The Fastify framework is written in vanilla JavaScript, and as such type definitions are not as easy to maintain; however, since version 2 and beyond, maintainers and contributors have put in a great effort to improve the types.
The type system was changed in Fastify version 3. The new type system introduces
generic constraining and defaulting, plus a new way to define schema types such
as a request body, querystring, and more! As the team works on improving
framework and type definition synergy, sometimes parts of the API will not be
typed or may be typed incorrectly. We encourage you to contribute to help us
fill in the gaps. Just make sure to read our
CONTRIBUTING.md
file before getting started to make sure things go smoothly!
The documentation in this section covers Fastify version 3.x typings
Plugins may or may not include typings. See Plugins for more information. We encourage users to send pull requests to improve typings support.
🚨 Don't forget to install @types/node
The best way to learn the Fastify type system is by example! The following four examples should cover the most common Fastify development cases. After the examples there is further, more detailed documentation for the type system.
This example will get you up and running with Fastify and TypeScript. It results in a blank http Fastify server.
- Create a new npm project, install Fastify, and install typescript & node.js types as peer dependencies:
npm init -y
npm i fastify
npm i -D typescript @types/node
- Add the following lines to the
"scripts"
section of thepackage.json
:
{
"scripts": {
"build": "tsc -p tsconfig.json",
"start": "node index.js"
}
}
- Initialize a TypeScript configuration file:
npx tsc --init
or use one of the recommended ones.
Note: Set target
property in tsconfig.json
to es2017
or greater to avoid
FastifyDeprecation warning.
- Create an
index.ts
file - this will contain the server code - Add the following code block to your file:
import fastify from 'fastify' const server = fastify() server.get('/ping', async (request, reply) => { return 'pong\n' }) server.listen({ port: 8080 }, (err, address) => { if (err) { console.error(err) process.exit(1) } console.log(`Server listening at ${address}`) })
- Run
npm run build
- this will compileindex.ts
intoindex.js
which can be executed using Node.js. If you run into any errors please open an issue in fastify/help - Run
npm run start
to run the Fastify server - You should see
Server listening at http://127.0.0.1:8080
in your console - Try out your server using
curl localhost:8080/ping
, it should returnpong
🏓
🎉 You now have a working Typescript Fastify server! This example demonstrates
the simplicity of the version 3.x type system. By default, the type system
assumes you are using an http
server. The later examples will demonstrate how
to create more complex servers such as https
and http2
, how to specify route
schemas, and more!
For more examples on initializing Fastify with TypeScript (such as enabling HTTP2) check out the detailed API section here
The type system heavily relies on generic properties to provide the most
accurate development experience. While some may find the overhead a bit
cumbersome, the tradeoff is worth it! This example will dive into implementing
generic types for route schemas and the dynamic properties located on the
route-level request
object.
-
If you did not complete the previous example, follow steps 1-4 to get set up.
-
Inside
index.ts
, define two interfacesIQuerystring
andIHeaders
:interface IQuerystring { username: string; password: string; } interface IHeaders { 'h-Custom': string; }
-
Using the two interfaces, define a new API route and pass them as generics. The shorthand route methods (i.e.
.get
) accept a generic objectRouteGenericInterface
containing five named properties:Body
,Querystring
,Params
,Headers
andReply
. The interfacesBody
,Querystring
,Params
andHeaders
will be passed down through the route method into the route method handlerrequest
instance and theReply
interface to thereply
instance.server.get<{ Querystring: IQuerystring, Headers: IHeaders }>('/auth', async (request, reply) => { const { username, password } = request.query const customerHeader = request.headers['h-Custom'] // do something with request data return `logged in!` })
-
Build and run the server code with
npm run build
andnpm run start
-
Query the api
curl localhost:8080/auth?username=admin&password=Password123!
And it should return back
logged in!
-
But wait there's more! The generic interfaces are also available inside route level hook methods. Modify the previous route by adding a
preValidation
hook:server.get<{ Querystring: IQuerystring, Headers: IHeaders }>('/auth', { preValidation: (request, reply, done) => { const { username, password } = request.query done(username !== 'admin' ? new Error('Must be admin') : undefined) // only validate `admin` account } }, async (request, reply) => { const customerHeader = request.headers['h-Custom'] // do something with request data return `logged in!` })
-
Build and run and query with the
username
query string option set to anything other thanadmin
. The API should now return a HTTP 500 error{"statusCode":500,"error":"Internal Server Error","message":"Must be admin"}
🎉 Good work, now you can define interfaces for each route and have strictly typed request and reply instances. Other parts of the Fastify type system rely on generic properties. Make sure to reference the detailed type system documentation below to learn more about what is available.
