| name | webiny-dependency-injection |
| context | webiny-extensions |
| description | The universal createImplementation DI pattern and all injectable services. Use this skill when the developer is writing any Webiny extension and needs to understand dependency injection, constructor injection, how to access Logger/BuildParams/IdentityContext, how to inject CMS use-cases (list/get/create/update/delete entries), or how the dependencies array works. This is the connective tissue across all extension types -- API, Admin, CLI, and Infrastructure.
|
Dependency Injection Patterns
TL;DR
Every Webiny extension type uses the same DI pattern: define a class implementing *.Interface, declare dependencies in the constructor, and export via *.createImplementation({ implementation, dependencies }). The DI container automatically provides the required services, ensures type safety, and validates at compile time. This pattern is the connective tissue across all extension types -- API, Admin, CLI, and Infrastructure.
The Universal Pattern
import { SomeFactory } from "webiny/some/path";
import { Logger, BuildParams } from "webiny/api";
class MyImplementation implements SomeFactory.Interface {
constructor(
private logger: Logger.Interface,
private buildParams: BuildParams.Interface
) {}
execute() {
this.logger.info("Doing something...");
const value = this.buildParams.get<string>("MY_PARAM");
}
}
export default SomeFactory.createImplementation({
implementation: MyImplementation,
dependencies: [Logger, BuildParams]
});
Key rules:
- One class per file -- each extension file exports a single implementation.
- Constructor injection -- dependencies are received as constructor parameters, in the same order as the
dependencies array.
- Dependencies array -- must exactly match the constructor parameter order and types.
- Interface types -- always type constructor params as
Feature.Interface.
Where This Pattern Appears
| Extension Type | Factory | Import Path |
|---|
| Content Models | ModelFactory | "webiny/api/cms/model" |
| GraphQL Schemas | GraphQLSchemaFactory | "webiny/api/graphql" |
| API Keys | ApiKeyFactory | "webiny/api/security" |
| CLI Commands | CliCommandFactory | "webiny/cli/command" |
| Pulumi Handlers | CorePulumi | "webiny/infra/core" |
Event handlers use the same createImplementation pattern but are not injectable dependencies.
Examples Across Extension Types
API Extension (GraphQL Schema with DI)
GraphQL schemas use the builder pattern. The execute method receives a builder and uses addTypeDefs and addResolver to define the schema. Resolver-level DI is declared per-resolver via dependencies in addResolver, resolved at request time from the request-scoped container.
import { GraphQLSchemaFactory } from "webiny/api/graphql";
import { IdentityContext } from "webiny/api/security";
class WhoAmISchema implements GraphQLSchemaFactory.Interface {
async execute(
builder: GraphQLSchemaFactory.SchemaBuilder
): Promise<GraphQLSchemaFactory.SchemaBuilder> {
builder.addTypeDefs( `
extend type Query {
whoAmI: String
}
`);
builder.addResolver({
path: "Query.whoAmI",
dependencies: [IdentityContext],
resolver: (identityContext: IdentityContext.Interface) => {
return () => {
const identity = identityContext.getIdentity();
return `Hello, ${identity.displayName}!`;
};
}
});
return builder;
}
}
export default GraphQLSchemaFactory.createImplementation({
implementation: WhoAmISchema,
dependencies: []
});
Note: GraphQLSchemaFactory implementations typically have dependencies: [] because DI happens at the resolver level via addResolver({ dependencies }), not at the class constructor level.
CLI Command with DI
import { Ui } from "webiny/cli";
import { CliCommandFactory } from "webiny/cli/command";
class MyCommandImpl implements CliCommandFactory.Interface<{ name: string }> {
constructor(private ui: Ui.Interface) {}
execute(): CliCommandFactory.CommandDefinition<{ name: string }> {
return {
name: "greet",
description: "Greet someone",
params: [{ name: "name", description: "Name", type: "string" }],
handler: async params => {
this.ui.success(`Hello, ${params.name}!`);
}
};
}
}
export default CliCommandFactory.createImplementation({
implementation: MyCommandImpl,
dependencies: [Ui]
});
Pulumi Handler with DI
import { Ui } from "webiny/infra";
import { CorePulumi } from "webiny/infra/core";
class MyPulumiImpl implements CorePulumi.Interface {
constructor(private ui: Ui.Interface) {}
execute(app: any) {
this.ui.info("Deploying with environment:", app.env);
}
}
export default CorePulumi.createImplementation({
implementation: MyPulumiImpl,
dependencies: [Ui]
});
Advanced Dependency Options
The dependencies array supports three forms per entry:
| Form | Meaning |
|---|
Abstraction | Single required dependency (shorthand) |
[Abstraction, { optional: true }] | Single optional dependency — injects undefined if not registered |
[Abstraction, { multiple: true }] | Multi-injection — injects all registered implementations as T[] |
[Abstraction, { multiple: true, optional: true }] | Multi-injection, optional — injects undefined if none registered (vs empty [] with just multiple) |
Multi-injection ({ multiple: true })
Use when a class needs all registered implementations of an abstraction. The container calls resolveAll() internally and injects the results as an array.
