893 lines
36 KiB
Plaintext
893 lines
36 KiB
Plaintext
block includes
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include ../_util-fns
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- var _thisDot = 'this.';
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:marked
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**Dependency injection** is an important application design pattern.
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Angular has its own dependency injection framework, and
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we really can't build an Angular application without it.
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It's used so widely that almost everyone just calls it _DI_.
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In this chapter we'll learn what DI is and why we want it.
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Then we'll learn [how to use it](#angular-di) in an Angular app.
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- [Why dependency injection?](#why-dependency-injection)
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- [Angular dependency injection](#angular-dependency-injection)
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- [Injector providers](#injector-providers)
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- [Dependency injection tokens](#dependency-injection-tokens)
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- [Summary](#summary)
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Run the <live-example></live-example>.
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.l-main-section#why-di
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:marked
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## Why dependency injection?
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Let's start with the following code.
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+makeExample('dependency-injection/ts/app/car/car-no-di.ts', 'car', 'app/car/car.ts (without DI)')
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:marked
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Our `Car` creates everything it needs inside its constructor.
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What's the problem?
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The problem is that our `Car` class is brittle, inflexible, and hard to test.
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Our `Car` needs an engine and tires. Instead of asking for them,
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the `Car` constructor instantiates its own copies from
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the very specific classes `Engine` and `Tires`.
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What if the `Engine` class evolves and its constructor requires a parameter?
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Our `Car` is broken and stays broken until we rewrite it along the lines of
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`#{_thisDot}engine = new Engine(theNewParameter)`.
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We didn't care about `Engine` constructor parameters when we first wrote `Car`.
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We don't really care about them now.
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But we'll *have* to start caring because
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when the definition of `Engine` changes, our `Car` class must change.
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That makes `Car` brittle.
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What if we want to put a different brand of tires on our `Car`? Too bad.
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We're locked into whatever brand the `Tires` class creates. That makes our `Car` inflexible.
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Right now each new car gets its own engine. It can't share an engine with other cars.
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While that makes sense for an automobile engine,
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we can think of other dependencies that should be shared, such as the onboard
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wireless connection to the manufacturer's service center. Our `Car` lacks the flexibility
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to share services that have been created previously for other consumers.
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When we write tests for our `Car` we're at the mercy of its hidden dependencies.
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Is it even possible to create a new `Engine` in a test environment?
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What does `Engine`itself depend upon? What does that dependency depend on?
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Will a new instance of `Engine` make an asynchronous call to the server?
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We certainly don't want that going on during our tests.
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What if our `Car` should flash a warning signal when tire pressure is low?
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How do we confirm that it actually does flash a warning
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if we can't swap in low-pressure tires during the test?
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We have no control over the car's hidden dependencies.
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When we can't control the dependencies, a class becomes difficult to test.
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How can we make `Car` more robust, flexible, and testable?
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<a id="ctor-injection"></a>
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That's super easy. We change our `Car` constructor to a version with DI:
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+makeTabs(
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'dependency-injection/ts/app/car/car.ts, dependency-injection/ts/app/car/car-no-di.ts',
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'car-ctor, car-ctor',
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'app/car/car.ts (excerpt with DI), app/car/car.ts (excerpt without DI)')(format=".")
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:marked
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See what happened? We moved the definition of the dependencies to the constructor.
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Our `Car` class no longer creates an engine or tires.
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It just consumes them.
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block ctor-syntax
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.l-sub-section
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:marked
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We also leveraged TypeScript's constructor syntax for declaring
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parameters and properties simultaneously.
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:marked
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Now we create a car by passing the engine and tires to the constructor.
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+makeExample('dependency-injection/ts/app/car/car-creations.ts', 'car-ctor-instantiation', '')(format=".")
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:marked
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How cool is that?
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The definition of the engine and tire dependencies are
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decoupled from the `Car` class itself.
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We can pass in any kind of engine or tires we like, as long as they
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conform to the general API requirements of an engine or tires.
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If someone extends the `Engine` class, that is not `Car`'s problem.
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.l-sub-section
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:marked
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The _consumer_ of `Car` has the problem. The consumer must update the car creation code to
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something like this:
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- var stylePattern = { otl: /(new Car.*$)/gm };
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+makeExample('dependency-injection/ts/app/car/car-creations.ts', 'car-ctor-instantiation-with-param', '', stylePattern)(format=".")
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:marked
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The critical point is this: `Car` itself did not have to change.
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We'll take care of the consumer's problem soon enough.