To validate your requests and responses you can use JSON Schema files. If you didn't know already, defining schemas for your Fastify routes can increase their throughput! Check out the Validation and Serialization documentation for more info.
Also it has the advantage to use the defined type within your handlers (including pre-validation, etc.).
Here are some options how to achieve this.
Fastify offers two packages wrapping json-schema-to-ts
and typebox
:
@fastify/type-provider-json-schema-to-ts
@fastify/type-provider-typebox
They simplify schema validation setup and you can read more about them in Type Providers page.
Below is how to setup schema validation using vanilla typebox
and
json-schema-to-ts
packages.
A useful library for building types and a schema at once is typebox along with fastify-type-provider-typebox. With typebox you define your schema within your code and use them directly as types or schemas as you need them.
When you want to use it for validation of some payload in a fastify route you can do it as follows:
-
Install
typebox
andfastify-type-provider-typebox
in your project.npm i @sinclair/typebox @fastify/type-provider-typebox
-
Define the schema you need with
Type
and create the respective type withStatic
.import { Static, Type } from '@sinclair/typebox' export const User = Type.Object({ name: Type.String(), mail: Type.Optional(Type.String({ format: 'email' })), }) export type UserType = Static<typeof User>
-
Use the defined type and schema during the definition of your route
import Fastify from 'fastify' import { TypeBoxTypeProvider } from '@fastify/type-provider-typebox' // ... const fastify = Fastify().withTypeProvider<TypeBoxTypeProvider>() app.post<{ Body: UserType, Reply: UserType }>( '/', { schema: { body: User, response: { 200: User }, }, }, (request, reply) => { // The `name` and `mail` types are automatically inferred const { name, mail } = request.body; reply.status(200).send({ name, mail }); } )
Note For Ajv version 7 and above is required to use the
ajvTypeBoxPlugin
:import Fastify from 'fastify' import { ajvTypeBoxPlugin, TypeBoxTypeProvider } from '@fastify/type-provider-typebox' const fastify = Fastify({ ajv: { plugins: [ajvTypeBoxPlugin] } }).withTypeProvider<TypeBoxTypeProvider>()
In the last example we used interfaces to define the types for the request querystring and headers. Many users will already be using JSON Schemas to define these properties, and luckily there is a way to transform existing JSON Schemas into TypeScript interfaces!
-
If you did not complete the 'Getting Started' example, go back and follow steps 1-4 first.
-
Install the
json-schema-to-typescript
module:npm i -D json-schema-to-typescript
-
Create a new folder called
schemas
and add two filesheaders.json
andquerystring.json
. Copy and paste the following schema definitions into the respective files:{ "title": "Headers Schema", "type": "object", "properties": { "h-Custom": { "type": "string" } }, "additionalProperties": false, "required": ["h-Custom"] }
{ "title": "Querystring Schema", "type": "object", "properties": { "username": { "type": "string" }, "password": { "type": "string" } }, "additionalProperties": false, "required": ["username", "password"] }
-
Add a
compile-schemas
script to the package.json:
{
"scripts": {
"compile-schemas": "json2ts -i schemas -o types"
}
}
json2ts
is a CLI utility included in json-schema-to-typescript
. schemas
is the input path, and types
is the output path.
5. Run npm run compile-schemas
. Two new files should have been created in the
types
directory.
6. Update index.ts
to have the following code:
import fastify from 'fastify'
// import json schemas as normal
import QuerystringSchema from './schemas/querystring.json'
import HeadersSchema from './schemas/headers.json'
// import the generated interfaces
import { QuerystringSchema as QuerystringSchemaInterface } from './types/querystring'
import { HeadersSchema as HeadersSchemaInterface } from './types/headers'
const server = fastify()
server.get<{
Querystring: QuerystringSchemaInterface,
Headers: HeadersSchemaInterface
}>('/auth', {
schema: {
querystring: QuerystringSchema,
headers: HeadersSchema
},
preValidation: (request, reply, done) => {
const { username, password } = request.query
done(username !== 'admin' ? new Error('Must be admin') : undefined)
}
// or if using async
// preValidation: async (request, reply) => {
// const { username, password } = request.query
// if (username !== "admin") throw new Error("Must be admin");
// }
}, async (request, reply) => {
const customerHeader = request.headers['h-Custom']
// do something with request data
return `logged in!`
})
server.route<{
Querystring: QuerystringSchemaInterface,
Headers: HeadersSchemaInterface
}>({
method: 'GET',
url: '/auth2',
schema: {
querystring: QuerystringSchema,
headers: HeadersSchema
},
preHandler: (request, reply, done) => {
const { username, password } = request.query
const customerHeader = request.headers['h-Custom']
done()
},
handler: (request, reply) => {
const { username, password } = request.query
const customerHeader = request.headers['h-Custom']
reply.status(200).send({username});
}
})
server.listen({ port: 8080 }, (err, address) => {
if (err) {
console.error(err)
process.exit(0)
}
console.log(`Server listening at ${address}`)
})
Pay special attention to the imports at the top of this file. It might seem redundant, but you need to import both the schema files and the generated interfaces.
