Dependency Providers
A dependency provider configures an injector with a DI token, which that injector uses to provide the concrete, runtime version of a dependency value. The injector relies on the provider configuration to create instances of the dependencies that it injects into components, directives, pipes, and other services.
You must configure an injector with a provider, or it won't know how to create the dependency.
The most obvious way for an injector to create an instance of a service class is with the class itself.
If you specify the service class itself as the provider token, the default behavior is for the injector to instantiate that class with new
.
In the following typical example, the Logger
class itself provides a Logger
instance.
providers: [Logger]
You can, however, configure an injector with an alternative provider, in order to deliver some other object that provides the needed logging functionality. For instance:
-
You can provide a substitute class.
-
You can provide a logger-like object.
-
Your provider can call a logger factory function.
The Provider
object literal
The class-provider syntax is a shorthand expression that expands
into a provider configuration, defined by the Provider
interface.
The following code snippets shows how a class that is given as the providers
value is expanded into a full provider object.
providers: [Logger]
[{ provide: Logger, useClass: Logger }]
The expanded provider configuration is an object literal with two properties.
-
The
provide
property holds the token that serves as the key for both locating a dependency value and configuring the injector. -
The second property is a provider definition object, which tells the injector how to create the dependency value. The provider-definition key can be
useClass
, as in the example. It can also beuseExisting
,useValue
, oruseFactory
. Each of these keys provides a different type of dependency, as discussed below.
Alternative class providers
Different classes can provide the same service.
For example, the following code tells the injector
to return a BetterLogger
instance when the component asks for a logger
using the Logger
token.
[{ provide: Logger, useClass: BetterLogger }]
Class providers with dependencies
Another class, EvenBetterLogger
, might display the user name in the log message.
This logger gets the user from an injected UserService
instance.
@Injectable()
export class EvenBetterLogger extends Logger {
constructor(private userService: UserService) { super(); }
log(message: string) {
let name = this.userService.user.name;
super.log(`Message to ${name}: ${message}`);
}
}
The injector needs providers for both this new logging service and its dependent UserService
. Configure this alternative logger with the useClass
provider-definition key, like BetterLogger
. The following array specifies both providers in the providers
metadata option of the parent module or component.
[ UserService,
{ provide: Logger, useClass: EvenBetterLogger }]
Aliased class providers
Suppose an old component depends upon the OldLogger
class.
OldLogger
has the same interface as NewLogger
, but for some reason
you can't update the old component to use it.
When the old component logs a message with OldLogger
,
you want the singleton instance of NewLogger
to handle it instead.
In this case, the dependency injector should inject that singleton instance
when a component asks for either the new or the old logger.
OldLogger
should be an alias for NewLogger
.
If you try to alias OldLogger
to NewLogger
with useClass
, you end up with two different NewLogger
instances in your app.
[ NewLogger,
// Not aliased! Creates two instances of `NewLogger`
{ provide: OldLogger, useClass: NewLogger}]
To make sure there is only one instance of NewLogger
, alias OldLogger
with the useExisting
option.
[ NewLogger,
// Alias OldLogger w/ reference to NewLogger
{ provide: OldLogger, useExisting: NewLogger}]
Value providers
Sometimes it's easier to provide a ready-made object rather than ask the injector to create it from a class.
To inject an object you have already created,
configure the injector with the useValue
option
The following code defines a variable that creates such an object to play the logger role.
// An object in the shape of the logger service
export function SilentLoggerFn() {}
const silentLogger = {
logs: ['Silent logger says "Shhhhh!". Provided via "useValue"'],
log: SilentLoggerFn
};
The following provider object uses the useValue
key to associate the variable with the Logger
token.
[{ provide: Logger, useValue: silentLogger }]
Non-class dependencies
Not all dependencies are classes. Sometimes you want to inject a string, function, or object.