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:marked
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The `Car` class is much easier to test because we are in complete control
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of its dependencies.
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We can pass mocks to the constructor that do exactly what we want them to do
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during each test:
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- var stylePattern = { otl: /(new Car.*$)/gm };
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+makeExample('dependency-injection/ts/app/car/car-creations.ts', 'car-ctor-instantiation-with-mocks', '', stylePattern)(format=".")
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:marked
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**We just learned what dependency injection is**.
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It's a coding pattern in which a class receives its dependencies from external
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sources rather than creating them itself.
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Cool! But what about that poor consumer?
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Anyone who wants a `Car` must now
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create all three parts: the `Car`, `Engine`, and `Tires`.
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The `Car` class shed its problems at the consumer's expense.
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We need something that takes care of assembling these parts for us.
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We could write a giant class to do that:
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+makeExample('dependency-injection/ts/app/car/car-factory.ts', null, 'app/car/car-factory.ts')
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:marked
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It's not so bad now with only three creation methods.
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But maintaining it will be hairy as the application grows.
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This factory is going to become a huge spiderweb of
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interdependent factory methods!
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Wouldn't it be nice if we could simply list the things we want to build without
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having to define which dependency gets injected into what?
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This is where the dependency injection framework comes into play.
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Imagine the framework had something called an _injector_.
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We register some classes with this injector, and it figures out how to create them.
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When we need a `Car`, we simply ask the injector to get it for us and we're good to go.
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+makeExample('dependency-injection/ts/app/car/car-injector.ts','injector-call')(format=".")
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:marked
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Everyone wins. The `Car` knows nothing about creating an `Engine` or `Tires`.
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The consumer knows nothing about creating a `Car`.
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We don't have a gigantic factory class to maintain.
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Both `Car` and consumer simply ask for what they need and the injector delivers.
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This is what a **dependency injection framework** is all about.
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Now that we know what dependency injection is and appreciate its benefits,
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let's see how it is implemented in Angular.
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.l-main-section#angular-di
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:marked
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## Angular dependency injection
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Angular ships with its own dependency injection framework. This framework can also be used
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as a standalone module by other applications and frameworks.
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That sounds nice. What does it do for us when building components in Angular?
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Let's see, one step at a time.
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We'll begin with a simplified version of the `HeroesComponent`
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that we built in the [The Tour of Heroes](../tutorial/).
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+makeTabs(
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`dependency-injection/ts/app/heroes/heroes.component.1.ts,
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dependency-injection/ts/app/heroes/hero-list.component.1.ts,
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dependency-injection/ts/app/heroes/hero.ts,
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dependency-injection/ts/app/heroes/mock-heroes.ts`,
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'v1,,,',
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`app/heroes/heroes.component.ts,
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app/heroes/hero-list.component.ts,
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app/heroes/hero.ts,
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app/heroes/mock-heroes.ts`)
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:marked
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The `HeroesComponent` is the root component of the *Heroes* feature area.
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It governs all the child components of this area.
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Our stripped down version has only one child, `HeroListComponent`,
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which displays a list of heroes.
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:marked
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Right now `HeroListComponent` gets heroes from `HEROES`, an in-memory collection
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defined in another file.
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That may suffice in the early stages of development, but it's far from ideal.
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As soon as we try to test this component or want to get our heroes data from a remote server,
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we'll have to change the implementation of `heroes` and
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fix every other use of the `HEROES` mock data.
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Let's make a service that hides how we get hero data.
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.l-sub-section
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:marked
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Given that the service is a
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[separate concern](https://en.wikipedia.org/wiki/Separation_of_concerns),
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we suggest that you
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write the service code in its own file.
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+ifDocsFor('ts')
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:marked
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See [this note](#one-class-per-file) for details.
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+makeExample('dependency-injection/ts/app/heroes/hero.service.1.ts',null, 'app/heroes/hero.service.ts' )
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:marked
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Our `HeroService` exposes a `getHeroes` method that returns
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the same mock data as before, but none of its consumers need to know that.
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.l-sub-section
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:marked
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Notice the `@Injectable()` #{_decorator} above the service class.
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We'll discuss its purpose [shortly](#injectable).
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- var _perhaps = _docsFor == 'dart' ? '' : 'perhaps';
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.l-sub-section
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:marked
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We aren't even pretending this is a real service.
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If we were actually getting data from a remote server, the API would have to be
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asynchronous, #{_perhaps} returning a !{_PromiseLinked}.