Great work! Now you can make use of both JSON Schemas and TypeScript definitions.
If you do not want to generate types from your schemas, but want to use them directly from your code, you can use the package json-schema-to-ts.
You can install it as dev-dependency.
npm i -D json-schema-to-ts
In your code you can define your schema like a normal object. But be aware of making it const like explained in the docs of the module.
const todo = {
type: 'object',
properties: {
name: { type: 'string' },
description: { type: 'string' },
done: { type: 'boolean' },
},
required: ['name'],
} as const; // don't forget to use const !
With the provided type FromSchema
you can build a type from your schema and
use it in your handler.
import { FromSchema } from "json-schema-to-ts";
fastify.post<{ Body: FromSchema<typeof todo> }>(
'/todo',
{
schema: {
body: todo,
response: {
201: {
type: 'string',
},
},
}
},
async (request, reply): Promise<void> => {
/*
request.body has type
{
[x: string]: unknown;
description?: string;
done?: boolean;
name: string;
}
*/
request.body.name // will not throw type error
request.body.notthere // will throw type error
reply.status(201).send();
},
);
One of Fastify's most distinguishable features is its extensive plugin ecosystem. Plugin types are fully supported, and take advantage of the declaration merging pattern. This example is broken up into three parts: Creating a TypeScript Fastify Plugin, Creating Type Definitions for a Fastify Plugin, and Using a Fastify Plugin in a TypeScript Project.
- Initialize a new npm project and install required dependencies
npm init -y npm i fastify fastify-plugin npm i -D typescript @types/node
- Add a
build
script to the"scripts"
section and'index.d.ts'
to the"types"
section of thepackage.json
file:{ "types": "index.d.ts", "scripts": { "build": "tsc -p tsconfig.json" } }
- Initialize a TypeScript configuration file:
Once the file is generated, enable the
npx typescript --init
"declaration"
option in the"compilerOptions"
object.{ "compileOptions": { "declaration": true } }
- Create an
index.ts
file - this will contain the plugin code - Add the following code to
index.ts
import { FastifyPluginCallback, FastifyPluginAsync } from 'fastify' import fp from 'fastify-plugin' // using declaration merging, add your plugin props to the appropriate fastify interfaces // if prop type is defined here, the value will be typechecked when you call decorate{,Request,Reply} declare module 'fastify' { interface FastifyRequest { myPluginProp: string } interface FastifyReply { myPluginProp: number } } // define options export interface MyPluginOptions { myPluginOption: string } // define plugin using callbacks const myPluginCallback: FastifyPluginCallback<MyPluginOptions> = (fastify, options, done) => { fastify.decorateRequest('myPluginProp', 'super_secret_value') fastify.decorateReply('myPluginProp', options.myPluginOption) done() } // define plugin using promises const myPluginAsync: FastifyPluginAsync<MyPluginOptions> = async (fastify, options) => { fastify.decorateRequest('myPluginProp', 'super_secret_value') fastify.decorateReply('myPluginProp', options.myPluginOption) } // export plugin using fastify-plugin export default fp(myPluginCallback, '3.x') // or // export default fp(myPluginAsync, '3.x')
- Run
npm run build
to compile the plugin code and produce both a JavaScript source file and a type definition file. - With the plugin now complete you can [publish to npm] or use it locally.
You do not need to publish your plugin to npm to use it. You can include it in a Fastify project and reference it as you would any piece of code! As a TypeScript user, make sure the declaration override exists somewhere that will be included in your project compilation so the TypeScript interpreter can process it.
This plugin guide is for Fastify plugins written in JavaScript. The steps outlined in this example are for adding TypeScript support for users consuming your plugin.
