Dependency Injection framework for Swift (iOS/macOS/Linux)
Declarative, easy-to-use and safe Dependency Injection framework for Swift (iOS/macOS/Linux)
Features
- [x] Dependency declaration via property wrappers or comments
- [x] DI Containers auto-generation
- [x] Dependency Graph compile time validation
- [x] ObjC support
- [x] Non-optional dependency resolution
- [x] Type safety
- [x] Injection with arguments
- [x] Registration Scopes
- [x] DI Container hierarchy
- [x] Thread safe
Talks
Tutorials
If you're looking for a step by step tutorial, check out these links.
- Part 1 - Basics
- Part 2 - Unit Testing
- Part 3 - Multi target application (coming soon)
Dependency Injection
Dependency Injection basically means "giving an object its instance variables" ¹. It seems like it's not such a big deal, but as soon as a project gets bigger, it gets tricky. Initializers become too complex, passing down dependencies through several layers becomes time consuming and just figuring out where to get a dependency from can be hard enough to give up and finally use a singleton.
However, Dependency Injection is a fundamental aspect of software architecture, and there is no good reason not to do it properly. That's where Weaver can help.
What is Weaver?
Weaver is a declarative, easy-to-use and safe Dependency Injection framework for Swift.
- Declarative because it allows developers to declare dependencies via annotations directly in the Swift code.
- Easy-to-use because it generates the necessary boilerplate code to inject dependencies into Swift types.
- Safe because it's all happening at compile time. If it compiles, it works.
How does Weaver work?
|-> validate() -> valid/invalid
swift files -> scan() -> [Token] -> parse() -> AST -> link() -> Graph -> |
|-> generate() -> source code
Weaver scans the Swift sources of the project, looking for annotations, and generates an AST (abstract syntax tree). It uses SourceKitten which is backed by Apple's SourceKit.
The AST then goes through a linking phase, which outputs a dependency graph.
Some safety checks are then performed on the dependency graph in order to ensure that the generated code won't crash at runtime. Issues are friendly reported in Xcode to make their correction easier.
Finally, Weaver generates the boilerplate code which can directly be used to make the dependency injections happen.
Installation
(1) - Weaver command
Weaver can be installed using Homebrew
, CocodaPods
or manually.
Binary form
Download the latest release with the prebuilt binary from release tab. Unzip the archive into the desired destination and run bin/weaver
Homebrew
$ brew install weaver
CocoaPods
Add the following to your Podfile
:
pod 'WeaverDI'
This will download the Weaver binaries and dependencies in Pods/ during your next pod install execution and will allow you to invoke it via ${PODS_ROOT}/WeaverDI/weaver/bin/weaver
in your Script Build Phases.
This is the best way to install a specific version of Weaver since Homebrew cannot automatically install a specific version.
Mint
To use Weaver via Mint, prefix the normal usage with mint run scribd/Weaver like so:
mint run scribd/Weaver version
To use a specific version of Weaver, add the release tag like so:
mint run scribd/Weaver@1.0.7 version
Building from source
Download the latest release source code from the release tab or clone the repository.
In the project directory, run brew update && brew bundle && make install
to build and install the command line tool.
Check installation
Run the following to check if Weaver has been installed correctly.
$ weaver swift --help
Usage:
$ weaver swift
Options:
--project-path - Project's directory.
--config-path - Configuration path.
--main-output-path - Where the swift code gets generated.
--tests-output-path - Where the test helpers gets generated.
--input-path - Paths to input files.
--ignored-path - Paths to ignore.
--cache-path - Where the cache gets stored.
--recursive-off
--tests - Activates the test helpers' generation.
--testable-imports - Modules to imports in the test helpers.
--swiftlint-disable-all - Disables all swiftlint rules.
(2) - Weaver build phase
In Xcode, add the following command to a command line build phase:
weaver swift --project-path $PROJECT_DIR/$PROJECT_NAME --main-output-path output/relative/path
Important - Move this build phase above the Compile Source
phase so that Weaver can generate the boilerplate code before compilation happens.
Basic Usage
For a more complete usage example, please check out the sample project.
Let's implement a simple app displaying a list of movies. It will be composed of three noticeable objects:
AppDelegate
where the dependencies are registered.MovieManager
providing the movies.MoviesViewController
showing a list of movies at the screen.
Let's get into the code.