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We'd also have to rewrite the way components consume our service.
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This is important in general, but not to our current story.
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:marked
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A service is nothing more than a class in Angular 2.
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It remains nothing more than a class until we register it with an Angular injector.
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#bootstrap
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:marked
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### Configuring the injector
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We don't have to create an Angular injector.
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Angular creates an application-wide injector for us during the bootstrap process.
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+makeExample('dependency-injection/ts/app/main.ts', 'bootstrap', 'app/main.ts (excerpt)')(format='.')
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:marked
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We do have to configure the injector by registering the **providers**
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that create the services our application requires.
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We'll explain what [providers](#providers) are later in this chapter.
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Before we do, let's see an example of provider registration during bootstrapping:
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+makeExample('dependency-injection/ts/app/main.1.ts', 'bootstrap-discouraged')(format='.')
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:marked
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The injector now knows about our `HeroService`.
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An instance of our `HeroService` will be available for injection across our entire application.
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Of course we can't help wondering about that comment telling us not to do it this way.
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It *will* work. It's just not a best practice.
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The bootstrap provider option is intended for configuring and overriding Angular's own
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preregistered services, such as its routing support.
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The preferred approach is to register application providers in application components.
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Because the `HeroService` is used within the *Heroes* feature area —
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and nowhere else — the ideal place to register it is in the top-level `HeroesComponent`.
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:marked
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### Registering providers in a component
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Here's a revised `HeroesComponent` that registers the `HeroService`.
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- var stylePattern = { otl: /(providers:.*),/ };
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+makeExample('dependency-injection/ts/app/heroes/heroes.component.1.ts', 'full','app/heroes/heroes.component.ts', stylePattern)(format='.')
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:marked
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Look closely at the `providers` part of the `@Component` metadata.
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An instance of the `HeroService` is now available for injection in this `HeroesComponent`
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and all of its child components.
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The `HeroesComponent` itself doesn't happen to need the `HeroService`.
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But its child `HeroListComponent` does, so we head there next.
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:marked
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### Preparing the HeroListComponent for injection
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The `HeroListComponent` should get heroes from the injected `HeroService`.
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Per the dependency injection pattern, the component must ask for the service in its
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constructor, [as we explained earlier](#ctor-injection).
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It's a small change:
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+makeTabs(
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`dependency-injection/ts/app/heroes/hero-list.component.2.ts,
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dependency-injection/ts/app/heroes/hero-list.component.1.ts`,
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null,
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`app/heroes/hero-list.component (with DI),
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app/heroes/hero-list.component (without DI)`)
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.l-sub-section
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:marked
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#### Focus on the constructor
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Adding a parameter to the constructor isn't all that's happening here.
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+makeExample('dependency-injection/ts/app/heroes/hero-list.component.2.ts', 'ctor')(format=".")
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:marked
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Note that the constructor parameter has the type `HeroService`, and that
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the `HeroListComponent` class has an `@Component` #{_decorator}
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(scroll up to confirm that fact).
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Also recall that the parent component (`HeroesComponent`)
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has `providers` information for `HeroService`.
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The constructor parameter type, the `@Component` #{_decorator},
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and the parent's `providers` information combine to tell the
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Angular injector to inject an instance of
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`HeroService` whenever it creates a new `HeroListComponent`.
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#di-metadata
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:marked
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### Implicit injector creation
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When we introduced the idea of an injector above, we showed how to
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use it to create a new `Car`. Here we also show how such an injector
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would be explicitly created:
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+makeExample('dependency-injection/ts/app/car/car-injector.ts','injector-create-and-call')(format=".")
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:marked
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We won't find code like that in the Tour of Heroes or any of our other samples.
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We *could* write code that [explicitly creates an injector](#explicit-injector) if we *had* to, but we rarely do.
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Angular takes care of creating and calling injectors
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when it creates components for us — whether through HTML markup, as in `<hero-list></hero-list>`,
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or after navigating to a component with the [router](./router.html).
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If we let Angular do its job, we'll enjoy the benefits of automated dependency injection.
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:marked
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### Singleton services
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Dependencies are singletons within the scope of an injector.
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In our example, a single `HeroService` instance is shared among the
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`HeroesComponent` and its `HeroListComponent` children.
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However, Angular DI is an hierarchical injection
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system, which means that nested injectors can create their own service instances.
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Learn more about that in the [Hierarchical Injectors](./hierarchical-dependency-injection.html) chapter.
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:marked
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### Testing the component
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We emphasized earlier that designing a class for dependency injection makes the class easier to test.
