This is the 4th (and final) part of a 4 part series covering the rom-rb and dry-rb suites of gems.
- Part 1: Application + Database setup
- Part 2: Validations + Operations
- Part 3: Testing
In this last part, we’re going to make it so that our application can receive and respond to HTTP requests.
So far, we’ve been seeing how to use gems either from the dry-rb suite of gems, or the rom-rb suite of gems. In this part though, we’re going to be using a gem from a different suite, a suite called Hanami.
Hanami is first and foremost a web framework. It has routes, controllers, actions, views and models. Just like your other favourite web framework – Rails. But the big difference between Hanami and Rails is that with Hanami we can pick and choose the parts of the framework that we want to use.
Hanami is a modular web framework, and if all we want to use is the router, controllers and actions, then we can. In this part of this showcase, we’re going to look at how we can use two gems from Hanami called hanami-router and hanami-controller. These gems will provide us with the features our application needs to receive and respond to HTTP requests.
Our application will take a request to POST /users with a JSON body shaped like this:
{
"first_name": "Ryan",
"last_name": "Bigg",
"age": 32,
}
And the response will indicate if the request was successful or not. If it was successful, we will see a JSON response:
{
"id": 1,
"first_name": "Ryan",
"last_name": "Bigg",
"age": 32
}
Let’s go!
Installing the Hanami gems
Let’s add these gems to our Gemfile:
gem "hanami-controller", "~> 1.3"
gem "hanami-router", "~> 1.3"
To install these gems, we can run bundle install.
In order to make sure that whatever we build with this application is performing correctly, we’ll add a third gem called rack-test:
gem "rack-test"
We’re going to be using this gem to test our application in conjunction with RSpec. You might be thinking: why rack-test? That’s because the part of our application that will recieve and respond to HTTP requests will be a Rack application! Just like every other Ruby web framework out there.
Setting up the test environment
Before we can write our any code, we need to write tests for it. It’ll make sure that our application is working correctly! But before we can write tests, there’s a bit of setup we need to do first. We’re going to create a new file called spec/web_helper.rb. This file will setup how our tests can speak to our Rack application:
require "spec_helper"
require "rack/test"
module RequestHelpers
def app
Bix::Web.app
end
def post_json(path, data)
post path, data.to_json, "CONTENT_TYPE" => "application/json"
end
def parsed_body
JSON.parse(last_response.body)
end
end
RSpec.configure do |config|
config.define_derived_metadata(file_path: %r{/spec/requests/}) do |metadata|
metadata[:request] = true
end
config.include Rack::Test::Methods, request: true
config.include RequestHelpers, request: true
end
We set the web metadata flag on any tests that will go in spec/requests. This allows us to specify that the Rack::Test::Methods and RequestHelpers modules are included only into tests under that particular directory.
The Rack::Test::Methods module will include methods that we can use to make requests to our app, like get, post and so on.
The RequestHelpers module defines one method so far, called app. This app method is what the rack-test gem uses to know what application to talk to when we use those get / post / etc. methods.
We’ve defined the app value here to be a small Rack application that compiles a few parts. The first is Hanami::Middleware::BodyParser. This is a piece of middleware, that will convert our JSON input into parameters that our controller can access. The second part is Bix::Web::Router, which will be the main Ruby entrypoint for our application. That doesn’t exist right now, but we’ll create it in a moment. We’ll see both of these parts again a little later on again.
The post_json method in RequestHelpers will allow us to make a POST request to our application and to send through JSON data with that request. Remember: the web part of application here is going to take JSON as input during a request, and it will also return JSON in a response. The parsed_body method will give us a Ruby hash of the response’s body, and we can use this later on to assert the returned data is what we expect.
Before we create our router and all of the other parts, let’s write a couple of simple tests to make sure it will behave as we wish.
