@typespec/http-server-js

## Functionality and generated code The emitter generates a few major components: ### Router The highest-level component that your code interacts with directly is the router implementation. `@typespec/http-server-js` generates a static router that you can bind to an implementation of an HTTP server. The router is generated in the `http/router.js` module within the output directory. Each service will have its own router implementation named after the service. For example, given a service namespace named `Todo`, the router module will export a function `createTodoRouter`. This function creates an instance of a router that dispatches methods within the `Todo` service. ```ts import { createTodoRouter } from "../tsp-output/@typespec/http-server-js/http/router.js"; const router = createTodoRouter(users, todoItems, attachments); ``` As arguments, the `createTodoRouter` function expects implementations of the underlying service interfaces. These interfaces are explained further in the next section. Once the router is created, it is bound to an instance of the HTTP server. The router's `dispatch` method implements the Node.js event handler signature for the `request` event on a Node.js HTTP server. ```ts const server = http.createServer(); server.on("request", router.dispatch); server.listen(8080, () => { console.log("Server listening on http://localhost:8080"); }); ``` Alternatively, the router can be used with Express.js instead of the Node.js HTTP server directly. If the `express` feature is enabled in the emitter options, the router will expose an `expressMiddleware` property that implements the Express.js middleware interface. ```ts import express from "express"; const app = express(); app.use(router.expressMiddleware); app.listen(8080, () => { console.log("Server listening on http://localhost:8080"); }); ``` ### Service interfaces The emitter generates interfaces for each collection of service methods that exists in the service namespace. Implementations of these interfaces are required to instantiate the router. When the router processes an HTTP request, it will call the appropriate method on the service implementation after determining the route and method. For example, given the following TypeSpec namespace `Users` within the `Todo` service: ```tsp namespace Users { @route("/users") @post op create( user: User, ): WithStandardErrors<UserCreatedResponse | UserExistsResponse | InvalidUserResponse>; } ``` The emitter will generate a corresponding interface `Users` within the module `models/all/todo/index.js` in the output directory. ```ts /** An interface representing the operations defined in the 'Todo.Users' namespace. */ export interface Users<Context = unknown> { create( ctx: Context, user: User, ): Promise< | UserCreatedResponse | UserExistsResponse | InvalidUserResponse | Standard4XxResponse | Standard5XxResponse >; } ``` An object implementing this `Users` interface must be passed to the router when it is created. The `Context` type parameter represents the underlying protocol or framework-specific context that the service implementation may inspect. If you need to access the HTTP request or response objects directly in the implementation of the service methods, you must use the `HttpContext` type as the `Context` argument when implementing the service interface. Otherwise, it is safe to use the default `unknown` argument. ```ts import { HttpContext } from "../tsp-output/@typespec/http-server-js/helpers/router.js"; import { Users } from "../tsp-output/@typespec/http-server-js/models/all/todo/index.js"; export const users: Users<HttpContext> = { async create(ctx, user) { // Implementation }, }; ``` ### Models The emitter generates TypeScript interfaces that represent the model types used in the service operations. This allows the service implementation to interact with the data structures carried over the HTTP protocol in a type-safe manner. ### Operation functions While your code should never need to interact with these functions directly, the emitter generates a function per HTTP operation that handles the parsing and validation of the request contents. This allows the service implementation to be written in terms of ordinary TypeScript types and values rather than raw HTTP request and response objects. In general: - The Node.js HTTP server or Express.js application (your code) calls the router (generated code), which determines which service operation function (generated code) to call based on the route, method, and other HTTP metadata in the case of shared routes. - The operation function (generated code) deserializes the request body, query parameters, and headers into TypeScript types, and may perform request validation. - The operation function (generated code) calls the service implementation (your code) with the deserialized request data. - The service implementation (your code) returns a result or throws an error. - The operation function (generated code) responds to the HTTP request on your behalf, converting the result or error into HTTP response data.