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Listing dependencies as constructor parameters may be all we need to test application parts effectively.
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For example, we can create a new `HeroListComponent` with a mock service that we can manipulate
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under test:
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+makeExample('dependency-injection/ts/app/test.component.ts', 'spec')(format='.')
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.l-sub-section
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:marked
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Learn more in [Testing](../testing/index.html).
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:marked
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### When the service needs a service
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Our `HeroService` is very simple. It doesn't have any dependencies of its own.
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What if it had a dependency? What if it reported its activities through a logging service?
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We'd apply the same *constructor injection* pattern,
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adding a constructor that takes a `Logger` parameter.
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Here is the revision compared to the original.
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+makeTabs(
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`dependency-injection/ts/app/heroes/hero.service.2.ts,
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dependency-injection/ts/app/heroes/hero.service.1.ts`,
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null,
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`app/heroes/hero.service (v2),
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app/heroes/hero.service (v1)`)
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:marked
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The constructor now asks for an injected instance of a `Logger` and stores it in a private property called `#{_priv}logger`.
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We call that property within our `getHeroes` method when anyone asks for heroes.
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//- FIXME refer to Dart API when that page becomes available.
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- var injMetaUrl = 'https://angular.io/docs/ts/latest/api/core/index/InjectableMetadata-class.html';
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h3#injectable Why @Injectable()?
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:marked
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**<a href="#{injMetaUrl}">@Injectable()</a>** marks a class as available to an
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injector for instantiation. Generally speaking, an injector will report an
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error when trying to instantiate a class that is not marked as
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`@Injectable()`.
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block injectable-not-always-needed-in-ts
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.l-sub-section
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:marked
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As it happens, we could have omitted `@Injectable()` from our first
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version of `HeroService` because it had no injected parameters.
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But we must have it now that our service has an injected dependency.
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We need it because Angular requires constructor parameter metadata
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in order to inject a `Logger`.
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.callout.is-helpful
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header Suggestion: add @Injectable() to every service class
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:marked
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We recommend adding `@Injectable()` to every service class, even those that don't have dependencies
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and, therefore, do not technically require it. Here's why:
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ul(style="font-size:inherit")
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li <b>Future proofing:</b> No need to remember <code>@Injectable()</code> when we add a dependency later.
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li <b>Consistency:</b> All services follow the same rules, and we don't have to wonder why #{_a} #{_decorator} is missing.
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:marked
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Injectors are also responsible for instantiating components
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like `HeroesComponent`. Why haven't we marked `HeroesComponent` as
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`@Injectable()`?
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We *can* add it if we really want to. It isn't necessary because the
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`HeroesComponent` is already marked with `@Component`, and this
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!{_decorator} class (like `@Directive` and `@Pipe`, which we'll learn about later)
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is a subtype of <a href="#{injMetaUrl}">InjectableMetadata</a>. It is in
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fact `InjectableMetadata` #{_decorator}s that
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identify a class as a target for instantiation by an injector.
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+ifDocsFor('ts')
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.l-sub-section
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:marked
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At runtime, injectors can read class metadata in the transpiled JavaScript code
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and use the constructor parameter type information
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to determine what things to inject.
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Not every JavaScript class has metadata.
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The TypeScript compiler discards metadata by default.
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If the `emitDecoratorMetadata` compiler option is true
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(as it should be in the `tsconfig.json`),
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the compiler adds the metadata to the generated JavaScript
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for _every class with at least one decorator_.
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While any decorator will trigger this effect, mark the service class with the
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<a href="#{injMetaUrl}">InjectableMetadata</a> #{_decorator}
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to make the intent clear.
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.callout.is-critical
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header Always include the parentheses
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block always-include-paren
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:marked
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Always write `@Injectable()`, not just `@Injectable`.
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Our application will fail mysteriously if we forget the parentheses.
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.l-main-section#logger-service
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:marked
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## Creating and registering a logger service
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We're injecting a logger into our `HeroService` in two steps:
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1. Create the logger service.
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1. Register it with the application.