AppDelegate
with comment annotations:
@UIApplicationMain
class AppDelegate: UIResponder, UIApplicationDelegate {
var window: UIWindow?
private let dependencies = MainDependencyContainer.appDelegateDependencyResolver()
// weaver: movieManager = MovieManager <- MovieManaging
// weaver: movieManager.scope = .container
// weaver: moviesViewController = MoviesViewController <- UIViewController
// weaver: moviesViewController.scope = .container
func application(_ application: UIApplication, didFinishLaunchingWithOptions launchOptions: [UIApplicationLaunchOptionsKey: Any]?) -> Bool {
window = UIWindow()
let rootViewController = dependencies.moviesViewController
window?.rootViewController = UINavigationController(rootViewController: rootViewController)
window?.makeKeyAndVisible()
return true
}
}
AppDelegate
registers two dependencies:
// weaver: movieManager = MovieManager <- MovieManaging
// weaver: moviesViewController = MoviesViewController <- UIViewController
These dependencies are made accessible to any object built from AppDelegate
because their scope is set to container
:
// weaver: movieManager.scope = .container
// weaver: moviesViewController.scope = .container
A dependency registration automatically generates the registration code and one accessor in AppDelegateDependencyContainer
, which is why the rootViewController
can be built:
let rootViewController = dependencies.moviesViewController
.
AppDelegate
with property wrapper annotations:
Since Weaver 1.0.1, you can use property wrappers instead of annotations in comments.
@UIApplicationMain
class AppDelegate: UIResponder, UIApplicationDelegate {
var window: UIWindow?
// Must be declared first!
private let dependencies = MainDependencyContainer.appDelegateDependencyResolver()
@Weaver(.registration, type: MovieManager.self, scope: .container)
private var movieManager: MovieManaging
@Weaver(.registration, type: MoviesViewController.self, scope: .container)
private var moviesViewController: UIViewController
func application(_ application: UIApplication, didFinishLaunchingWithOptions launchOptions: [UIApplicationLaunchOptionsKey: Any]?) -> Bool {
window = UIWindow()
window?.rootViewController = UINavigationController(rootViewController: moviesViewController)
window?.makeKeyAndVisible()
return true
}
}
-
Note how dependencies can be accessed from the
self
instance directly. -
Also note that the dependencies object must be declared and created prior to any other Weaver annotation. Not doing so would immediately crash the application.
-
It is possible to use comment and property wrapper annotations in the same type.
MovieManager
:
protocol MovieManaging {
func getMovies(_ completion: @escaping (Result<Page<Movie>, MovieManagerError>) -> Void)
}
final class MovieManager: MovieManaging {
func getMovies(_ completion: @escaping (Result<Page<Movie>, MovieManagerError>) -> Void) {
// fetches movies from the server...
completion(.success(movies))
}
}
MoviesViewController
with comment annotations:
final class MoviesViewController: UIViewController {
private let dependencies: MoviesViewControllerDependencyResolver
private var movies = [Movie]()
// weaver: movieManager <- MovieManaging
required init(injecting dependencies: MoviesViewControllerDependencyResolver) {
self.dependencies = dependencies
super.init(nibName: nil, bundle: nil)
}
override func viewDidLoad() {
super.viewDidLoad()
// Setups the tableview...
// Fetches the movies
dependencies.movieManager.getMovies { result in
switch result {
case .success(let page):
self.movies = page.results
self.tableView.reloadData()
case .failure(let error):
self.showError(error)
}
}
}
// ...
}
MoviesViewController
declares a dependency reference:
// weaver: movieManager <- MovieManaging
This annotation generates an accessor in MoviesViewControllerDependencyResolver
, but no registration, which means MovieManager
is not stored in MoviesViewControllerDependencyContainer
, but in its parent (the container from which it was built). In this case, AppDelegateDependencyContainer
.
MoviesViewController
also needs to declare a specific initializer:
required init(injecting dependencies: MoviesViewControllerDependencyResolver)
This initializer is used to inject the DI Container. Note that MoviesViewControllerDependencyResolver
is a protocol, which means a fake version of the DI Container can be injected when testing.
MoviesViewController
with property wrapper annotations:
final class MoviesViewController: UIViewController {
private var movies = [Movie]()
@Weaver(.reference)
private var movieManager: MovieManaging
required init(injecting _: MoviesViewControllerDependencyResolver) {
super.init(nibName: nil, bundle: nil)
}
override func viewDidLoad() {
super.viewDidLoad()
// Setups the tableview...
// Fetches the movies
movieManager.getMovies { result in
switch result {
case .success(let page):
self.movies = page.results
self.tableView.reloadData()
case .failure(let error):
self.showError(error)
}
}
}
// ...
}
API
Code Annotations
Weaver allows you to declare dependencies by annotating the code with comments like // weaver: ...
or property wrappers like @Weaver(...) var ...
It currently supports the following annotations:
- Registration
-
Adds the dependency builder to the container.