Writing our first test
Currently, our application has a single transaction for creating users. We’re going to use this transaction very soon, using it when a request to POST /users is made. We’re going to add two tets now. These two tests will ensure that the application behaves correctly for valid and invalid input to POST /users. Let’s add these new tests to spec/requests/users_spec.rb:
require "web_helper"
RSpec.describe "/users" do
context "POST /" do
context "with valid input" do
let(:input) do
{
first_name: "Ryan",
last_name: "Bigg",
age: 32,
}
end
it "succeeds" do
post_json "/users", input
expect(last_response.status).to eq(200)
user = parsed_body
expect(user["id"]).not_to be_nil
expect(user["first_name"]).to eq("Ryan")
expect(user["last_name"]).to eq("Bigg")
expect(user["age"]).to eq(32)
end
end
context "with invalid input" do
let(:input) do
{
last_name: "Bigg",
age: 32,
}
end
it "returns an error" do
post_json "/users", input
expect(last_response.status).to eq(422)
user = parsed_body
expect(user["errors"]["first_name"]).to include("is missing")
end
end
end
end
These tests should look pretty familiar! They are essentially the same tests for our transaction, just with rack-test methods being the primary difference.
When we attempt to run these tests, we’ll see that we’re missing a part of our application:
1) /users POST / with valid input succeeds
Failure/Error: Bix::Web.app
NoMethodError:
undefined method `app' for Bix::Web:Module
Oh right! We need to setup this Web thing!
Building the Web component
To setup this web part of our application, we’re going to add a new file to system/boot, called web.rb. In this file, we’ll need to require all the gems that we’ll be using for the web part of our application:
Bix::Application.boot(:web) do |app|
init do
require "hanami-router"
require "hanami-controller"
end
end
This two lines will require the hanami gems that we’re going to be using here. Where we’ll use these gems is in a couple of files.
The first is a file called lib/bix/web/application.rb. This is where we’ll define the different Rack pieces for our application:
require "hanami/middleware/body_parser"
module Bix
module Web
def self.app
Rack::Builder.new do
use Hanami::Middleware::BodyParser, :json
run Bix::Web::Router
end
end
end
end
This file is defines the Bix::Web.app method that our test is looking for! This method returns a Rack::Builder object, which is to say it returns a Rack application.
This Rack application uses a single piece of middleware: Hanami::Middleware::BodyParser. This middleware is used to take in any JSON request body, and to transform it into parameters for our actions.
The run line at the of the builder’s block directs Rack to the application that will be serving our requests. Let’s build this part now in lib/bix/web/router.rb:
module Bix
module Web
Router = Hanami::Router.new do
post "/users", to: Controllers::Users::Create
end
end
end
This file allows us to define routes for the web side of our application. This route defines a POST /users request to go to Controllers::Users::Create. What is this mythical constant? It’s going to be the action that serves this request.
In this application, we’re going to put actions inside their own classes. This will keep the code for each action more clearly isolated from other actions.
We’ll define this action inside lib/bix/web/controllers/users/create.rb:
module Bix
module Web
module Controllers
module Users
class Create
include Hanami::Action
def call(params)
self.body = "{}"
end
end
end
end
end
end
This action class includes the Hanami::Action module from the hanami-controller gem. This gives us access to a number of helpful methods, but the only one of these we’re using now is self.body=, which we’re using to set the response body to an empty JSON hash. What’s also worth mentioning here is that due to us not specifying a status, this action will return a 200 status.
With our router and controller now setup correctly, let’s switch back to looking at our tests.
Running our tests
When we run these tests with bundle exec rspec spec/requests we’ll see they’re both failing:
1) /users POST / with valid input succeeds
Failure/Error: expect(user["id"]).not_to be_nil
expected: not nil
got: nil
# ./spec/requests/users_spec.rb:18:in `block (4 levels) in <top (required)>'
2) /users POST / with invalid input returns an error
Failure/Error: expect(last_response.status).to eq(422)
expected: 422
got: 200
(compared using ==)
# ./spec/requests/users_spec.rb:36:in `block (4 levels) in <top (required)>'
This is happening because all our action returns is an empty JSON body. Let’s work on changing this.
We’ll change the action to use the transaction class:
module Bix
module Web
module Controllers
module Users
class Create
include Hanami::Action
include Import["transactions.users.create_user"]
include Dry::Monads[:result]
def call(params)
case create_user.call(params.to_h)
in Success(result)
self.body = result.to_h.to_json
self.status = 200
in Failure(result)
self.body = { errors: result.errors.to_h }.to_json
self.status = 422
end
end
end
end
end
end
end
At the top of this controller action, we import the create_user transaction by using the Import constant that we made a few parts ago – this is from dry-auto_inject.
