Latest version is v4.0.1
If you need to use any older version you can find them:
- 4.0 version branch
- 3.3 version branch
- 3.2 version branch
- 3.1 version branch
- 3.0 version branch
- 2.0 version branch
To install VIPER Xcode templates clone this repo and run the following command from root folder:
make install_templates
To uninstall Xcode template run:
make uninstall_templates
After that, restart your Xcode if it was already opened.
There's a TV Shows demo project in Demo folder. You can find most common VIPER module use cases in it. If you're already familiar with the base Viper modules you can check out our RxModule Guide.
If you want to check out how you could use Formatter in your apps, feel free to check out Formatter Guide.
How to organize all your code and not end up with a couple of Massive View Controllers with millions of lines of code? In short, VIPER (View Interactor Presenter Entity Router) is an architecture which, among other things, aims at solving the common Massive View Controller problem in iOS apps. When implemented to its full extent it achieves complete separation of concerns between modules, which also yields testability. This is good because another problem with Apple's Model View Controller architecture is poor testability.
If you search the web for VIPER architecture in iOS apps you'll find a number of different implementations and a lot of them are not covered in enough detail. At Infinum we have tried out several approaches to this architecture in real-life projects and with that we have defined our own version of VIPER which we will try to cover in detail here.
Let's go over the basics quickly - the main components of VIPER are as follows:
- View: contains UI logic and knows how to layout and animate itself. It displays what it's told by the Presenter and it delegates user interaction actions to the Presenter. Ideally it contains no business logic, only view logic.
- Interactor: used for fetching data when requested by the Presenter, regardless of where the data is coming from. Contains only business logic.
- Presenter: also known as the event handler. Handles all the communication with view, interactor and wireframe. Contains presentation logic - basically it controllers the module.
- Entity: models which are handled by the Interactor. Contains only business logic, but primarily data, not rules.
- Formatter(new): handles formatting logic. Sits between presenter and the view. It formats the data from the business world into something that can be consumed by the view.
- Router: handles navigation logic. In our case we use components called Wireframes for this responsibility.
Your entire app is made up of multiple modules which you organize in logical groups and use one storyboard for that group. In most cases the modules will represent screens and your module groups will represent user-stories, business-flows and so on.
Module components:
- View
- Presenter
- Interactor (not mandatory)
- Formatter (not mandatory)
- Wireframe
In some simpler cases you won't need an Interactor for a certain module, which is why this component is not mandatory. These are cases where you don't need to fetch any data, which is usually not common.
Wireframes inherit from the BaseWireframe. Presenters and Interactors do not inherit any class. Views most often inherit UIViewControllers. All protocols should be located in one file called Interfaces. More on this later.
The following pictures shows relationships and communication for one module.
Let's take a look at the communication logic.
- LoginViewController communicates with LoginPresenter via a LoginPresenterInterface protocol
- LoginPresenter communicates with LoginViewController via a LoginViewInterface protocol
- LoginPresenter communicates with LoginInteractor via a LoginInteractorInterface protocol
- LoginPresenter communicates with LoginWireframe via a LoginWireframeInterface protocol
The communication between most components of a module is done via protocols to ensure scoping of concerns and testability. Only the Wireframe communicates directly with the Presenter since it actually instantiates the Presenter, Interactor and View and connects the three via dependency injection.
Now let's take a look at the references logic.
- LoginPresenter has a strong reference to LoginInteractor
- LoginPresenter has a strong reference to LoginWireframe
- LoginPresenter has a unowned reference to LoginViewController
- LoginViewController has a strong reference to LoginPresenter
The reference types might appear a bit counter-intuitive, but they are organized this way to assure all module components are not deallocated from memory as long as one of its Views is active. In this way the Views lifecycle is also the lifecycle of the module - which actually makes perfect sense.
The creation and setup of module components is done in the Wireframe. The creation of a new Wireframe is almost always done in the previous Wireframe. More details on this later in the actual code.
Before we go into detail we should comment one somewhat unusual decision we made naming-wise and that's suffixing protocol names with "Interface" (LoginWireframeInterface, RegisterViewInterface, ...). A common way to do this would be to omit the "Interface" part but we've found that this makes code somewhat less readable and the logic behind VIPER harder to grasp, especially when starting out.
The module generator tool will generate five files - but in order for these to work you will need a couple of base protocols and classes. These are also available in the repo. Let's start by covering these base files: WireframeInterface, BaseWireframe, ViewInterface, InteractorInterface, PresenterInterface, UIStoryboardExtension:
import UIKit
protocol WireframeInterface: AnyObject {
}
class BaseWireframe<ViewController> where ViewController: UIViewController {
private weak var _viewController: ViewController?