Apps often define configuration objects with lots of small facts, like the title of the application or the address of a web API endpoint. These configuration objects aren't always instances of a class. They can be object literals, as shown in the following example.
export const HERO_DI_CONFIG: AppConfig = {
apiEndpoint: 'api.heroes.com',
title: 'Dependency Injection'
};
TypeScript interfaces are not valid tokens
The HERO_DI_CONFIG
constant conforms to the AppConfig
interface.
Unfortunately, you cannot use a TypeScript interface as a token.
In TypeScript, an interface is a design-time artifact, and doesn't have a runtime representation (token) that the DI framework can use.
// FAIL! Can't use interface as provider token
[{ provide: AppConfig, useValue: HERO_DI_CONFIG })]
// FAIL! Can't inject using the interface as the parameter type
constructor(private config: AppConfig){ }
This might seem strange if you're used to dependency injection in strongly typed languages where an interface is the preferred dependency lookup key. However, JavaScript, doesn't have interfaces, so when TypeScript is transpiled to JavaScript, the interface disappears. There is no interface type information left for Angular to find at runtime.
One alternative is to provide and inject the configuration object in an NgModule like AppModule
.
providers: [
UserService,
{ provide: APP_CONFIG, useValue: HERO_DI_CONFIG }
],
Another solution to choosing a provider token for non-class dependencies is
to define and use an InjectionToken
object.
The following example shows how to define such a token.
import { InjectionToken } from '@angular/core';
export const APP_CONFIG = new InjectionToken<AppConfig>('app.config');
The type parameter, while optional, conveys the dependency's type to developers and tooling. The token description is another developer aid.
Register the dependency provider using the InjectionToken
object:
providers: [{ provide: APP_CONFIG, useValue: HERO_DI_CONFIG }]
Now you can inject the configuration object into any constructor that needs it, with
the help of an @Inject()
parameter decorator.
constructor(@Inject(APP_CONFIG) config: AppConfig) {
this.title = config.title;
}
Although the AppConfig
interface plays no role in dependency injection,
it supports typing of the configuration object within the class.
Factory providers
Sometimes you need to create a dependent value dynamically, based on information you won't have until run time. For example, you might need information that changes repeatedly in the course of the browser session. Also, your injectable service might not have independent access to the source of the information.
In cases like this you can use a factory provider. Factory providers can also be useful when creating an instance of a dependency from a third-party library that wasn't designed to work with DI.
For example, suppose HeroService
must hide secret heroes from normal users.
Only authorized users should see secret heroes.
Like EvenBetterLogger
, HeroService
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 you log in a different user.
Let's say you don't want to inject UserService
directly into HeroService
, because you don't want to complicate that service with security-sensitive information.
HeroService
won't have direct access to the user information to decide
who is authorized and who isn't.
To resolve this, we give the HeroService
constructor a boolean flag to control display of secret heroes.
constructor(
private logger: Logger,
private isAuthorized: boolean) { }
getHeroes() {
let auth = this.isAuthorized ? 'authorized ' : 'unauthorized';
this.logger.log(`Getting heroes for ${auth} user.`);
return HEROES.filter(hero => this.isAuthorized || !hero.isSecret);
}
You can inject Logger
, but you can't inject the isAuthorized
flag. Instead, you can use a factory provider to create a new logger instance for HeroService
.
A factory provider needs a factory function.
let heroServiceFactory = (logger: Logger, userService: UserService) => {
return new HeroService(logger, userService.user.isAuthorized);
};
Although HeroService
has no access to UserService
, the factory function does.
You inject both Logger
and UserService
into the factory provider
and let the injector pass them along to the factory function.
export let heroServiceProvider =
{ provide: HeroService,
useFactory: heroServiceFactory,
deps: [Logger, UserService]
};
-
The
useFactory
field tells Angular that the provider is a factory function whose implementation isheroServiceFactory
. -
The
deps
property is an array of provider tokens. TheLogger
andUserService
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.
Notice that you captured the factory provider in an exported variable, heroServiceProvider
.
This extra step makes the factory provider reusable.
You can configure a provider of HeroService
with this variable wherever you need it.
In this sample, you need it only in HeroesComponent
,
where heroServiceProvider
replaces HeroService
in the metadata providers
array.
