Request handlers are a fundamental building block of Boltzmann applications. They are functions which you provide to Boltzmann to handle incoming HTTP requests.
This document will cover how to write handler functions, how to control request routing, how handler responses are interpreted, and how to control these behaviors using attributes on your exported functions.
What is a Request Handler?
A request handler is any function exported from handlers.js
(or
handlers/index.js
) that has a .route
property. A request handler is
called with a Context
object when an incoming HTTP request matches against
its .route
attribute.
A TypeScript definition of the types involved is included below. Don't worry if you're not comfortable reading this syntax! We'll cover each of the types below in natural language in this document.
class Context {
// Contents covered in reference doc.
}
const HEADERS = Symbol.for('headers')
const STATUS = Symbol.for('status')
type UserResponse = {[STATUS]?: number, [HEADERS]?: {[key: string]: string}} &
(string | AsyncIterable<Buffer | string> | Buffer | Object);
type Handler = {
route?: String,
method?: String,
version?: String,
middleware?: Array<Function | [Function, any...]>
} & (context: Context, ...args: any[]) => UserResponse | Promise<UserResponse>;
Context
When Boltzmann receives an HTTP request, it wraps the Node.JS request and response
objects in a Context
instance. The Context
object provides useful information about
the request:
- The request headers & method
- The matched URL route parameters
- A parsed URL object
- A mechanism for content-type negotiation
- Clients enabled by flags, like
postgresClient
orredisClient
- Cookie support
- Body parsing support
In short, it contains all relevant information about the current request.
Additionally, it is intended for extension: you are expected to attach your own
clients to the Context
using middleware, which we'll cover in the next chapter.
For more on the specific properties of the Context
object, see the reference
documentation.
Request handlers are responsible for mapping incoming request Context
to desired
response data. But how does Boltzmann know which handler to call for a given HTTP
request?
Routing
Your exported handlers are mounted to an internal-to-Boltzmann find-my-way
router based on their .route
attribute:
// handlers.js
module.exports = {
greeting
}
greeting.route = 'GET /hello'
function greeting (context) {
return `hello world!`
}
This handler will fire whenever the server receives a GET
request for /hello
, and
it will return the plain text string hello world!
The router is capable of matching against provided parameters, as well. For
example, to handle requests like GET /hello/world
or GET /hello/mars
with a
single handler, you might write something like the following.
// handlers.js
module.exports = {
greeting
}
greeting.route = 'GET /hello/:subject'
function greeting (context) {
return `hello ${context.params.subject}!`
}
The portion of the path that matched :subject
will be available as
context.params.subject
.
find-my-way
supports many different parameter behaviors:
- You can define multiple params in a path:
/:foo-:bar
- You can include regexen as part of the parameter definition:
/:foo(\\d+)
- You can specify wildcard params:
/*
, which will be available atcontext.params['*']
find-my-way
has excellent documentation.
Handling multiple methods with a single handler
If you wish to install a handler for multiple methods, you can split the route definition like so:
greeting.method = ['GET', 'POST']
greeting.route = '/hello/:subject'
function greeting (context) {
return `hello ${context.params.subject}!`
}
.route = 'GET /foo'
is shorthand for .route = '/foo'; .method = ['GET'];
.
Handling different versions of the same route
Over the course of time, your application might update the functionality of a given
handler. In order to support both the old behavior and the new behavior, you can
version your APIs using the .version
attribute:
LOUD_GREETING.route = 'GET /hello/:subject'
LOUD_GREETING.version = '2.0.0'
function LOUD_GREETING (context) {
return `hello ${context.params.subject}!`.toUpperCase()
}
greeting.route = 'GET /hello/:subject'
function greeting (context) {
return `hello ${context.params.subject}!`
}
Boltzmann will examine the incoming Accept-Version
request header in order to
determine which handler to dispatch the request to. Clients may specify the header in
semver format. For example, you might have handlers for versions 1.0.0
, 1.2.0
, and
2.0.0
. A client could then request 1.x
, ^1.2.0
, or 2.0.0
and expect to be routed
to the appropriate version.
For more information on route versioning, see the find-my-way
docs on versioning.
Responses
As we stated before, handlers are responsible for mapping your internal application semantics -- the types and error codes your business logic is implemented in terms of -- into HTTP semantics. Boltzmann is here to lend a helping hand by providing useful defaults for common JavaScript control flow semantics and types.
By default, returning a value from a handler will create a HTTP 200 OK
response. If your handler returns undefined
, Boltzmann will generate a 204 No Content
response. If your handler throws an error, Boltzmann will map that
to a 500 Internal Server Error
response by default.
All of this behavior can be configured using global Symbols. Boltzmann respects the following symbols on any returned or thrown value:
Symbol.for('status')
: Sets the outgoing HTTP response status code.Symbol.for('headers')
: Sets the HTTP response headers.Symbol.for('template')
: If the--templates
flag is enabled, sets the template used for rendering.
Beyond control flow mapping, Boltzmann casts different return types into HTTP response bodies with appropriate headers:
- Strings become
Buffer
instances containing UTF8 data. - Node.JS
ReadableStream
objects will be treated asapplication/octet-stream
data unless otherwise specified. - JavaScript objects and class instances will be stringified and returned as
application/json
data. Note: this invokes thetoJSON
method on all objects in the tree, so you can control the serialized representation of class instances you return. undefined
will become an emptyBuffer
and treated as a204 No Content
.
You may use Object.assign
to decorate your responses with this metadata, or provide your own classes:
create.route = 'POST /things'
async function create(context) {
const myThing = await context.thingFactory.createThing()
return Object.assign(thing, {
[Symbol.for('status')]: 201
})
}
class ThingNotFound extends Error {
[Symbol.for('status')] = 404
}
create.route = 'DELETE /things/:id'
async function destroy(context) {
try {
await context.thingFactory.deleteThing(context.params.id)
// 204 on success by returning nothing at all!
} catch (err) {
// Map internal application semantics to HTTP semantics:
if (err.code === 'NO_SUCH_THING') {
throw new ThingNotFound(`No thing by that id: ${context.params.id}`)
}
throw err
}
}
Next Steps
In this chapter, we defined the role handlers play in your application, how they are routed and dispatched, what information they receive, and how to control their output. In the next chapter, we'll cover middleware, which allows you to wrap all (or a subset of) your handlers with additional behavior -- think of them as higher-order handlers!