- Initialize a new npm project and install required dependencies
npm init -y npm i fastify-plugin
- Create two files
index.js
andindex.d.ts
- Modify the package json to include these files under the
main
andtypes
properties (the name does not have to beindex
explicitly, but it is recommended the files have the same name):{ "main": "index.js", "types": "index.d.ts" }
- Open
index.js
and add the following code:// fastify-plugin is highly recommended for any plugin you write const fp = require('fastify-plugin') function myPlugin (instance, options, done) { // decorate the fastify instance with a custom function called myPluginFunc instance.decorate('myPluginFunc', (input) => { return input.toUpperCase() }) done() } module.exports = fp(myPlugin, { fastify: '3.x', name: 'my-plugin' // this is used by fastify-plugin to derive the property name })
- Open
index.d.ts
and add the following code:import { FastifyPlugin } from 'fastify' interface PluginOptions { //... } // Optionally, you can add any additional exports. // Here we are exporting the decorator we added. export interface myPluginFunc { (input: string): string } // Most importantly, use declaration merging to add the custom property to the Fastify type system declare module 'fastify' { interface FastifyInstance { myPluginFunc: myPluginFunc } } // fastify-plugin automatically adds named export, so be sure to add also this type // the variable name is derived from `options.name` property if `module.exports.myPlugin` is missing export const myPlugin: FastifyPlugin<PluginOptions> // fastify-plugin automatically adds `.default` property to the exported plugin. See the note below export default myPlugin
Note: fastify-plugin v2.3.0 and
newer, automatically adds .default
property and a named export to the exported
plugin. Be sure to export default
and export const myPlugin
in your typings
to provide the best developer experience. For a complete example you can check
out
@fastify/swagger.
With those files completed, the plugin is now ready to be consumed by any TypeScript project!
The Fastify plugin system enables developers to decorate the Fastify instance, and the request/reply instances. For more information check out this blog post on Declaration Merging and Generic Inheritance.
Using a Fastify plugin in TypeScript is just as easy as using one in JavaScript.
Import the plugin with import/from
and you're all set -- except there is one
exception users should be aware of.
Fastify plugins use declaration merging to modify existing Fastify type interfaces (check out the previous two examples for more details). Declaration merging is not very smart, meaning if the plugin type definition for a plugin is within the scope of the TypeScript interpreter, then the plugin types will be included regardless of if the plugin is being used or not. This is an unfortunate limitation of using TypeScript and is unavoidable as of right now.
However, there are a couple of suggestions to help improve this experience:
- Make sure the
no-unused-vars
rule is enabled in ESLint and any imported plugin are actually being loaded. - Use a module such as depcheck or npm-check to verify plugin dependencies are being used somewhere in your project.
Note that using require
will not load the type definitions properly and may
cause type errors.
TypeScript can only identify the types that are directly imported into code,
which means that you can use require inline with import on top. For example:
import 'plugin' // here will trigger the type augmentation.
fastify.register(require('plugin'))
import plugin from 'plugin' // here will trigger the type augmentation.
fastify.register(plugin)
Or even explicit config on tsconfig
{
"types": ["plugin"] // we force TypeScript to import the types
}
Vanilla JavaScript can use the published types to provide code completion (e.g. Intellisense) by following the TypeScript JSDoc Reference.
For example:
/** @type {import('fastify').FastifyPluginAsync<{ optionA: boolean, optionB: string }>} */
module.exports = async function (fastify, { optionA, optionB }) {
fastify.get('/look', () => 'at me');
}
This section is a detailed account of all the types available to you in Fastify version 3.x
All http
, https
, and http2
types are inferred from @types/node
Generics are documented by their default value as well as their constraint value(s). Read these articles for more information on TypeScript generics.
The Fastify API is powered by the fastify()
method. In JavaScript you would
import it using const fastify = require('fastify')
. In TypeScript it is
recommended to use the import/from
syntax instead so types can be resolved.
There are a couple supported import methods with the Fastify type system.
import fastify from 'fastify'
- Types are resolved but not accessible using dot notation
- Example:
import fastify from 'fastify' const f = fastify() f.listen({ port: 8080 }, () => { console.log('running') })
- Gain access to types with destructuring:
import fastify, { FastifyInstance } from 'fastify' const f: FastifyInstance = fastify() f.listen({ port: 8080 }, () => { console.log('running') })
- Destructuring also works for the main API method:
import { fastify, FastifyInstance } from 'fastify' const f: FastifyInstance = fastify() f.listen({ port: 8080 }, () => { console.log('running') })
import * as Fastify from 'fastify'
- Types are resolved and accessible using dot notation
- Calling the main Fastify API method requires a slightly different syntax (see example)
- Example:
import * as Fastify from 'fastify' const f: Fastify.FastifyInstance = Fastify.fastify() f.listen({ port: 8080 }, () => { console.log('running') })
const fastify = require('fastify')
- This syntax is valid and will import fastify as expected; however, types will not be resolved
- Example:
const fastify = require('fastify') const f = fastify() f.listen({ port: 8080 }, () => { console.log('running') })
- Destructuring is supported and will resolve types properly
const { fastify } = require('fastify') const f = fastify() f.listen({ port: 8080 }, () => { console.log('running') })
Many type definitions share the same generic parameters; they are all documented, in detail, within this section.
