us:

# db/migrate/20200502192018_create_user_events.rb

class CreateUserEvents < ActiveRecord::Migration[6.0]
  def change
    create_table :user_events do |t|
    end
  end
end

We want to add four fields:

  • a belongs_to relationship to a :user
  • an event_type String
  • a payload JSON
  • timestamps
# db/migrate/20200502192018_create_user_events.rb

class CreateUserEvents < ActiveRecord::Migration[6.0]
  def change
    create_table :user_events do |t|
      t.belongs_to :user, null: false, foreign_key: true
      t.string :event_type
      t.json :payload

      t.timestamps
    end
  end
end

Run the migration:

rails db:migrate

And open up Postico to check out the new user_events table:

Postico page showing the user_events table selected

Our table and fields are ready to go!

Postico page showing user_events table fields

Events::User::BaseEvent

Inside our app/models/events directory, create a new user directory.

Inside that directory, create a new file base_event.rb. This gives us the namespacing to create this class:

# app/models/events/user/base_event.rb

class Events::User::BaseEvent < Events::BaseEvent
  self.table_name = "user_events"
end

With self.table_name = “user_events”, any new Event class we create that inherits from Events::User::BaseEvent will automatically be saved and retrieved from the user_events table!

belongs_to :user and has_many :events

Since all our User-related events target a User, it makes sense to create a has_many / belongs_to relationship between Users and Events in the Events::User:: namespace.

Since we’re deep in a namespace that uses the name User, to tell Rails to look for the regular top-level User model, we need to add :: before our classnames. This tells our has_many and belongs_to relationships to look outside the current namespace.

Let’s update our Events::User::BaseEvent and User classes with the relationships:

# app/models/events/user/base_event.rb

class Events::User::BaseEvent < Events::BaseEvent
  self.table_name = "user_events"

  belongs_to :user, class_name: "::User"
end


# app/models/user.rb

class User < ApplicationRecord
  has_many :events, class_name: "Events::User::BaseEvent" 
end

Great! Now, when we load a User into a user variable, we can call user.events to load all related events from the user_events table.

We’re now ready to create some real, usable Events!

Creating a new User with Events::User::Created

With our BaseEvent pattern in place, we can now build our first event!

Events::User::Created will record the params used to create a User, as well as the new User’s id, and the event’s timestamp.

Build the Events::User::Created class

In app/models/events/user, make a new created.rb file. Our class will inherit from Events::User::BaseEvent in the same directory:

# app/models/events/user/created.rb

class Events::User::Created < Events::User::BaseEvent
end

As we defined in the top-level Events::BaseEvent, we must define an apply method that will take a User instance as its aggregate argument:

# app/models/events/user/created.rb

class Events::User::Created < Events::User::BaseEvent
  def apply(user)
  end
end

Since we know creating a User requires params with a name, email, and password, we can also add them as a list of symbols to payload_attributes to create our getters and setters:

# app/models/events/user/created.rb

class Events::User::Created < Events::User::BaseEvent
  payload_attributes :name, :email, :password

  def apply(user)
  end
end

Add logic to the apply method

The logic in the event’s apply method is where the event’s power lies. It:

  • takes in a User instance
  • applies the changes to the User instance, supplied by payload_attributes
  • returns the mutated User instance => this is where the top-level BaseEvent receives back the User instance, and calls save! to persist the changes in the database!

Thanks to the list of attributes passed to payload_attributes, we can simply call the attributes inside our apply method to update the User instance:

# app/models/events/user/created.rb

payload_attributes :name, :email, :password

def apply(user)
  user.name = name
  user.email = email
  user.password_digest = password

  user
end

Perfect! Now, all we need to do is tell Insomnia to pass params that contain name, email, and password Strings, and our event will map them to the User model’s name, email, and password_digest fields.
(Remember: password_digest is related to bcrypt functionality, which we will explore in another article.)