// We need it in order to retain the view controller reference upon first access
private var temporaryStoredViewController: ViewController?
init(viewController: ViewController) {
temporaryStoredViewController = viewController
_viewController = viewController
}
}
extension BaseWireframe: WireframeInterface {
}
extension BaseWireframe {
var viewController: ViewController {
defer { temporaryStoredViewController = nil }
guard let vc = _viewController else {
fatalError(
"""
The `ViewController` instance that the `_viewController` property holds
was already deallocated in a previous access to the `viewController` computed property.
If you don't store the `ViewController` instance as a strong reference
at the call site of the `viewController` computed property,
there is no guarantee that the `ViewController` instance won't be deallocated since the
`_viewController` property has a weak reference to the `ViewController` instance.
For the correct usage of this computed property, make sure to keep a strong reference
to the `ViewController` instance that it returns.
"""
)
}
return vc
}
var navigationController: UINavigationController? {
return viewController.navigationController
}
}
extension UIViewController {
func presentWireframe<ViewController>(_ wireframe: BaseWireframe<ViewController>, animated: Bool = true, completion: (() -> Void)? = nil) {
present(wireframe.viewController, animated: animated, completion: completion)
}
}
extension UINavigationController {
func pushWireframe<ViewController>(_ wireframe: BaseWireframe<ViewController>, animated: Bool = true) {
pushViewController(wireframe.viewController, animated: animated)
}
func setRootWireframe<ViewController>(_ wireframe: BaseWireframe<ViewController>, animated: Bool = true) {
setViewControllers([wireframe.viewController], animated: animated)
}
}
The Wireframe is used in 2 steps:
- Initialization using a UIViewController (see the init method). Since the Wireframe is in charge of performing the navigation it needs access to the actual UIViewController with which it will do so.
- Navigation to a screen (see the pushWireframe, presentWireframe and setRootWireframe methods). Those methods are defined on UIViewController and UINavigationController since those objects are responsible for performing the navigation.
protocol ViewInterface: AnyObject {
}
extension ViewInterface {
}
protocol InteractorInterface: AnyObject {
}
extension InteractorInterface {
}
protocol PresenterInterface: AnyObject {
}
extension PresenterInterface {
}
These interfaces are initially empty. They exists just to make it simple to insert any and all functions needed in all views/interactors/presenters in you project. ViewInterface and InteractorInterface protocols need to be class bound because the Presenter will hold them via a weak reference.
Ok, let's get to the actual module. First we'll cover the files you get when creating a new module via the module generator.
When running the module generator you will get five files. Say we wanted to create a Home module, we would get the following: HomeInterfaces, HomeWireframe, HomePresenter, HomeView and HomeInteractor. Let's go over all five.
protocol HomeWireframeInterface: WireframeInterface {
}
protocol HomeViewInterface: ViewInterface {
}
protocol HomePresenterInterface: PresenterInterface {
}
protocol HomeInteractorInterface: InteractorInterface {
}
This interface file will provide you with a nice overview of your entire module at one place. Since most components communicate with each other via protocols we found very useful to put all of these protocols for one module in one place. That way you have a very clean overview of the entire behavior of the module.
final class HomeWireframe: BaseWireframe<HomeViewController> {
// MARK: - Private properties -
private let storyboard = UIStoryboard(name: "Home", bundle: nil)
// MARK: - Module setup -
init() {
let moduleViewController = storyboard.instantiateViewController(ofType: HomeViewController.self)
super.init(viewController: moduleViewController)
let interactor = HomeInteractor()
let presenter = HomePresenter(view: moduleViewController, interactor: interactor, wireframe: self)
moduleViewController.presenter = presenter
}
}
// MARK: - Extensions -
extension HomeWireframe: HomeWireframeInterface {
}
It generates a Storyboard file for you too so you don't have to create one yourself. You can tailor the Storyboard to match its purpose.
final class HomePresenter {
// MARK: - Private properties -
private unowned let view: HomeViewInterface
private let interactor: HomeInteractorInterface
private let wireframe: HomeWireframeInterface
// MARK: - Lifecycle -
init(
view: HomeViewInterface,
interactor: HomeInteractorInterface,
wireframe: HomeWireframeInterface
) {
self.view = view
self.interactor = interactor
self.wireframe = wireframe
}
}
// MARK: - Extensions -
extension HomePresenter: HomePresenterInterface {
}
This is the skeleton of a Presenter which will get a lot more meat on it once you start implementing the business logic.
final class HomeViewController: UIViewController {
// MARK: - Public properties -
var presenter: HomePresenterInterface!
// MARK: - Life cycle -
override func viewDidLoad() {
super.viewDidLoad()
}
}
// MARK: - Extensions -
extension HomeViewController: HomeViewInterface {
}
Like the Presenter above, this is only a skeleton which you will populate with IBOutlets, animations and so on.
final class HomeInteractor {
}
extension HomeInteractor: HomeInteractorInterface {
}
When generated your Interactor is also a skeleton which you will in most cases use to perform fetching of data from remote API services, Database services, etc.