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Our logger service is quite simple:
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+makeExample('dependency-injection/ts/app/logger.service.ts', null, 'app/logger.service.ts')
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block real-logger
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//- N/A
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:marked
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We're likely to need the same logger service everywhere in our application,
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so we put it in the project's `#{_appDir}` folder, and
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|
we register it in the `providers` #{_array} of the metadata for our application root component, `AppComponent`.
|
|
|
|
+makeExcerpt('app/providers.component.ts','providers-logger','app/app.component.ts (excerpt)')
|
|
|
|
:marked
|
|
If we forget to register the logger, Angular throws an exception when it first looks for the logger:
|
|
code-example(format="nocode").
|
|
EXCEPTION: No provider for Logger! (HeroListComponent -> HeroService -> Logger)
|
|
|
|
:marked
|
|
That's Angular telling us that the dependency injector couldn't find the *provider* for the logger.
|
|
It needed that provider to create a `Logger` to inject into a new
|
|
`HeroService`, which it needed to
|
|
create and inject into a new `HeroListComponent`.
|
|
|
|
The chain of creations started with the `Logger` provider. *Providers* are the subject of our next section.
|
|
|
|
.l-main-section#providers
|
|
:marked
|
|
## Injector providers
|
|
|
|
A provider *provides* the concrete, runtime version of a dependency value.
|
|
The injector relies on **providers** to create instances of the services
|
|
that the injector injects into components and other services.
|
|
|
|
We must register a service *provider* with the injector, or it won't know how to create the service.
|
|
|
|
Earlier we registered the `Logger` service in the `providers` #{_array} of the metadata for the `AppComponent` like this:
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-logger')
|
|
|
|
- var implements = _docsFor == 'dart' ? 'implements' : 'looks and behaves like a '
|
|
- var objectlike = _docsFor == 'dart' ? '' : 'an object that behaves like '
|
|
- var loggerlike = _docsFor == 'dart' ? '' : 'We could provide a logger-like object. '
|
|
:marked
|
|
There are many ways to *provide* something that #{implements} `Logger`.
|
|
The `Logger` class itself is an obvious and natural provider.
|
|
But it's not the only way.
|
|
|
|
We can configure the injector with alternative providers that can deliver #{objectlike} a `Logger`.
|
|
We could provide a substitute class. #{loggerlike}
|
|
We could give it a provider that calls a logger factory function.
|
|
Any of these approaches might be a good choice under the right circumstances.
|
|
|
|
What matters is that the injector has a provider to go to when it needs a `Logger`.
|
|
|
|
//- Dart limitation: the provide function isn't const so it cannot be used in an annotation.
|
|
- var _andProvideFn = _docsFor == 'dart' ? '' : 'and <i>provide</i> object literal';
|
|
#provide
|
|
:marked
|
|
### The *Provider* class !{_andProvideFn}
|
|
|
|
:marked
|
|
We wrote the `providers` #{_array} like this:
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-1')
|
|
|
|
block provider-shorthand
|
|
:marked
|
|
This is actually a shorthand expression for a provider registration
|
|
using a _provider_ object literal with two properties:
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-3')
|
|
|
|
block provider-ctor-args
|
|
- var _secondParam = 'provider definition object';
|
|
|
|
:marked
|
|
The first is the [token](#token) that serves as the key for both locating a dependency value
|
|
and registering the provider.
|
|
|
|
The second is a !{_secondParam},
|
|
which we can think of as a *recipe* for creating the dependency value.
|
|
There are many ways to create dependency values ... and many ways to write a recipe.
|
|
|
|
#class-provider
|
|
:marked
|
|
### Alternative class providers
|
|
|
|
Occasionally we'll ask a different class to provide the service.
|
|
The following code tells the injector
|
|
to return a `BetterLogger` when something asks for the `Logger`.
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-4')
|
|
|
|
block dart-diff-const-metadata
|
|
//- N/A
|
|
|
|
:marked
|
|
### Class provider with dependencies
|
|
Maybe an `EvenBetterLogger` could display the user name in the log message.
|
|
This logger gets the user from the injected `UserService`,
|
|
which happens also to be injected at the application level.
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','EvenBetterLogger')(format='.')
|
|
|
|
:marked
|
|
Configure it like we did `BetterLogger`.
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-5')(format=".")
|
|
|
|
:marked
|
|
### Aliased class providers
|
|
|
|
Suppose an old component depends upon an `OldLogger` class.
|
|
`OldLogger` has the same interface as the `NewLogger`, but for some reason
|
|
we can't update the old component to use it.
|
|
|
|
When the *old* component logs a message with `OldLogger`,
|
|
we want the singleton instance of `NewLogger` to handle it instead.
|
|
|
|
The dependency injector should inject that singleton instance
|
|
when a component asks for either the new or the old logger.
|
|
The `OldLogger` should be an alias for `NewLogger`.
|
|
|
|
We certainly do not want two different `NewLogger` instances in our app.
|
|
Unfortunately, that's what we get if we try to alias `OldLogger` to `NewLogger` with `useClass`.