Most definitions depend on @node/types
modules http
, https
, and http2
Underlying Node.js server type
Default: http.Server
Constraints: http.Server
, https.Server
, http2.Http2Server
,
http2.Http2SecureServer
Enforces generic parameters: RawRequest
,
RawReply
Underlying Node.js request type
Default: RawRequestDefaultExpression
Constraints: http.IncomingMessage
, http2.Http2ServerRequest
Enforced by: RawServer
Underlying Node.js response type
Default: RawReplyDefaultExpression
Constraints: http.ServerResponse
, http2.Http2ServerResponse
Enforced by: RawServer
Fastify logging utility
Default: FastifyLoggerOptions
Enforced by: RawServer
A generic parameter for the content-type-parser methods.
Constraints: string | Buffer
fastify<RawServer, RawRequest, RawReply, Logger>(opts?: FastifyServerOptions): FastifyInstance
The main Fastify API method. By default creates an HTTP server. Utilizing
discriminant unions and overload methods, the type system will automatically
infer which type of server (http, https, or http2) is being created purely based
on the options based to the method (see the examples below for more
information). It also supports an extensive generic type system to allow the
user to extend the underlying Node.js Server, Request, and Reply objects.
Additionally, the Logger
generic exists for custom log types. See the examples
and generic breakdown below for more information.
No need to specify the Server
generic as the type system defaults to HTTP.
import fastify from 'fastify'
const server = fastify()
Check out the Learn By Example - Getting Started example for a more detailed http server walkthrough.
- Create the following imports from
@types/node
andfastify
import fs from 'fs' import path from 'path' import fastify from 'fastify'
- Follow the steps in this official Node.js https server
guide
to create the
key.pem
andcert.pem
files - Instantiate a Fastify https server and add a route:
const server = fastify({ https: { key: fs.readFileSync(path.join(__dirname, 'key.pem')), cert: fs.readFileSync(path.join(__dirname, 'cert.pem')) } }) server.get('/', async function (request, reply) { return { hello: 'world' } }) server.listen({ port: 8080 }, (err, address) => { if (err) { console.error(err) process.exit(0) } console.log(`Server listening at ${address}`) })
- Build and run! Test your server out by querying with:
curl -k https://localhost:8080
There are two types of HTTP2 server types, insecure and secure. Both require
specifying the http2
property as true
in the options
object. The https
property is used for creating a secure http2 server; omitting the https
property will create an insecure http2 server.
const insecureServer = fastify({ http2: true })
const secureServer = fastify({
http2: true,
https: {} // use the `key.pem` and `cert.pem` files from the https section
})
For more details on using HTTP2 check out the Fastify HTTP2 documentation page.
Not only can you specify the server type, but also the request and reply types. Thus, allowing you to specify special properties, methods, and more! When specified at server instantiation, the custom type becomes available on all further instances of the custom type.
import fastify from 'fastify'
import http from 'http'
interface customRequest extends http.IncomingMessage {
mySpecialProp: string
}
const server = fastify<http.Server, customRequest>()
server.get('/', async (request, reply) => {
const someValue = request.raw.mySpecialProp // TS knows this is a string, because of the `customRequest` interface
return someValue.toUpperCase()
})
Fastify uses Pino logging library under the hood. Since
pino@7
, all of it's properties can be configured via logger
field when
constructing Fastify's instance. If properties you need aren't exposed, please
open an Issue to Pino
or pass a
preconfigured external instance of Pino (or any other compatible logger) as
temporary fix to Fastify via the same field. This allows creating custom
serializers as well, see the Logging documentation for more info.
import fastify from 'fastify'
const server = fastify({
logger: {
level: 'info',
redact: ['x-userinfo'],
messageKey: 'message'
}
})
server.get('/', async (request, reply) => {
server.log.info('log message')
return 'another message'
})
Union type of: 'DELETE' | 'GET' | 'HEAD' | 'PATCH' | 'POST' | 'PUT' | 'OPTIONS'
Dependant on @types/node
modules http
, https
, http2
Union type of: http.Server | https.Server | http2.Http2Server | http2.Http2SecureServer
Dependant on @types/node
modules http
Type alias for http.Server
An interface of properties used in the instantiation of the Fastify server. Is
used in the main fastify()
method. The RawServer
and Logger
generic parameters are passed down through that method.
See the main fastify method type definition section for examples on instantiating a Fastify server with TypeScript.
fastify.FastifyInstance<RawServer, RawRequest, RequestGeneric, Logger>
Interface that represents the Fastify server object. This is the returned server
instance from the fastify()
method. This type is an interface so it
can be extended via declaration
merging
if your code makes use of the decorate
method.