-
Adds an accessor for the dependency to the container's resolver protocol.
Example:
// weaver: dependencyName = DependencyConcreteType <- DependencyProtocol
@Weaver(.registration, type: DependencyConcreteType.self)
var dependencyName: DependencyProtocol
or
// weaver: dependencyName = DependencyConcreteType
@Weaver(.registration)
var dependencyName: DependencyConcreteType
-
dependencyName
: Dependency's name. Used to make reference to the dependency in other objects and/or annotations. -
DependencyConcreteType
: Dependency's implementation type. Can be astruct
or aclass
. -
DependencyProtocol
: Dependency'sprotocol
if any. Optional, you can register a dependency with its concrete type only.
- Reference
Adds an accessor for the dependency to the container's protocol.
Example:
// weaver: dependencyName <- DependencyType
@Weaver(.reference)
var dependencyName: DependencyType
DependencyType
: Either the concrete or abstract type of the dependency. This also defines the type the dependency's accessor returns.
- Parameter
Adds a parameter to the container's resolver protocol. This means that the generated container needs to take these parameter at initialisation. It also means that all the concerned dependency accessors need to take this parameter.
Example:
// weaver: parameterName <= ParameterType
@Weaver(.parameter)
var parameterName: ParameterType
- Scope
Sets the scope of a dependency. The default scope being container
. Only works for registrations or weak parameters.
The scope
defines a dependency lifecycle. Four scopes are available:
-
transient
: Always creates a new instance when resolved. -
container
: Builds an instance at initialization of its container and lives as long as its container lives. -
weak
: A new instance is created when resolved the first time and then lives as long as its strong references are living. -
lazy
: A new instance is created when resolved the first time with the same lifetime than its container.
Example:
// weaver: dependencyName.scope = .scopeValue
@Weaver(.registration, scope: .scopeValue)
var dependencyName: DependencyType
scopeValue
: Value of the scope. It can be one of the values described above.
- Custom Builder
Overrides a dependency's default initialization code.
Works for registration annotations only.
Example:
// weaver: dependencyName.builder = DependencyType.make
@Weaver(.registration, builder: DependencyType.make)
var dependencyName: DependencyType
DependencyType.make
: Code overriding the dependency's initialization code taking DependencyTypeInputDependencyResolver
as a parameter and returning DependencyType
(e.g. make
's signature could be static func make(_ dependencies: DependencyTypeInputDependencyResolver) -> DependencyType
).
Warning - Make sure you don't do anything unsafe with the DependencyResolver
parameter passed down in this method since it won't be caught by the dependency graph validator.
- Configuration
Sets a configuration attribute to the concerned object.
Example:
// weaver: dependencyName.attributeName = aValue
@Weaver(..., attributeName: aValue, ...)
var dependencyName: DependencyType
Configuration Attributes:
-
isIsolated: Bool
(default:false
): any object setting this to true is considered by Weaver as an object which isn't used in the project. An object flagged as isolated can only have isolated dependents. This attribute is useful to develop a feature wihout all the dependencies setup in the project. -
setter: Bool
(default:false
): generates a setter (setDependencyName(dependency)
) in the dependency container. Note that a dependency using a setter has to be set manually before being accessed through a dependency resolver or it will crash. -
objc: Bool
(default:false
): generates an ObjC compliant resolver for a given dependency, allowing it be accessed from ObjC code. -
escaping: Bool
(default:true
when applicable): asks Weaver to use@escaping
when declaring a closure parameter. -
platforms: [Platform]
(default:[]
): List of platforms for which Weaver is allowed to use the dependency. An empty list means any platform is allowed.
Using protperty wrappers with parameters:
Types using parameter annotations need to take the said parameters as an input when being registered or referenced. This is particularly true when using property wrappers, because the signature of the annotation won't compile if not done correctly.
For example, the following shows how a type taking two parameters at initialization can be annotated:
final class MovieViewController {
@Weaver(.parameter) private var movieID: Int
@Weaver(.parameter) private var movieTitle: String
}
And how that same type can be registered and referenced:
@WeaverP2(.registration)
private var movieViewController: (Int, String) -> MovieViewController
@WeaverP2(.reference)
private var moviewViewController: (Int, String) -> MovieViewController
Note that Weaver generates one property wrapper per amount of input parameters, so if a type takes one parameter WeaverP1
shall be used, for two parameters, WeaverP2
, and so on.
Writing tests:
Weaver can also generate a dependency container stub which can be used for testing. This feature is accessible by adding the option --tests
to the command (e.g. weaver swift --tests
).
To compile, the stub expects certain type doubles to be implemented.