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-6a')(format=".")
|
|
|
|
:marked
|
|
The solution: alias with the `useExisting` option.
|
|
|
|
- var stylePattern = { otl: /(useExisting: \w*)/gm };
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-6b', '', stylePattern)(format=".")
|
|
|
|
#value-provider
|
|
:marked
|
|
### Value providers
|
|
|
|
:marked
|
|
Sometimes it's easier to provide a ready-made object rather than ask the injector to create it from a class.
|
|
|
|
block dart-diff-const-metadata-ctor
|
|
//- N/A
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','silent-logger')(format=".")
|
|
|
|
:marked
|
|
Then we register a provider with the `useValue` option,
|
|
which makes this object play the logger role.
|
|
|
|
- var stylePattern = { otl: /(useValue: \w*)/gm };
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-7', '', stylePattern)(format=".")
|
|
|
|
:marked
|
|
See more `useValue` examples in the
|
|
[Non-class dependencies](#non-class-dependencies) and
|
|
[OpaqueToken](#opaquetoken) sections.
|
|
|
|
#factory-provider
|
|
:marked
|
|
### Factory providers
|
|
|
|
Sometimes we need to create the dependent value dynamically,
|
|
based on information we won't have until the last possible moment.
|
|
Maybe the information changes repeatedly in the course of the browser session.
|
|
|
|
Suppose also that the injectable service has no independent access to the source of this information.
|
|
|
|
This situation calls for a **factory provider**.
|
|
|
|
Let's illustrate by adding a new business requirement:
|
|
the HeroService must hide *secret* heroes from normal users.
|
|
Only authorized users should see secret heroes.
|
|
|
|
Like the `EvenBetterLogger`, the `HeroService` needs a fact about the user.
|
|
It needs to know if the user is authorized to see secret heroes.
|
|
That authorization can change during the course of a single application session,
|
|
as when we log in a different user.
|
|
|
|
Unlike `EvenBetterLogger`, we can't inject the `UserService` into the `HeroService`.
|
|
The `HeroService` won't have direct access to the user information to decide
|
|
who is authorized and who is not.
|
|
|
|
.l-sub-section
|
|
:marked
|
|
Why? We don't know either. Stuff like this happens.
|
|
|
|
:marked
|
|
Instead the `HeroService` constructor takes a boolean flag to control display of secret heroes.
|
|
|
|
+makeExample('dependency-injection/ts/app/heroes/hero.service.ts','internals', 'app/heroes/hero.service.ts (excerpt)')(format='.')
|
|
|
|
:marked
|
|
We can inject the `Logger`, but we can't inject the boolean `isAuthorized`.
|
|
We'll have to take over the creation of new instances of this `HeroService` with a factory provider.
|
|
|
|
A factory provider needs a factory function:
|
|
|
|
+makeExample('dependency-injection/ts/app/heroes/hero.service.provider.ts','factory', 'app/heroes/hero.service.provider.ts (excerpt)')(format='.')
|
|
|
|
:marked
|
|
Although the `HeroService` has no access to the `UserService`, our factory function does.
|
|
|
|
We inject both the `Logger` and the `UserService` into the factory provider and let the injector pass them along to the factory function:
|
|
|
|
+makeExample('dependency-injection/ts/app/heroes/hero.service.provider.ts','provider', 'app/heroes/hero.service.provider.ts (excerpt)')(format='.')
|
|
|
|
.l-sub-section
|
|
:marked
|
|
The `useFactory` field tells Angular that the provider is a factory function
|
|
whose implementation is the `heroServiceFactory`.
|
|
|
|
The `deps` property is #{_an} #{_array} of [provider tokens](#token).
|
|
The `Logger` and `UserService` classes serve as tokens for their own class providers.
|
|
The injector resolves these tokens and injects the corresponding services into the matching factory function parameters.
|
|
|
|
- var exportedvar = _docsFor == 'dart' ? 'constant' : 'exported variable'
|
|
- var variable = _docsFor == 'dart' ? 'constant' : 'variable'
|
|
:marked
|
|
Notice that we captured the factory provider in #{_an} #{exportedvar}, `heroServiceProvider`.
|
|
This extra step makes the factory provider reusable.
|
|
We can register our `HeroService` with this #{variable} wherever we need it.
