Pure makes Pure DI easy in Swift. This repository also introduces a way to do Pure DI in a Swift application.
Pure DI is a way to do a dependency injection without a DI container. The term was first introduced by Mark Seemann. The core concept of Pure DI is not to use a DI container and to compose an entire object dependency graph in the Composition Root.
The Composion Root is where the entire object graph is resolved. In a Cocoa application, AppDelegate
is the Composition Root.
The root dependencies are the app delegate's dependency and the root view controller's dependency. The best way to inject those dependencies is to create a struct named AppDependency
and store both dependencies in it.
struct AppDependency {
let networking: Networking
let remoteNotificationService: RemoteNotificationService
}
extension AppDependency {
static func resolve() -> AppDependency {
let networking = Networking()
let remoteNotificationService = RemoteNotificationService()
return AppDependency(
networking: networking
remoteNotificationService: remoteNotificationService
)
}
}
It is important to separate a production environment from a testing environment. We have to use an actual object in a production environment and a mock object in a testing environment.
AppDelegate is created automatically by the system using init()
. In this initializer we're going to initialize the actaul app dependency with AppDependency.resolve()
. On the other hand, we're going to provide a init(dependency:)
to inject a mock app dependency in a testing environment.
class AppDelegate: UIResponder, UIApplicationDelegate {
private let dependency: AppDependency
/// Called from the system (it's private: not accessible in the testing environment)
private override init() {
self.dependency = AppDependency.resolve()
super.init()
}
/// Called in a testing environment
init(dependency: AppDependency) {
self.dependency = dependency
super.init()
}
}
The app dependency can be used as the code below:
func application(_ application: UIApplication, didFinishLaunchingWithOptions launchOptions: [UIApplicationLaunchOptionsKey: Any]?) -> Bool {
// inject rootViewController's dependency
if let viewController = self.window?.rootViewController as? RootViewController {
viewController.networking = self.dependency.networking
}
}
func application(_ application: UIApplication, didReceiveRemoteNotification userInfo: [AnyHashable : Any], fetchCompletionHandler completionHandler: @escaping (UIBackgroundFetchResult) -> Void) {
// delegates remote notification receive event
self.dependency.remoteNotificationService.receiveRemoteNotification(userInfo)
}
AppDelegate
is one of the most important class in a Cocoa application. It resolves an app dependency and handles app events. It can be easily tested as we separated the app dependency.
This is an example test case of AppDelegate
. It verifies that AppDepegate
correctly injects root view controller's dependency in application(_:didFinishLaunchingWithOptions)
.
class AppDelegateTests: XCTestCase {
func testInjectRootViewControllerDependencies() {
// given
let networking = MockNetworking()
let mockDependency = AppDependency(
networking: networking,
remoteNotificationService: MockRemoteNotificationService()
)
let appDelegate = AppDelegate(dependency: mockDependency)
appDelegate.window = UIWindow()
appDelegate.window?.rootViewController = UIStoryboard(name: "Main", bundle: nil).instantiateInitialViewController()
// when
_ = appDelegate.application(.shared, didFinishLaunchingWithOptions: nil)
// then
let rootViewController = appDelegate.window?.rootViewController as? RootViewController
XCTAssertTrue(rootViewController?.networking === networking)
}
}
You can write tests for verifying remote notification events, open url events and even an app termination event.
But there is a problem: AppDelegate
is still created by the system while testing. It causes AppDependency.resolve()
gets called so we have to use a fake app delegate class in a testing environment.
First of all, create a new file in the test target. Define a new class named TestAppDelegate
and implement basic requirements of the delegate protocol.
// iOS
class TestAppDelegate: NSObject, UIApplicationDelegate {
var window: UIWindow?
}
// macOS
class TestAppDelegate: NSObject, NSApplicationDelegate {
}
Then create another file named main.swift
to your application target. This file will replace the entry point of the application. We are going to provide different app delegates in this file. Don't forget to replace "MyAppTests.TestAppDelegate"
with your project target and class name.
// iOS
UIApplicationMain(
CommandLine.argc,
CommandLine.unsafeArgv,
NSStringFromClass(UIApplication.self),
NSStringFromClass(NSClassFromString("MyAppTests.TestAppDelegate") ?? AppDelegate.self)
)
// macOS
func createAppDelegate() -> NSApplicationDelegate {
if let cls = NSClassFromString("AllkdicTests.TestAppDelegate") as? (NSObject & NSApplicationDelegate).Type {
return cls.init()
} else {
return AppDelegate(dependency: AppDependency.resolve())
}
}
let application = NSApplication.shared
application.delegate = createAppDelegate()
_ = NSApplicationMain(CommandLine.argc, CommandLine.unsafeArgv)
Finally, remove the @UIApplicationMain
and @NSApplicationMain
from the AppDelegate
.