Through the use of generic cascading, all methods attached to the instance inherit the generic properties from instantiation. This means that by specifying the server, request, or reply types, all methods will know how to type those objects.
Check out the main Learn by Example section for detailed guides, or the more simplified fastify method examples for additional details on this interface.
fastify.FastifyRequest<RequestGeneric, RawServer, RawRequest>
This interface contains properties of Fastify request object. The properties
added here disregard what kind of request object (http vs http2) and disregard
what route level it is serving; thus calling request.body
inside a GET request
will not throw an error (but good luck sending a GET request with a body 😉).
If you need to add custom properties to the FastifyRequest
object (such as
when using the [decorateRequest
][DecorateRequest] method) you need to use
declaration merging on this interface.
A basic example is provided in the FastifyRequest
section.
For a more detailed example check out the Learn By Example section:
Plugins
import fastify from 'fastify'
const server = fastify()
server.decorateRequest('someProp', 'hello!')
server.get('/', async (request, reply) => {
const { someProp } = request // need to use declaration merging to add this prop to the request interface
return someProp
})
// this declaration must be in scope of the typescript interpreter to work
declare module 'fastify' {
interface FastifyRequest { // you must reference the interface and not the type
someProp: string
}
}
// Or you can type your request using
type CustomRequest = FastifyRequest<{
Body: { test: boolean };
}>
server.get('/typedRequest', async (request: CustomRequest, reply: FastifyReply) => {
return request.body.test
})
Fastify request objects have four dynamic properties: body
, params
, query
,
and headers
. Their respective types are assignable through this interface. It
is a named property interface enabling the developer to ignore the properties
they do not want to specify. All omitted properties are defaulted to unknown
.
The corresponding property names are: Body
, Querystring
, Params
,
Headers
.
import fastify, { RequestGenericInterface } from 'fastify'
const server = fastify()
interface requestGeneric extends RequestGenericInterface {
Querystring: {
name: string
}
}
server.get<requestGeneric>('/', async (request, reply) => {
const { name } = request.query // the name prop now exists on the query prop
return name.toUpperCase()
})
If you want to see a detailed example of using this interface check out the Learn by Example section: JSON Schema.
fastify.RawRequestDefaultExpression<RawServer>
Dependant on @types/node
modules http
, https
, http2
Generic parameter RawServer
defaults to RawServerDefault
If RawServer
is of type http.Server
or https.Server
, then this expression
returns http.IncomingMessage
, otherwise, it returns
http2.Http2ServerRequest
.
import http from 'http'
import http2 from 'http2'
import { RawRequestDefaultExpression } from 'fastify'
RawRequestDefaultExpression<http.Server> // -> http.IncomingMessage
RawRequestDefaultExpression<http2.Http2Server> // -> http2.Http2ServerRequest
fastify.FastifyReply<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>
This interface contains the custom properties that Fastify adds to the standard Node.js reply object. The properties added here disregard what kind of reply object (http vs http2).
If you need to add custom properties to the FastifyReply object (such as when
using the decorateReply
method) you need to use declaration merging on this
interface.
A basic example is provided in the FastifyReply
section. For a
more detailed example check out the Learn By Example section:
Plugins
import fastify from 'fastify'
const server = fastify()
server.decorateReply('someProp', 'world')
server.get('/', async (request, reply) => {
const { someProp } = reply // need to use declaration merging to add this prop to the reply interface
return someProp
})
// this declaration must be in scope of the typescript interpreter to work
declare module 'fastify' {
interface FastifyReply { // you must reference the interface and not the type
someProp: string
}
}
fastify.RawReplyDefaultExpression<RawServer>
Dependant on @types/node
modules http
, https
, http2
Generic parameter RawServer
defaults to RawServerDefault
If RawServer
is of type http.Server
or https.Server
, then this expression
returns http.ServerResponse
, otherwise, it returns
http2.Http2ServerResponse
.
import http from 'http'
import http2 from 'http2'
import { RawReplyDefaultExpression } from 'fastify'
RawReplyDefaultExpression<http.Server> // -> http.ServerResponse
RawReplyDefaultExpression<http2.Http2Server> // -> http2.Http2ServerResponse
Fastify allows the user to extend its functionalities with plugins. A plugin can
be a set of routes, a server decorator or whatever. To activate plugins, use the
fastify.register()
method.