|
|
|
|
In our sample, we need it only in the `HeroesComponent`,
|
|
where it replaces the previous `HeroService` registration in the metadata `providers` #{_array}.
|
|
Here we see the new and the old implementation side-by-side:
|
|
|
|
- var stylePattern = { otl: /(providers.*),$/gm };
|
|
+makeTabs(
|
|
`dependency-injection/ts/app/heroes/heroes.component.ts,
|
|
dependency-injection/ts/app/heroes/heroes.component.1.ts`,
|
|
',full',
|
|
`app/heroes/heroes.component (v3),
|
|
app/heroes/heroes.component (v2)`,
|
|
stylePattern)
|
|
|
|
.l-main-section#token
|
|
:marked
|
|
## Dependency injection tokens
|
|
|
|
When we register a provider with an injector, we associate that provider with a dependency injection token.
|
|
The injector maintains an internal *token-provider* map that it references when
|
|
asked for a dependency. The token is the key to the map.
|
|
|
|
In all previous examples, the dependency value has been a class *instance*, and
|
|
the class *type* served as its own lookup key.
|
|
Here we get a `HeroService` directly from the injector by supplying the `HeroService` type as the token:
|
|
|
|
+makeExample('dependency-injection/ts/app/injector.component.ts','get-hero-service')(format='.')
|
|
|
|
:marked
|
|
We have similar good fortune when we write a constructor that requires an injected class-based dependency.
|
|
We define a constructor parameter with the `HeroService` class type,
|
|
and Angular knows to inject the
|
|
service associated with that `HeroService` class token:
|
|
|
|
+makeExample('dependency-injection/ts/app/heroes/hero-list.component.ts', 'ctor-signature')
|
|
|
|
:marked
|
|
This is especially convenient when we consider that most dependency values are provided by classes.
|
|
|
|
//- TODO: if function injection is useful explain or illustrate why.
|
|
:marked
|
|
### Non-class dependencies
|
|
p
|
|
| What if the dependency value isn't a class? Sometimes the thing we want to inject is a
|
|
block non-class-dep-eg
|
|
span string, function, or object.
|
|
p
|
|
| Applications often define configuration objects with lots of small facts
|
|
| (like the title of the application or the address of a web API endpoint)
|
|
block config-obj-maps
|
|
| but these configuration objects aren't always instances of a class.
|
|
| They can be object literals
|
|
| such as this one:
|
|
|
|
+makeExample('dependency-injection/ts/app/app.config.ts','config','app/app-config.ts (excerpt)')(format='.')
|
|
|
|
:marked
|
|
We'd like to make this configuration object available for injection.
|
|
We know we can register an object with a [value provider](#value-provider).
|
|
|
|
block what-should-we-use-as-token
|
|
:marked
|
|
But what should we use as the token?
|
|
We don't have a class to serve as a token.
|
|
There is no `AppConfig` class.
|
|
|
|
.l-sub-section#interface
|
|
:marked
|
|
### TypeScript interfaces aren't valid tokens
|
|
|
|
The `HERO_DI_CONFIG` constant has an interface, `AppConfig`. Unfortunately, we
|
|
cannot use a TypeScript interface as a token:
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-9-interface')(format=".")
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','provider-9-ctor-interface')(format=".")
|
|
:marked
|
|
That seems strange if we're used to dependency injection in strongly typed languages, where
|
|
an interface is the preferred dependency lookup key.
|
|
|
|
It's not Angular's fault. An interface is a TypeScript design-time artifact. JavaScript doesn't have interfaces.
|
|
The TypeScript interface disappears from the generated JavaScript.
|
|
There is no interface type information left for Angular to find at runtime.
|
|
|
|
//- FIXME simplify once APIs are defined for Dart.
|
|
- var opaquetoken = _docsFor == 'dart' ? '<b>OpaqueToken</b>' : '<a href="../api/core/index/OpaqueToken-class.html"><b>OpaqueToken</b></a>'
|
|
:marked
|
|
### OpaqueToken
|
|
|
|
One solution to choosing a provider token for non-class dependencies is
|
|
to define and use an !{opaquetoken}.
|
|
The definition looks like this:
|
|
|
|
+makeExample('dependency-injection/ts/app/app.config.ts','token')(format='.')
|
|
|
|
:marked
|
|
We register the dependency provider using the `OpaqueToken` object:
|
|
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','providers-9')(format=".")
|
|
|
|
:marked
|
|
Now we can inject the configuration object into any constructor that needs it, with
|
|
the help of an `@Inject` #{_decorator}:
|
|
|
|
+makeExample('dependency-injection/ts/app/app.component.2.ts','ctor')(format=".")