Here's an example of a wireframe for a Home screen. Let's start with the Presenter.
final class HomePresenter {
// MARK: - Private properties -
private unowned let view: HomeViewInterface
private let interactor: HomeInteractorInterface
private let wireframe: HomeWireframeInterface
private var items: [Show] = [] {
didSet {
view.reloadData()
}
}
// MARK: - Lifecycle -
init(
view: HomeViewInterface,
interactor: HomeInteractorInterface,
wireframe: HomeWireframeInterface
) {
self.view = view
self.interactor = interactor
self.wireframe = wireframe
}
}
// MARK: - Extensions -
extension HomePresenter: HomePresenterInterface {
func logout() {
interactor.logout()
wireframe.navigateToLogin()
}
var numberOfItems: Int {
items.count
}
func item(at indexPath: IndexPath) -> Show {
items[indexPath.row]
}
func itemSelected(at indexPath: IndexPath) {
let show = items[indexPath.row]
wireframe.navigateToShowDetails(id: show.id)
}
func loadShows() {
view.showProgressHUD()
interactor.getShows { [unowned self] result in
switch result {
case .failure(let error):
showValidationError(error)
case .success(let shows):
items = shows
}
view.hideProgressHUD()
}
}
}
private extension HomePresenter {
func showValidationError(_ error: Error) {
wireframe.showAlert(with: "Error", message: error.localizedDescription)
}
}
In this simple example the Presenter fetches TV shows by doing an API call and handles the result. The Presenter can also handle the logout action and item selection in a tableView which is delegated from the view. If an item has been selected the Presenter will initiate opening of the Details screen.
final class HomeWireframe: BaseWireframe<HomeViewController> {
// MARK: - Private properties -
private let storyboard = UIStoryboard(name: "Home", bundle: nil)
// MARK: - Module setup -
init() {
let moduleViewController = storyboard.instantiateViewController(ofType: HomeViewController.self)
super.init(viewController: moduleViewController)
let interactor = HomeInteractor()
let presenter = HomePresenter(view: moduleViewController, interactor: interactor, wireframe: self)
moduleViewController.presenter = presenter
}
}
// MARK: - Extensions -
extension HomeWireframe: HomeWireframeInterface {
func navigateToLogin() {
navigationController?.setRootWireframe(LoginWireframe())
}
func navigateToShowDetails(id: String) {
navigationController?.pushWireframe(DetailsWireframe())
}
}
This is also a simple example of a wireframe which handles two navigation functions. You've maybe noticed the showAlert Wireframe method used in the Presenter to display alerts. This is used in the BaseWireframe in this concrete project and looks like this:
func showAlert(with title: String?, message: String?) {
let okAction = UIAlertAction(title: "OK", style: .default, handler: nil)
showAlert(with: title, message: message, actions: [okAction])
}
This is just one example of some shared logic you'll want to put in your base class or maybe one of the base protocols.
Here's an example of a simple Interactor we used in the Demo project:
final class HomeInteractor {
private let userService: UserService
private let showService: ShowService
init(userService: UserService = .shared, showService: ShowService = .shared) {
self.userService = userService
self.showService = showService
}
}
// MARK: - Extensions -
extension HomeInteractor: HomeInteractorInterface {
func getShows(_ completion: @escaping ((Result<[Show], Error>) -> ())) {
showService.getShows(completion)
}
func logout() {
userService.removeUser()
}
}
The Interactor contains services which actually communicate with the server. The Interactor can contain as many services as needed but beware that you don't add the ones which aren't needed.
Using this architecture impacted the way we organize our projects. In most cases we have four main subfolders in the project folder: Application, Common, Modules and Resources. Let's go over those a bit.
Contains AppDelegate and any other app-wide components, initializers, appearance classes, managers and so on. Usually this folder contains only a few files.
Used for all common utility and view components grouped in sub folders. Some common cases for these groups are Analytics, Constants, Extensions, Protocols, Views, Networking, etc. Also here is where we always have a VIPER subfolder which contains the base VIPER protocols and classes.
This folder should contain image assets, fonts, audio and video files, and so on. We use one .xcassets for images and in that folder separate images into logical folders so we don't get a long list of files in one place.
As described earlier you can think of one VIPER module as one screen. In the Modules folder we organize screens into logical groups which are basically user-stories. Each group is organized in a sub-folder which contains one storyboard (containing all screens for that group) and multiple module sub-folders.
- https://tech.badoo.com/en/article/285/ios-architecture-patterns/
- https://www.objc.io/issues/13-architecture/viper/
- https://swifting.io/2016/03/07/VIPER-to-be-or-not-to-be.html
Feedback and code contributions are very much welcome. Just make a pull request with a short description of your changes.
Before creating a PR, please run:
ruby main.rb
from Templates
directory to generate all templates files.
By making contributions to this project you give permission for your code to be used under the same license.
Maintained and sponsored by Infinum.