// iOS
- @UIApplicationMain
class AppDelegate: UIResponder, UIApplicationDelegate
// macOS
- @NSApplicationMain
class AppDelegate: NSObject, NSApplicationDelegate
It is also a good practice to add a test case to verify that the application is using TestAppDelegate
in a testing environment.
XCTAssertTrue(UIApplication.shared.delegate is TestAppDelegate)
In Cocoa applications, view controllers are created lazily. For example, DetailViewController
is not created until the user taps an item on ListViewController
. In this case we have to pass a factory closure of DetailViewController
to ListViewController
.
/// A root view controller
class ListViewController {
var detailViewControllerFactory: ((Item) -> DetailViewController)!
func presentItemDetail(_ selectedItem: Item) {
let detailViewController = self.detailViewControllerFactory(selectedItem)
self.present(detailViewController, animated: true)
}
}
static func resolve() -> AppDependency {
let storyboard = UIStoryboard(name: "Main", bundle: nil)
let networking = Networking()
let detailViewControllerFactory: (Item) -> DetailViewController = { selectedItem in
let detailViewController = storyboard.instantiateViewController(withIdentifier: "DetailViewController") as! DetailViewController
detailViewController.networking = networking
detailViewController.item = selectedItem
return detailViewController
}
return AppDependency(
networking: networking,
detailViewControllerFactory: detailViewControllerFactory
)
}
But it has a critical problem: we cannot test the factory closure. Because the factory closure is created in the Composition Root but we should not access the Composition Root in a testing environment. What if I forget to inject the DetailViewController.networking
property?
One possible approach is to create a factory closure outside of the Composition Root. Note that Storyboard
and Networking
is from the Composition Root, and Item
is from the previous view controller so we have to separate the scope.
extension DetailViewController {
static let factory: (UIStoryboard, Networking) -> (Item) -> DetailViewController = { storyboard, networking in
return { selectedItem in
let detailViewController = storyboard.instantiateViewController(withIdentifier: "DetailViewController") as! DetailViewController
detailViewController.networking = networking
detailViewController.item = selectedItem
return detailViewController
}
}
}
static func resolve() -> AppDependency {
let storyboard = ...
let networking = ...
return .init(
detailViewControllerFactory: DetailViewController.factory(storyboard, networking)
)
}
Now we can test the DetailViewController.factory
closure. Every dependencies are resolved in the Composition Root and a selected item can be passed from ListViewController
to DetailViewController
in runtime.
There is another lazy dependency. Cells are created lazily but we cannot use the factory closure because the cells are created by the framework. We can just configure the cells.
Imagine that an UICollectionViewCell
or UITableViewCell
displays an image. There is an imageDownloader
which downloads an actual image in a production environment and returns a mock image in a testing environment.
class ItemCell {
var imageDownloader: ImageDownloaderType?
var imageURL: URL? {
didSet {
guard let imageDownloader = self.imageDownloader else { return }
self.imageView.setImage(with: self.imageURL, using: imageDownloader)
}
}
}
This cell is displayed in DetailViewController
. DetailViewController
should inject imageDownloader
to the cell and sets the image
property. Like we did in the factory, we can create a configurator closure for it. But this closure takes an existing instance and doens't have a return value.
class ItemCell {
static let configurator: (ImageDownloaderType) -> (ItemCell, UIImage) -> Void = { imageDownloader
return { cell, image in
cell.imageDownloader = imageDownloader
cell.image = image
}
}
}
DetailViewController
can have the configurator and use it when configurating cell.
class DetailViewController {
var itemCellConfigurator: ((ItemCell, UIImage) -> Void)?
func collectionView(_ collectionView: UICollectionView, cellForItemAt indexPath: IndexPath) -> UICollectionViewCell {
...
self.itemCellConfigurator?(cell, image)
return cell
}
}
DetailViewController.itemCellConfigurator
is injected from a factory.
extension DetailViewController {
static let factory: (UIStoryboard, Networking, (ItemCell, UIImage) -> Void) -> (Item) -> DetailViewController = { storyboard, networking, imageCellConfigurator in
return { selectedItem in
let detailViewController = storyboard.instantiateViewController(withIdentifier: "DetailViewController") as! DetailViewController
detailViewController.networking = networking
detailViewController.item = selectedItem
detailViewController.imageCellConfigurator = imageCellConfigurator
return detailViewController
}
}
}
And the Composition Root finally looks like:
static func resolve() -> AppDependency {
let storybard = ...
let networking = ...
let imageDownloader = ...
let listViewController = ...
listViewController.detailViewControllerFactory = DetailViewController.factory(
storyboard,
networking,
ImageCell.configurator(imageDownloader)
)
...
}
Theoretically it works. But as you can see in the DetailViewController.factory
it will be very complicated when there are many dependencies. This is why I created Pure. Pure makes factories and configurators neat.