|
|
|
|
- var configType = _docsFor == 'dart' ? '<code>Map</code>' : '<code>AppConfig</code>'
|
|
.l-sub-section
|
|
:marked
|
|
Although the !{configType} interface plays no role in dependency injection,
|
|
it supports typing of the configuration object within the class.
|
|
|
|
block dart-map-alternative
|
|
:marked
|
|
Or we can provide and inject the configuration object in our top-level `AppComponent`.
|
|
|
|
+makeExcerpt('app/app.component.ts','providers')
|
|
|
|
#optional
|
|
:marked
|
|
## Optional dependencies
|
|
|
|
Our `HeroService` *requires* a `Logger`, but what if it could get by without
|
|
a logger?
|
|
We can tell Angular that the dependency is optional by annotating the
|
|
constructor argument with `@Optional()`:
|
|
|
|
+ifDocsFor('ts')
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','import-optional', '')
|
|
+makeExample('dependency-injection/ts/app/providers.component.ts','provider-10-ctor', '')(format='.')
|
|
|
|
:marked
|
|
When using `@Optional()`, our code must be prepared for a null value. If we
|
|
don't register a logger somewhere up the line, the injector will set the
|
|
value of `logger` to null.
|
|
|
|
.l-main-section
|
|
:marked
|
|
## Summary
|
|
|
|
We learned the basics of Angular dependency injection in this chapter.
|
|
We can register various kinds of providers,
|
|
and we know how to ask for an injected object (such as a service) by
|
|
adding a parameter to a constructor.
|
|
|
|
Angular dependency injection is more capable than we've described.
|
|
We can learn more about its advanced features, beginning with its support for
|
|
nested injectors, in the
|
|
[Hierarchical Dependency Injection](hierarchical-dependency-injection.html) chapter.
|
|
|
|
.l-main-section#explicit-injector
|
|
:marked
|
|
## Appendix: Working with injectors directly
|
|
|
|
We rarely work directly with an injector, but
|
|
here's an `InjectorComponent` that does.
|
|
|
|
+makeExample('dependency-injection/ts/app/injector.component.ts', 'injector', 'app/injector.component.ts')
|
|
|
|
:marked
|
|
An `Injector` is itself an injectable service.
|
|
|
|
In this example, Angular injects the component's own `Injector` into the component's constructor.
|
|
The component then asks the injected injector for the services it wants.
|
|
|
|
Note that the services themselves are not injected into the component.
|
|
They are retrieved by calling `injector.get`.
|
|
|
|
The `get` method throws an error if it can't resolve the requested service.
|
|
We can call `get` with a second parameter (the value to return if the service is not found)
|
|
instead, which we do in one case
|
|
to retrieve a service (`ROUS`) that isn't registered with this or any ancestor injector.
|
|
|
|
.l-sub-section
|
|
:marked
|
|
The technique we just described is an example of the
|
|
[service locator pattern](https://en.wikipedia.org/wiki/Service_locator_pattern).
|
|
|
|
We **avoid** this technique unless we genuinely need it.
|
|
It encourages a careless grab-bag approach such as we see here.
|
|
It's difficult to explain, understand, and test.
|
|
We can't know by inspecting the constructor what this class requires or what it will do.
|
|
It could acquire services from any ancestor component, not just its own.
|
|
We're forced to spelunk the implementation to discover what it does.
|
|
|
|
Framework developers may take this approach when they
|
|
must acquire services generically and dynamically.
|
|
|
|
+ifDocsFor('ts')
|
|
.l-main-section#one-class-per-file
|
|
:marked
|
|
## Appendix: Why we recommend one class per file
|
|
|
|
Having multiple classes in the same file is confusing and best avoided.
|
|
Developers expect one class per file. Keep them happy.
|
|
|
|
If we scorn this advice and, say,
|
|
combine our `HeroService` class with the `HeroesComponent` in the same file,
|
|
**define the component last!**
|
|
If we define the component before the service,
|
|
we'll get a runtime null reference error.
|
|
|
|
.l-sub-section
|
|
:marked
|
|
We actually can define the component first with the help of the `forwardRef()` method as explained
|
|
in this [blog post](http://blog.thoughtram.io/angular/2015/09/03/forward-references-in-angular-2.html).
|
|
But why flirt with trouble?
|
|
Avoid the problem altogether by defining components and services in separate files.
|