When creating plugins for Fastify, it is recommended to use the fastify-plugin
module. Additionally, there is a guide to creating plugins with TypeScript and
Fastify available in the Learn by Example, Plugins section.
fastify.FastifyPluginCallback<Options>
Interface method definition used within the
fastify.register()
method.
fastify.FastifyPluginAsync<Options>
Interface method definition used within the
fastify.register()
method.
fastify.FastifyPlugin<Options>
Interface method definition used within the
fastify.register()
method. Document deprecated in favor of
FastifyPluginCallback
and FastifyPluginAsync
since general FastifyPlugin
doesn't properly infer types for async functions.
A loosely typed object used to constrain the options
parameter of
fastify.register()
to an object. When creating a plugin,
define its options as an extension of this interface (interface MyPluginOptions extends FastifyPluginOptions
) so they can be passed to the register method.
fastify.FastifyRegister(plugin: FastifyPluginCallback, opts: FastifyRegisterOptions)
fastify.FastifyRegister(plugin: FastifyPluginAsync, opts: FastifyRegisterOptions)
fastify.FastifyRegister(plugin: FastifyPlugin, opts: FastifyRegisterOptions)
This type interface specifies the type for the
fastify.register()
method. The type interface returns
a function signature with an underlying generic Options
which is defaulted to
FastifyPluginOptions. It infers this generic from the
FastifyPlugin parameter when calling this function so there is no need to
specify the underlying generic. The options parameter is the intersection of the
plugin's options and two additional optional properties: prefix: string
and
logLevel
: LogLevel.
Below is an example of the options inference in action:
const server = fastify()
const plugin: FastifyPlugin<{
option1: string;
option2: boolean;
}> = function (instance, opts, done) { }
fastify().register(plugin, {}) // Error - options object is missing required properties
fastify().register(plugin, { option1: '', option2: true }) // OK - options object contains required properties
See the Learn By Example, Plugins section for more detailed examples of creating TypeScript plugins in Fastify.
This type is the intersection of the Options
generic and a non-exported
interface RegisterOptions
that specifies two optional properties: prefix: string
and logLevel
: LogLevel. This type can also be specified as
a function that returns the previously described intersection.
Check out the Specifying Logger Types example for more details on specifying a custom logger.
fastify.FastifyLoggerOptions<RawServer, RawRequest, RawReply>
An interface definition for the internal Fastify logger. It is emulative of the Pino.js logger. When enabled through server options, use it following the general logger documentation.
An overload function interface that implements the two ways Fastify calls log methods. This interface is passed to all associated log level properties on the FastifyLoggerOptions object.
Union type of: 'info' | 'error' | 'debug' | 'fatal' | 'warn' | 'trace'
The context type definition is similar to the other highly dynamic pieces of the type system. Route context is available in the route handler method.
An interface with a single required property config
that is set by default to
unknown
. Can be specified either using a generic or an overload.
This type definition is potentially incomplete. If you are using it and can provide more details on how to improve the definition, we strongly encourage you to open an issue in the main fastify/fastify repository. Thank you in advanced!
One of the core principles in Fastify is its routing capabilities. Most of the
types defined in this section are used under-the-hood by the Fastify instance
.route
and .get/.post/.etc
methods.
fastify.RouteHandlerMethod<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>
A type declaration for the route handler methods. Has two arguments, request
and reply
which are typed by FastifyRequest
and FastifyReply
respectfully.
The generics parameters are passed through to these arguments. The method
returns either void
or Promise<any>
for synchronous and asynchronous
handlers respectfully.
fastify.RouteOptions<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>
An interface that extends RouteShorthandOptions and adds the following three required properties:
method
which corresponds to a singular HTTPMethod or a list of HTTPMethodsurl
a string for the routehandler
the route handler method, see [RouteHandlerMethod][] for more details
fastify.RouteShorthandMethod<RawServer, RawRequest, RawReply>
An overloaded function interface for three kinds of shorthand route methods to
be used in conjunction with the .get/.post/.etc
methods.
fastify.RouteShorthandOptions<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>
An interface that covers all of the base options for a route. Each property on this interface is optional, and it serves as the base for the RouteOptions and RouteShorthandOptionsWithHandler interfaces.
fastify.RouteShorthandOptionsWithHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>
This interface adds a single, required property to the RouteShorthandOptions
interface handler
which is of type RouteHandlerMethod
A generic type that is either a string
or Buffer
fastify.FastifyBodyParser<RawBody, RawServer, RawRequest>
A function type definition for specifying a body parser method. Use the
RawBody
generic to specify the type of the body being parsed.
fastify.FastifyContentTypeParser<RawServer, RawRequest>
A function type definition for specifying a body parser method. Content is typed
via the RawRequest
generic.
fastify.AddContentTypeParser<RawServer, RawRequest>
An overloaded interface function definition for the addContentTypeParser
method. If parseAs
is passed to the opts
parameter, the definition uses
[FastifyBodyParser][] for the parser
parameter; otherwise, it uses
[FastifyContentTypeParser][].