First of all, take a look at the factory and the configurator we used in the example code.
static let factory: (UIStoryboard, Networking, (ItemCell, UIImage) -> Void) -> (Item) -> DetailViewController
static let configurator: (ImageDownloaderType) -> (ItemCell, UIImage) -> Void
Those are the functions that return another function. The outer functions are executed in the Composition Root to inject static dependencies like Networking
and the inner functions are executed in the view controllers to pass a runtime information like selectedItem
. The parameter of the outer function is Dependency. The parameter of the inner function is Payload.
static let factory: (UIStoryboard, Networking, (ItemCell, UIImage) -> Void) -> (Item) -> DetailViewController
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ ^^^^
Dependency Payload
static let configurator: (ImageDownloaderType) -> (ItemCell, UIImage) -> Void
^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^^^^^^^^^
Dependency Payload
Pure generalizes the factory and configurator using Dependency and Payload.
Pure treats every class that requires a dependency and a payload as a Module. A protocol Module
requires two types: Dependency
and Payload
.
protocol Module {
/// A dependency that is resolved in the Composition Root.
associatedtype Dependency
/// A runtime information for configuring the module.
associatedtype Payload
}
There are two types of module: FactoryModule
and ConfiguratorModule
.
FactoryModule is a generalized version of factory closure. It requires an initializer which takes both dependency
and payload
.
protocol FactoryModule: Module {
init(dependency: Dependency, payload: Payload)
}
class DetailViewController: FactoryModule {
struct Dependency {
let storyboard: UIStoryboard
let networking: Networking
}
struct Payload {
let selectedItem: Item
}
init(dependency: Dependency, payload: Payload) {
}
}
When a class conforms to FactoryModule
, it will have a nested type Factory
. Factory.init(dependency:)
takes a dependency of the module and has a method create(payload:)
which creates a new instance.
class Factory<Module> {
let dependency: Module.Dependency
func create(payload: Module.Payload) -> Module
}
// In AppDependency
let factory = DetailViewController.Factory(dependency: .init(
storyboard: storyboard
networking: networking
))
// In ListViewController
let viewController = factory.create(payload: .init(
selectedItem: selectedItem
))
ConfiguratorModule is a generalized version of configurator closure. It requires a configure()
method which takes both dependency
and payload
.
protocol ConfiguratorModule: Module {
func configure(dependency: Dependency, payload: Payload)
}
class ItemCell: ConfiguratorModule {
struct Dependency {
let imageDownloader: ImageDownloaderType
}
struct Payload {
let image: UIImage
}
func configure(dependency: Dependency, payload: Payload) {
self.imageDownloader = dependency.imageDownloader
self.image = payload.image
}
}
When a class conforms to ConfiguratorModule
, it will have a nested type Configurator
. Configurator.init(dependency:)
takes a dependency of the module and has a method configure(_:payload:)
which configures an existing instance.
class Configurator<Module> {
let dependency: Module.Dependency
func configure(_ module: Module, payload: Module.Payload)
}
// In AppDependency
let configurator = ItemCell.Configurator(dependency: .init(
imageDownloader: imageDownloader
))
// In DetailViewController
configurator.configure(cell, payload: .init(image: image))
With FactoryModule
and ConfiguratorModule
, the example can be refactored as below:
static func resolve() -> AppDependency {
let storybard = ...
let networking = ...
let imageDownloader = ...
return .init(
detailViewControllerFactory: DetailViewController.Factory(dependency: .init(
storyboard: storyboard,
networking: networking,
itemCellConfigurator: ItemCell.Configurator(dependency: .init(
imageDownloader: imageDownloader
))
))
)
}
Factory
and Configurator
are customizable. This is an example of customized factory:
extension Factory where Module == DetailViewController {
func create(payload: Module.Payload, extraValue: ExtraValue) -> Payload {
let module = self.create(payload: payload)
module.extraValue = extraValue
return module
}
}
FactoryModule
can support Storyboard-instantiated view controllers using customizing feature. The code below is an example for storyboard support of DetailViewController
:
extension Factory where Module == DetailViewController {
func create(payload: Module.Payload) -> Payload {
let module = self.dependency.storyboard.instantiateViewController(withIdentifier: "DetailViewController") as! Module
module.networking = dependency.networking
module.itemCellConfigurator = dependency.itemCellConfigurator
module.selectedItem = payload.selectedItem
return module
}
}
URLNavigator is an elegant library for deeplink support. Pure can be also used in registering a view controller to a navigator.
class UserViewController {
struct Payload {
let userID: Int
}
}
extension Factory where Module == UserViewController {
func create(url: URLConvertible, values: [String: Any], context: Any?) -> Module? {
guard let userID = values["id"] else { return nil }
return self.create(payload: .init(userID: userID))
}
}
let navigator = Navigator()
navigator.register("myapp://user/<id>", UserViewController.Factory().create)
Any discussions and pull requests are welcomed 💖
-
To development:
$ make project
-
To test:
$ swift test
Pure is under MIT license. See the LICENSE file for more info.