The following shows the new and the old implementations side-by-side.
Predefined tokens and multiple providers
Angular provides a number of built-in injection-token constants that you can use to customize the behavior of various systems.
For example, you can use the following built-in tokens as hooks into the framework’s bootstrapping and initialization process. A provider object can associate any of these injection tokens with one or more callback functions that take app-specific initialization actions.
-
PLATFORM_INITIALIZER: Callback is invoked when a platform is initialized.
-
APP_BOOTSTRAP_LISTENER: Callback is invoked for each component that is bootstrapped. The handler function receives the ComponentRef instance of the bootstrapped component.
-
APP_INITIALIZER: Callback is invoked before an app is initialized. All registered initializers can optionally return a Promise. All initializer functions that return Promises must be resolved before the application is bootstrapped. If one of the initializers fails to resolves, the application is not bootstrapped.
The provider object can have a third option, multi: true
, which you can use with APP_INITIALIZER
to register multiple handlers for the provide event.
For example, when bootstrapping an application, you can register many initializers using the same token.
export const APP_TOKENS = [
{ provide: PLATFORM_INITIALIZER, useFactory: platformInitialized, multi: true },
{ provide: APP_INITIALIZER, useFactory: delayBootstrapping, multi: true },
{ provide: APP_BOOTSTRAP_LISTENER, useFactory: appBootstrapped, multi: true },
];
Multiple providers can be associated with a single token in other areas as well.
For example, you can register a custom form validator using the built-in NG_VALIDATORS token,
and provide multiple instances of a given validator provider by using the multi: true
property in the provider object.
Angular adds your custom validators to the existing collection.
The Router also makes use of multiple providers associated with a single token. When you provide multiple sets of routes using RouterModule.forRoot and RouterModule.forChild in a single module, the ROUTES token combines all the different provided sets of routes into a single value.
Tree-shakable providers
Tree shaking refers to a compiler option that removes code from the final bundle if the app doesn't reference that code. When providers are tree-shakable, the Angular compiler removes the associated services from the final output when it determines that your application doesn't use those services. This significantly reduces the size of your bundles.
Ideally, if an application isn't injecting a service, Angular shouldn't include it in the final output.
However, Angular has to be able to identify at build time whether the app will require the service or not.
Because it's always possible to inject a service directly using injector.get(Service)
,
Angular can't identify all of the places in your code where this injection could happen,
so it has no choice but to include the service in the injector.
Thus, services in the NgModule providers
array or at component level are not tree-shakable.
The following example of non-tree-shakable providers in Angular configures a service provider for the injector of an NgModule.
import { Injectable, NgModule } from '@angular/core';
@Injectable()
export class Service {
doSomething(): void {
}
}
@NgModule({
providers: [Service],
})
export class ServiceModule {
}
You can then import this module into your application module to make the service available for injection in your app, as in the following example.
@NgModule({
imports: [
BrowserModule,
RouterModule.forRoot([]),
ServiceModule,
],
})
export class AppModule {
}
When ngc
runs, it compiles AppModule
into a module factory, which contains definitions for all the providers declared in all the modules it includes. At runtime, this factory becomes an injector that instantiates these services.
Tree-shaking doesn't work here because Angular can't decide to exclude one chunk of code (the provider definition for the service within the module factory) based on whether another chunk of code (the service class) is used. To make services tree-shakable, the information about how to construct an instance of the service (the provider definition) needs to be a part of the service class itself.
Creating tree-shakable providers
You can make a provider tree-shakable by specifying it in the @Injectable()
decorator on the service itself, rather than in the metadata for the NgModule or component that depends on the service.
The following example shows the tree-shakable equivalent to the ServiceModule
example above.
@Injectable({
providedIn: 'root',
})
export class Service {
}
The service can be instantiated by configuring a factory function, as in the following example.
@Injectable({
providedIn: 'root',
useFactory: () => new Service('dependency'),
})
export class Service {
constructor(private dep: string) {
}
}