For example, given the following code:
final class MovieViewController {
@Weaver(.reference) private var movieManager: MovieManaging
}
The generated stub expects MovieManagingDouble
to be implemented in order to compile.
Testing MoviewViewController
can then be written like the following:
final class MovieViewControllerTests: XCTestCase {
func test_view_controller() {
let dependencies = MainDependencyResolverStub()
let viewController = dependencies.buildMovieViewController()
viewController.viewDidLoad()
XCTAssertEqual(dependencies.movieManagerDouble.didRequestMovies, true)
}
}
Generate Swift Files
To generate the boilerplate code, the swift
command shall be used.
$ weaver swift --help
Usage:
$ weaver swift
Options:
--project-path - Project's directory.
--config-path - Configuration path.
--main-output-path - Where the swift code gets generated.
--tests-output-path - Where the test helpers gets generated.
--input-path - Paths to input files.
--ignored-path - Paths to ignore.
--cache-path - Where the cache gets stored.
--recursive-off
--tests - Activates the test helpers' generation.
--testable-imports - Modules to imports in the test helpers.
--swiftlint-disable-all - Disables all swiftlint rules.
--platform - Targeted platform.
--included-imports - Included imports.
--excluded-imports - Excluded imports.
Example:
weaver swift --project-path $PROJECT_DIR/$PROJECT_NAME --main-output-path Generated
Parameters:
--project-path
: Acts like a base path for other relative paths likeconfig-path
,output-path
,template-path
,input-path
andignored-path
. It defaults to the running directory.--config-path
: Path to a configuration file. By defaults, Weaver automatically detects.weaver.yaml
and.weaver.json
located atproject-path
.--main-output-path
: Path where the code will be generated. Defaults toproject-path
.--tests-output-path
: Path where the test utils code will be generated. Defaults toproject-path
.--input-path
: Path to the project's Swift code. Defaults toproject-path
. Variadic parameter, which means it can be set more than once. By default, Weaver recursively read any Swift file located under theinput-path
.--ignored-path
: Same thaninput-path
but for ignoring files which shouldn't be parsed by Weaver.--recursive-off
: Deactivates recursivity forinput-path
andignored-path
.--tests
- Activates the test helpers' generation.--testable-imports
- Modules to imports in the test helpers. Variadic parameter, which means it can be set more than once.--swiftlint-disable-all
- Disables all swiftlint rules in generated files.--platform
- Platform for which the generated code will be compiled (iOS, watchOS, OSX, macOS or tvOS).--included-imports
- Modules which can be imported in generated files.--excluded-imports
- Modules which can't be imported in generated files.
Configuration File:
Weaver can read a configuration file rather than getting its parameters from the command line. It supports both json
and yaml
formats.
To configure Weaver with a file, write a file named .weaver.yaml
or .weaver.json
at the root of your project.
Parameters are named the same, but snakecased. They also work the same way with one exception, project_path
cannot be defined in a configuration. Weaver automatically set its value to the configuration file location.
For example, the sample project configuration looks like:
main_output_path: Sample/Generated
input_paths:
- Sample
ignored_paths:
- Sample/Generated
Caching & Cleaning
In order to avoid parsing the same swift files over and over again, Weaver has a cache system built in. It means that Weaver won't reprocess files which haven't been changed since last time they got processed.
Using this functionality is great in a development environment because it makes Weaver's build phase much faster most of the time. However, on a CI it is preferable to let Weaver process the Swift files everytime for safety, for which the clean command can be used.
For example, the following always processes all of the swift code:
$ weaver clean
$ weaver swift
Export Dependency Graph
Weaver can ouput a JSON representation of the dependency graph of a project.
$ weaver json --help
Usage:
$ weaver json
Options:
--project-path - Project's directory.
--config-path - Configuration path.
--pretty [default: false]
--input-path - Paths to input files.
--ignored-path - Paths to ignore.
--cache-path - Cache path.
--recursive-off
--platform - Selected platform
For an output example, please check this Gist.
Migration guides
- From weaver 0.9.+ to 0.10.+
- From weaver 0.10.+ to 0.11.+
- From weaver 0.11.+ to 0.12.+
- From weaver 0.12.+ to 1.+
More content...
- Weaver: A Painless Dependency Injection Framework For Swift
- Dependency Injection Demisifyied, James Shore, 03/22/2006 ¹
Contributing
- Fork it
- Create your feature branch (
git checkout -b my-new-feature
) - Commit your changes (
git commit -am 'Add some feature'
) - Push to the branch (
git push origin my-new-feature
) - Create a new Pull Request
License
MIT license. See the [LICENSE file] for details.