Then we include Dry::Moands[:result] – this gives us access to the Success and Failure methods we use inside the action.
Inside the action itself, we call the transaction and then use Ruby 2.7’s new pattern matching to decide what to do. In the case of a successful transaction, we return the body of the result. If it fails, we return the errors and set the status to 422.
This should be exactly what our test is expecting. Let’s run them again and find out:
2 examples, 0 failures
Good! Our tests for our router are now passing. But this only means that our router is working, not that we can serve HTTP requests yet! We need one final piece for that to work.
Racking up the server
To run our HTTP server, we’ll use a gem called puma. Let’s add that gem to the Gemfile now:
gem "puma"
And we’ll run bundle install to install it.
To run the Puma server, we can use the command by the same name:
puma
When we do this, we get an error:
Puma starting in single mode...
* Version 3.12.1 (ruby 2.7.0-p0), codename: Llamas in Pajamas
* Min threads: 0, max threads: 16
* Environment: development
ERROR: No application configured, nothing to run
This is because Puma hasn’t been told what to run yet. The good thing for us is that Puma will look for a special file to know what to run. That file is called config.ru. Let’s create that file now:
require_relative "config/application"
Bix::Application.finalize!
run Bix::Web.app
This file looks a lot like bin/console:
#!/usr/bin/env ruby
require_relative '../config/application'
Bix::Application.finalize!
require 'irb'
IRB.start
The difference is that we’re starting a server, instead of starting a console session.
Let’s try puma again:
Puma starting in single mode...
* Version 3.12.1 (ruby 2.7.0-p0), codename: Llamas in Pajamas
* Min threads: 0, max threads: 16
* Environment: development
* Listening on tcp://0.0.0.0:9292
Great! We now have a HTTP server listening on port 9292.
To test this out, we can do one of two things. If you have the marvellous httpie installed, you can run this command:
http --json post http://localhost:9292/users first_name=Ryan last_name=Bigg
Otherwise, if you’re using curl, it’s a little more verbose:
curl --request 'POST' \
-i \
--header 'Content-Type: application/json' \
--data '{"first_name":"Ryan"}' \
'http://localhost:9292/users'
(Use HTTPie!)
Either way, what we’ll see returned here is a validation error message indicating that our input was not quite complete:
HTTP/1.1 422 Unprocessable Entity
Content-Length: 39
Content-Type: application/json; charset=utf-8
{
"errors": {
"last_name": [
"is missing"
]
}
}
Note here that the HTTP status is 422 as well.
Great, so that means the failure case for our action is now working as we wished it would.
Let’s see if we can test out the success case too with this http call:
http --json post http://localhost:9292/users first_name=Ryan last_name=Bigg
Or this curl one:
curl --request 'POST' \
-i \
--header 'Content-Type: application/json' \
--data '{"first_name":"Ryan", "last_name": "Bigg"}' \
'http://localhost:9292/users'
Now we will see a successful response:
HTTP/1.1 200 OK
Content-Length: 140
Content-Type: application/json; charset=utf-8
{
"age": null,
"created_at": "[timestamp]",
"first_name": "Ryan",
"id": 6,
"last_name": "Bigg",
"updated_at": "[timestamp]"
}
And that’s all now working!
Summary
In this fourth and final part of the ROM and Dry showcase, we barely looked at either Rom or Dry! Instead, we looked at some pieces of the Hanami web framework.
The Hanami web framework is a great alternative to the Rails framework that I’ve loved for a few years. What’s been great about Hanami in this series is that we were able to opt-in to using Hanami’s hanami-router and hanami-controller gems without having to opt-in to absolutely everything else from Hanami too.
These gems, along with the puma and rack gems, have allowed us to build a HTTP interface to our application. Our application is now capable of receiving and responding to HTTP requests.
I hope that this series has given you a great demonstration of what the rom-rb, dry-rb and Hanami gems are capable of. I strongly believe that these are viable, new-age alternatives to Rails for building modern Ruby applications.
I hope you continue to explore what these gems can offer and how you can approach building better, easier to maintain applications with them.