Service Worker API

Note: This feature is available in Web Workers.

Service workers essentially act as proxy servers that sit between web applications, the browser, and the network (when available). They are intended, among other things, to enable the creation of effective offline experiences, intercept network requests, and take appropriate action based on whether the network is available, and update assets residing on the server. They will also allow access to push notifications and background sync APIs.

Service worker concepts and usage

A service worker is an event-driven worker registered against an origin and a path. It takes the form of a JavaScript file that can control the web page/site that it is associated with, intercepting and modifying navigation and resource requests, and caching resources in a very granular fashion to give you complete control over how your app behaves in certain situations (the most obvious one being when the network is not available).

Service workers run in a worker context: they therefore have no DOM access and run on a different thread to the main JavaScript that powers your app. They are non-blocking and designed to be fully asynchronous. As a consequence, APIs such as synchronous XHR and Web Storage can't be used inside a service worker.

Service workers can't import JavaScript modules dynamically, and import() will throw if it is called in a service worker global scope. Static imports using the import statement are allowed.

Service workers only run over HTTPS, for security reasons. Most significantly, HTTP connections are susceptible to malicious code injection by man in the middle attacks, and such attacks could be worse if allowed access to these powerful APIs. In Firefox, service worker APIs are also hidden and cannot be used when the user is in private browsing mode.

Note: On Firefox, for testing you can run service workers over HTTP (insecurely); simply check the Enable Service Workers over HTTP (when toolbox is open) option in the Firefox Devtools options/gear menu.

Note: Unlike previous attempts in this area such as AppCache, service workers don't make assumptions about what you are trying to do, but then break when those assumptions are not exactly right. Instead, service workers give you much more granular control.

Note: Service workers make heavy use of promises, as generally they will wait for responses to come through, after which they will respond with a success or failure action. The promises architecture is ideal for this.

Registration

A service worker is first registered using the ServiceWorkerContainer.register() method. If successful, your service worker will be downloaded to the client and attempt installation/activation (see below) for URLs accessed by the user inside the whole origin, or a subset specified by you.

Download, install and activate

At this point, your service worker will observe the following lifecycle:

  1. Download
  2. Install
  3. Activate

The service worker is immediately downloaded when a user first accesses a service worker–controlled site/page.

After that, it is updated when:

  • A navigation to an in-scope page occurs.
  • An event is fired on the service worker and it hasn't been downloaded in the last 24 hours.

Installation is attempted when the downloaded file is found to be new — either different to an existing service worker (byte-wise compared), or the first service worker encountered for this page/site.

If this is the first time a service worker has been made available, installation is attempted, then after a successful installation, it is activated.

If there is an existing service worker available, the new version is installed in the background, but not yet activated — at this point it is called the worker in waiting. It is only activated when there are no longer any pages loaded that are still using the old service worker. As soon as there are no more pages to be loaded, the new service worker activates (becoming the active worker). Activation can happen sooner using ServiceWorkerGlobalScope.skipWaiting() and existing pages can be claimed by the active worker using Clients.claim().

You can listen for the install event; a standard action is to prepare your service worker for usage when this fires, for example by creating a cache using the built-in storage API, and placing assets inside it that you'll want for running your app offline.

There is also an activate event. The point where this event fires is generally a good time to clean up old caches and other things associated with the previous version of your service worker.

Your service worker can respond to requests using the FetchEvent event. You can modify the response to these requests in any way you want, using the FetchEvent.respondWith() method.

Note: Because install/activate events could take a while to complete, the service worker spec provides a waitUntil() method. Once it is called on install or activate events with a promise, functional events such as fetch and push will wait until the promise is successfully resolved.

For a complete tutorial to show how to build up your first basic example, read Using Service Workers.

Using static routing to control how resources are fetched

Service workers can incur an unnecessary performance cost — when a page is loaded for the first time in a while, the browser has to wait for the service worker to start up and run to know what content to load and whether it should come from a cache or the network.

If you already know ahead of time where certain content should be fetched from, you can bypass the service worker altogether and fetch resources immediately. The InstallEvent.addRoutes() method can be used to implement this use case and more.

Other use case ideas

Service workers are also intended to be used for such things as:

  • Background data synchronization.
  • Responding to resource requests from other origins.
  • Receiving centralized updates to expensive-to-calculate data such as geolocation or gyroscope, so multiple pages can make use of one set of data.
  • Client-side compiling and dependency management of CoffeeScript, less, CJS/AMD modules, etc. for development purposes.
  • Hooks for background services.
  • Custom templating based on certain URL patterns.
  • Performance enhancements, for example, pre-fetching resources that the user is likely to need soon, such as the next few pictures in a photo album.
  • API mocking.

In the future, service workers will be able to do several other useful things for the web platform that will bring it closer to native app viability. Interestingly, other specifications can and will start to make use of the service worker context, for example:

  • Background synchronization: Start up a service worker even when no users are at the site, so caches can be updated, etc.
  • Reacting to push messages: Start up a service worker to send users a message to tell them new content is available.
  • Reacting to a particular time & date.
  • Entering a geo-fence.

Interfaces

Cache

Represents the storage for Request / Response object pairs that are cached as part of the ServiceWorker life cycle.

CacheStorage

Represents the storage for Cache objects. It provides a master directory of all the named caches that a ServiceWorker can access, and maintains a mapping of string names to corresponding Cache objects.

Client

Represents the scope of a service worker client. A service worker client is either a document in a browser context or a SharedWorker, which is controlled by an active worker.

Clients

Represents a container for a list of Client objects; the main way to access the active service worker clients at the current origin.

ExtendableEvent

Extends the lifetime of the install and activate events dispatched on the ServiceWorkerGlobalScope, as part of the service worker lifecycle. This ensures that any functional events (like FetchEvent) are not dispatched to the ServiceWorker, until it upgrades database schemas, and deletes outdated cache entries, etc.

ExtendableMessageEvent

The event object of a message event fired on a service worker (when a channel message is received on the ServiceWorkerGlobalScope from another context) — extends the lifetime of such events.

FetchEvent

The parameter passed into the onfetch handler, FetchEvent represents a fetch action that is dispatched on the ServiceWorkerGlobalScope of a ServiceWorker. It contains information about the request and resulting response, and provides the FetchEvent.respondWith() method, which allows us to provide an arbitrary response back to the controlled page.

InstallEvent

The parameter passed into an install event handler function, the InstallEvent interface represents an install action that is dispatched on the ServiceWorkerGlobalScope of a ServiceWorker. As a child of ExtendableEvent, it ensures that functional events such as FetchEvent are not dispatched during installation.

Provides methods for managing the preloading of resources with a service worker.

ServiceWorker

Represents a service worker. Multiple browsing contexts (e.g. pages, workers, etc.) can be associated with the same ServiceWorker object.

ServiceWorkerContainer

Provides an object representing the service worker as an overall unit in the network ecosystem, including facilities to register, unregister, and update service workers, and access the state of service workers and their registrations.

ServiceWorkerGlobalScope

Represents the global execution context of a service worker.

ServiceWorkerRegistration

Represents a service worker registration.

WindowClient

Represents the scope of a service worker client that is a document in a browser context, controlled by an active worker. This is a special type of Client object, with some additional methods and properties available.

Extensions to other interfaces

Window.caches and WorkerGlobalScope.caches

Returns the CacheStorage object associated with the current context.

Returns a ServiceWorkerContainer object, which provides access to registration, removal, upgrade, and communication with the ServiceWorker objects for the associated document.

Specifications

Specification
Service Workers

See also