Abstraction:
interface IPageType {
name: string;
label: string;
modify(form: IFormModel): void;
}
export const PageType = createAbstraction<IPageType>("PageType");
export namespace PageType {
export type Interface = IPageType;
}
Multiple implementations registered separately:
class StaticPageTypeImpl implements PageType.Interface {
name = "static";
label = "Static Page";
modify(form: IFormModel) {
}
}
export const StaticPageType = PageType.createImplementation({
implementation: StaticPageTypeImpl,
dependencies: []
});
class ProductPageTypeImpl implements PageType.Interface {
name = "product";
label = "Product Page";
modify(form: IFormModel) {
form.fields(fields => ({
product: fields.select().label("Product").required("Product is required")
}));
form.field("title").disabled(true);
form.field("path").disabled(true);
}
}
export const ProductPageType = PageType.createImplementation({
implementation: ProductPageTypeImpl,
dependencies: []
});
Consumer injects the array:
class CreatePagePresenterImpl implements CreatePagePresenter.Interface {
constructor(
private factory: FormModelFactory.Interface,
private pageTypes: PageType.Interface[],
private modifiers: CreatePageFormModifier.Interface[]
) {}
}
export const CreatePagePresenter = PresenterAbstraction.createImplementation({
implementation: CreatePagePresenterImpl,
dependencies: [
FormModelFactory,
[PageType, { multiple: true }],
[CreatePageFormModifier, { multiple: true }]
]
});
Registration — each implementation is a separate container.register() call:
export const CreatePageFeature = createFeature({
name: "CreatePage",
register(container) {
container.register(StaticPageType);
container.register(ProductPageType);
container.register(CreatePagePresenter);
}
});
When CreatePagePresenter is resolved, pageTypes receives [StaticPageTypeImpl, ProductPageTypeImpl] in registration order.
Optional dependency ({ optional: true })
Use when a dependency may not be registered. The container injects undefined instead of throwing.
class MyPresenterImpl {
constructor(
private required: RequiredService.Interface,
private analytics: AnalyticsService.Interface | undefined
) {}
}
export const MyPresenter = Abstraction.createImplementation({
implementation: MyPresenterImpl,
dependencies: [RequiredService, [AnalyticsService, { optional: true }]]
});
Container API Reference
Registration
| Method | Description |
|---|
container.register(Impl) | Register a class implementation. Returns RegistrationBuilder with .inSingletonScope(). Multiple registrations of the same abstraction accumulate — resolve() returns the last, resolveAll() returns all. |
container.registerInstance(Abstraction, instance) | Register a pre-built instance (no constructor resolution). |
container.registerFactory(Abstraction, factory) | Register a factory function. Called on every resolve(). |
container.registerDecorator(Decorator) | Register a decorator that wraps resolved instances. Applied in registration order. |
container.registerComposite(Composite) | Register a composite that aggregates all implementations behind a single resolve(). |
Resolution
| Method | Description |
|---|
container.resolve(Abstraction) | Resolve single instance (last registered wins). Throws if not registered. |
container.resolveAll(Abstraction) | Resolve all registered implementations as T[]. Returns empty array if none. |
container.createChildContainer() | Create a child container that inherits parent registrations. |
Lifetime Scopes
- Transient (default): New instance on every
resolve().
- Singleton (
.inSingletonScope()): Cached after first resolution, one instance per container.
Convention: Use cases = transient. Repositories, gateways, services, registries = singleton.
Decorators
Decorators wrap resolved instances. The decoratee is always the last constructor parameter. The dependencies array does NOT include the decoratee.
class LoggingServiceDecorator implements MyService.Interface {
constructor(
private logger: Logger.Interface,
private decoratee: MyService.Interface
) {}
execute() {
this.logger.info("Before");
this.decoratee.execute();
}
}
export const MyServiceLoggingDecorator = MyService.createDecorator({
decorator: LoggingServiceDecorator,
dependencies: [Logger]
});
container.registerDecorator(MyServiceLoggingDecorator);
Composites
Composites aggregate multiple implementations behind a single resolve() call. Created via Abstraction.createComposite():
class AllValidatorsComposite implements Validator.Interface {
constructor(private validators: Validator.Interface[]) {}
validate(input: unknown) {
for (const v of this.validators) v.validate(input);
}
}
export const ValidatorComposite = Validator.createComposite({
implementation: AllValidatorsComposite,
dependencies: [[Validator, { multiple: true }]]
});
container.registerComposite(ValidatorComposite);
Key Rules
- Always import from the feature path, not the package root.
- Use
Feature.Interface for constructor parameter types.
- The
dependencies array order must match the constructor parameter order.
- Read the
abstractions.ts file in the feature folder to see available methods.
- Extensions with no dependencies use
dependencies: [].
BuildParams.get<T>(name) returns T | null — always type the receiving property/variable as nullable (e.g. string | null) and handle the null case.
- BuildParam declarations belong inside the extension's
Extension.tsx, not in webiny.config.tsx. Expose required params as React props on the extension component so the consumer decides where values come from (see webiny-full-stack-architect skill for the full pattern).
- For multi-injection, type the constructor param as
T[] and use [Abstraction, { multiple: true }] in the dependencies array.
- Each implementation of a multi-bound abstraction is a separate
container.register() call — they accumulate.
Related Skills
webiny-custom-graphql-api -- DI in GraphQL schema extensions
webiny-cli-extensions -- DI in CLI command extensions
webiny-full-stack-architect -- Full-stack extension skeleton and registration pattern
webiny-api-architect -- API-side architecture using DI
webiny-admin-architect -- Admin-side architecture using DI