Update our controller to create an Event and use strong params

Back in our users_controller, we need to update two things:

  • the create action needs to call Events::User::Created.create(payload: user_params)
  • add strong params to protect the user_params we will pass to .create(payload: user_params)

For the strong params, we will require the user_params to have name, email, and password nested inside a user key:

# app/controllers/users_controller.rb

private def user_params
  params.require(:user).permit(:name, :email, :password)
end

Now, we can safely pass user_params to Events::User::Created.create(payload: user_params) in the create action:

# app/controllers/users_controller.rb

def create
  Events::User::Created.create(payload: user_params)
end

private def user_params
  params.require(:user).permit(:name, :email, :password)
end

Let’s test our event with Insomnia and Postico!

If we send the correct params via a POST request to localhost:3000/users/create, we expect several behaviors:

  • a new record in the user_events table, with:
    • event_type “Created”
    • payload with the user_params
      • note that the password will be stored as plaintext => this is UNSAFE BEHAVIOR, and is because we have not implemented bcrypt encryption yet!
    • user_id with the newly-created User’s id
  • a new record in the user table, with:
    • correct name
    • correct email
    • password_digest that is the plaintext password => this is UNSAFE BEHAVIOR, and is because we have not implemented bcrypt encryption yet!

Let’s test it out!

Fire up rails s, and open up Insomnia.

In our Create User request, set the Body to JSON:

Insomnia page showing Body type being set to JSON

Then, create a JSON hash with a ”user” key, which points to a hash containing a ”name”, ”email”, and ”password”:

Insomnia page showing JSON body with user params

Now hit Send, and let’s check out our database tables!

First, let’s see if we have an event in our user_events table:

Postico table with first Created event record, overlaid on Insomnia request body

So far, so good!
(Remember: storing passwords as plaintext is UNSAFE BEHAVIOR, and is because we have not implemented bcrypt encryption yet!)

Now, let’s check out the users table:

Postico table with first User record, overlaid on Insomnia request body

Terrific! We now have our new User, ongo_gablogian, and a record of the Event and params that created him!

gif of Danny DeVito as Ongo Gablogian, a parody of Andy Warhol, on Always Sunny

There you have it! Our event sourcing system is now capturing changes to our data!

As long as we never alter the data in the user_events table, we have a reliable log of how our data got to its current state!

screenshot of a banner stating MISSION ACCOMPLISHED on Arrested Development

Destroying a User with Events::User::Destroyed

Now that we have our pattern in place, it’s very straightforward to create a new Event and record it to our user_events table!

Since we never want to destroy our data, we implemented a boolean deleted field on the User model. When a new User is created, it defaults to false.

Let’s create a new event, Events::User::Destroyed, that will set the deleted field to true!

Create an app/models/events/user/destroyed.rb file

In the same directory as our Events::User::Created class, create an equivalent Events::User::Destroyed class:

# app/models/events/user/destroyed.rb

class Events::User::Destroyed < Events::User::BaseEvent
  def apply(user)
    user
  end
end

Above, we start with an apply method that simply returns the passed-in User instance.

To delete a User, we’ll simply require an id. Let’s add the payload_attributes for it:

# app/models/events/user/destroyed.rb

class Events::User::Destroyed < Events::User::BaseEvent
  payload_attributes :id
end

And we’ll make our apply method update the passed-in User’s deleted field to true:

# app/models/events/user/destroyed.rb

class Events::User::Destroyed < Events::User::BaseEvent
  payload_attributes :id

  def apply(user)
    user.deleted = true

    user
  end
end

That’s it—our new Event is done!

Update the destroy action in users_controller

In our users_controller, we’ll make our destroy action simply create our new Events::User::Destroyed event.

Thanks to the find_or_build_aggregate and aggregate_id methods defined in our top-level BaseEvent, this ”Destroyed” event will look up a User automatically if a user_id argument is supplied.