A method for checking the existence of a type parser of a certain content type
FastifyError is a custom error object that includes status code and validation results.
It extends the Node.js Error
type, and adds two additional, optional
properties: statusCode: number
and validation: ValidationResult[]
.
The route validation internally relies upon Ajv, which is a high-performance JSON schema validator.
This interface is passed to instance of FastifyError.
fastify.onRequestHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, done: (err?: FastifyError) => void): Promise<unknown> | void
onRequest
is the first hook to be executed in the request lifecycle. There was
no previous hook, the next hook will be preParsing
.
Notice: in the onRequest
hook, request.body will always be null, because the
body parsing happens before the preHandler
hook.
fastify.preParsingHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, done: (err?: FastifyError) => void): Promise<unknown> | void
preParsing
is the second hook to be executed in the request lifecycle. The
previous hook was onRequest
, the next hook will be preValidation
.
Notice: in the preParsing
hook, request.body will always be null, because the
body parsing happens before the preValidation
hook.
Notice: you should also add receivedEncodedLength
property to the returned
stream. This property is used to correctly match the request payload with the
Content-Length
header value. Ideally, this property should be updated on each
received chunk.
fastify.preValidationHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, done: (err?: FastifyError) => void): Promise<unknown> | void
preValidation
is the third hook to be executed in the request lifecycle. The
previous hook was preParsing
, the next hook will be preHandler
.
fastify.preHandlerHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, done: (err?: FastifyError) => void): Promise<unknown> | void
preHandler
is the fourth hook to be executed in the request lifecycle. The
previous hook was preValidation
, the next hook will be preSerialization
.
fastify.preSerializationHookHandler<PreSerializationPayload, RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, payload: PreSerializationPayload, done: (err: FastifyError | null, res?: unknown) => void): Promise<unknown> | void
preSerialization
is the fifth hook to be executed in the request lifecycle.
The previous hook was preHandler
, the next hook will be onSend
.
Note: the hook is NOT called if the payload is a string, a Buffer, a stream or null.
fastify.onSendHookHandler<OnSendPayload, RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, payload: OnSendPayload, done: (err: FastifyError | null, res?: unknown) => void): Promise<unknown> | void
You can change the payload with the onSend
hook. It is the sixth hook to be
executed in the request lifecycle. The previous hook was preSerialization
, the
next hook will be onResponse
.
Note: If you change the payload, you may only change it to a string, a Buffer, a stream, or null.
fastify.onResponseHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, done: (err?: FastifyError) => void): Promise<unknown> | void
onResponse
is the seventh and last hook in the request hook lifecycle. The
previous hook was onSend
, there is no next hook.
The onResponse hook is executed when a response has been sent, so you will not be able to send more data to the client. It can however be useful for sending data to external services, for example to gather statistics.
fastify.onErrorHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(request: FastifyRequest, reply: FastifyReply, error: FastifyError, done: () => void): Promise<unknown> | void
This hook is useful if you need to do some custom error logging or add some specific header in case of error.
It is not intended for changing the error, and calling reply.send will throw an exception.
This hook will be executed only after the customErrorHandler has been executed, and only if the customErrorHandler sends an error back to the user (Note that the default customErrorHandler always sends the error back to the user).
Notice: unlike the other hooks, pass an error to the done function is not supported.
fastify.onRouteHookHandler<RawServer, RawRequest, RawReply, RequestGeneric, ContextConfig>(opts: RouteOptions & { path: string; prefix: string }): Promise<unknown> | void
Triggered when a new route is registered. Listeners are passed a routeOptions object as the sole parameter. The interface is synchronous, and, as such, the listener does not get passed a callback
fastify.onRegisterHookHandler<RawServer, RawRequest, RawReply, Logger>(instance: FastifyInstance, done: (err?: FastifyError) => void): Promise<unknown> | void
Triggered when a new plugin is registered and a new encapsulation context is created. The hook will be executed before the registered code.
This hook can be useful if you are developing a plugin that needs to know when a plugin context is formed, and you want to operate in that specific context.
Note: This hook will not be called if a plugin is wrapped inside fastify-plugin.
fastify.onCloseHookHandler<RawServer, RawRequest, RawReply, Logger>(instance: FastifyInstance, done: (err?: FastifyError) => void): Promise<unknown> | void
Triggered when fastify.close() is invoked to stop the server. It is useful when plugins need a "shutdown" event, for example to close an open connection to a database.