First, let’s add id to the list of strong params in user_params:

# app/controllers/users_controller.rb

private def user_params
  params.require(:user).permit(:name, :email, :password, :id)
end

Now, our controller’s destroy action can accept a user_params that has the necessary id. We’ll also use user_params[:id] so the event can look up our target User’s record:

# app/controllers/users_controller.rb

def destroy
  Events::User::Destroyed.create(user_id: user_params[:id], payload: user_params)
end

We’re ready to go ahead and test with Insomnia!

Test a DELETE request in Insomnia

Let’s fire up rails s.

Over in Insomnia, create a new request called Destroy User and make it a DELETE:

Insomnia page showing new Destroy User being set to type DELETE

Set its target URL to localhost:3000/users/destroy:

Insomnia page showing DELETE request's target URL

Set the Body type to JSON, and add a hash with a ”user” key pointing to a hash containing the ”id”:

Insomnia page showing DELETE request's JSON body with a user id

Hit Send, and check the database to see if the Event was created:

Postico user_events table showing new Destroyed event record, overlaid on Insomnia request

And finally, let’s check the database to see if our User has deleted set to true:

Postico users table showing only User record with deleted field set to true

Perfect! We get to keep our User record, but also have it be deleted—we’re having our cake, and eating it too!

screenshot of cake from video game Portal
And that's no lie!

That’s all it takes to add a new event to our event sourcing system!

Conclusion

Wow, we covered a lot of ground! Let’s recap the steps we took to implement our event sourcing system:

  • Create a new Rails app, with a User model and controller, and PostgreSQL for the database
  • Create an Events::BaseEvent class in app/models/events to handle Event logic:
    • Looking up or creating aggregates (Users)
    • Creating getters and setters for payload_attributes
    • Inferring its own event_type
    • Hooks for automatically applying changes and saving to the database
  • Create a user_events table migration
  • Create an Events::User::BaseEvent to save all Events in its Events::User:: namespace to the user_events table
  • Create an Events::User::Created event that will apply user_params to a new User instance
  • Create an Events::User::Destroyed event that will look up at User by id and set its deleted field to true

This minimal system allows us to do the following:

  • Have a record of events that create and destroy Users
  • Keep all User data permanently, and still have the ability to scope the deleted ones as needed
  • A pattern that allows us to easily add new Events that will be saved to the same user_events table

All code from this demo can be found in this GitHub repo:
https://github.com/isalevine/event-sourcing-user-app

Next Up

We have a lot more we can do to improve our event sourcing system, especially around security and data validations! In the next article, we will cover:

  • Storing sensitive information safely in Event payloads, such as passwords
  • Wrapping creating Events in Commands, per Kickstarter’s example
  • Adding validations to Commands

References

Special thanks to Philippe Creux and Kickstarter for sharing their Event Sourcing example.

Thanks to Martin Fowler for his important writings on Event Sourcing.

Thanks to Arkency for their great work with the RailsEventStore library.

And finally, thanks to fellow Dev.to user Alfredo Motta for sharing about this years ago (and keeping it up for me to catch up on!).

Top comments (4)

Collapse
 
matiasgarcia profile image
Matías Hernán García

Great article!

Dumb question. Probably this is left out due that the focus is about showing how an evented system can be built.

  1. What about validations at the moment of running the create event?
  2. I mean, what if a user submits, twice, to create a given user? How they will get feedback that that went wrong?
Collapse
 
thatjsdev profile image
Nishant Mendiratta

Hi Isa, thanks for sharing this insightful article. I'm still a noob in rails but this was really helpful. cheers.

Note: There is a typo, app/models/events/user/destroy.rb should be destroyed.rb.

Collapse
 
isalevine profile image
Isa Levine

Thank you Nishant, and great catch! Code samples and the Github repo have been updated. :)

Collapse
 
chuylerma profile image
chuylerma

I followed up the whole series (2 at this moment) I really enjoyed, and I'm sure that this is going to help me a lot. Thank you so much for sharing!