search
element with form functionality — Last Updated 1 December 2021This section is non-normative.
Worklets are a piece of specification infrastructure which can be used for running scripts independent of the main JavaScript execution environment, while not requiring any particular implementation model.
The worklet infrastructure specified here cannot be used directly by web developers. Instead, other specifications build upon it to create directly-usable worklet types, specialized for running in particular parts of the browser implementation pipeline.
This section is non-normative.
Allowing extension points to rendering, or other sensitive parts of the implementation pipeline
such as audio output, is difficult. If extension points were done with full access to the APIs
available on Window
, engines would need to abandon previously-held assumptions for
what could happen in the middle of those phases. For example, during the layout phase, rendering
engines assume that no DOM will be modified.
Additionally, defining extension points in the Window
environment would restrict
user agents to performing work in the same thread as the Window
object. (Unless
implementations added complex, high-overhead infrastructure to allow thread-safe APIs, as well
as thread-joining guarantees.)
Worklets are designed to allow extension points, while keeping guarantees that user agents
currently rely on. This is done through new global environments, based on subclasses of
WorkletGlobalScope
.
Worklets are similar to web workers. However, they:
Are thread-agnostic. That is, they are not designed to run on a dedicated separate thread, like each worker is. Implementations can run worklets wherever they choose (including on the main thread).
Are able to have multiple duplicate instances of the global scope created, for the purpose of parallelism.
Do not use an event-based API. Instead, classes are registered on the global scope, whose methods are invoked by the user agent.
Have a reduced API surface on the global scope.
Have a lifetime for their global object which is defined by other specifications, often in an implementation-defined manner.
As worklets have relatively high overhead, they are best used sparingly. Due to this, a given
WorkletGlobalScope
is expected to be shared between multiple separate scripts. (This
is similar to how a single Window
is shared between multiple separate scripts.)
Worklets are a general technology that serve different use cases. Some worklets, such as those defined in CSS Painting API, provide extension points intended for stateless, idempotent, and short-running computations, which have special considerations as described in the next couple of sections. Others, such as those defined in Web Audio API, are used for stateful, long-running operations. [CSSPAINT] [WEBAUDIO]
Some specifications which use worklets are intended to allow user agents to parallelize work over multiple threads, or to move work between threads as required. In these specifications, user agents might invoke methods on a web-developer-provided class in an implementation-defined order.
As a result of this, to prevent interoperability issues, authors who register classes on such
WorkletGlobalScope
s should make their code idempotent. That is, a method or set of
methods on the class should produce the same output given a particular input.
This specification uses the following techniques in order to encourage authors to write code in an idempotent way:
No reference to the global object is available (i.e., there is no counterpart to self
on WorkletGlobalScope
).
Although this was the intention when worklets were first specified, the
introduction of globalThis
has made it no longer true. See issue #6059 for more discussion.
Code is loaded as a module script, which results in the code being executed
in strict mode and with no shared this
referencing the global
proxy.
Together, these restrictions help prevent two different scripts from sharing state using properties of the global object.
Additionally, specifications which use worklets and intend to allow implementation-defined behavior must obey the following:
They must require user agents to always have at least two WorkletGlobalScope
instances per Worklet
, and randomly assign a method or set of methods on a class to
a particular WorkletGlobalScope
instance. These specifications may provide an
opt-out under memory constraints.
These specifications must allow user agents to create and destroy instances of their
WorkletGlobalScope
subclasses at any time.
Some specifications which use worklets can invoke methods on a web-developer-provided class based on the state of the user agent. To increase concurrency between threads, a user agent may invoke a method speculatively, based on potential future states.
In these specifications, user agents might invoke such methods at any time, and with any arguments, not just ones corresponding to the current state of the user agent. The results of such speculative evaluations are not displayed immediately, but can be cached for use if the user agent state matches the speculated state. This can increase the concurrency between the user agent and worklet threads.
As a result of this, to prevent interoperability risks between user agents, authors who
register classes on such WorkletGlobalScope
s should make their code stateless. That
is, the only effect of invoking a method should be its result, and not any side effects such as
updating mutable state.
The same techniques which encourage code idempotence also encourage authors to write stateless code.
This section is non-normative.
For these examples, we'll use a fake worklet. The Window
object provides two
Worklet
instances, which each run code in their own collection of
FakeWorkletGlobalScope
s:
partial interface Window {
[SameObject , SecureContext ] readonly attribute Worklet fakeWorklet1 ;
[SameObject , SecureContext ] readonly attribute Worklet fakeWorklet2 ;
};
Each Window
has two Worklet
instances, fake
worklet 1 and fake worklet 2. Both of these have their worklet
global scope type set to FakeWorkletGlobalScope
, and their worklet
destination type set to "fakeworklet
". User agents should create at
least two FakeWorkletGlobalScope
instances per worklet.
"fakeworklet
" is not actually a valid destination per Fetch. But this
illustrates how real worklets would generally have their own worklet-type-specific destination.
[FETCH]
The fakeWorklet1
getter steps are to return
this's fake worklet 1.
The fakeWorklet2
getter steps are to return
this's fake worklet 2.
[Global =(Worklet ,FakeWorklet ),
Exposed =FakeWorklet ,
SecureContext ]
interface FakeWorkletGlobalScope : WorkletGlobalScope {
undefined registerFake (DOMString type , Function classConstructor );
};
Each FakeWorkletGlobalScope
has a registered class constructors map,
which is an ordered map, initially empty.
The registerFake(type, classConstructor)
method
steps are to set this's registered class constructors
map[type] to classConstructor.
This section is non-normative.
To load scripts into fake worklet 1, a web developer would write:
window. fakeWorklet1. addModule( 'script1.mjs' );
window. fakeWorklet1. addModule( 'script2.mjs' );
Note that which script finishes fetching and runs first is dependent on network timing: it
could be either script1.mjs
or script2.mjs
. This
generally won't matter for well-written scripts intended to be loaded in worklets, if they follow
the suggestions about preparing for speculative
evaluation.
If a web developer wants to perform a task only after the scripts have successfully run and loaded into some worklets, they could write:
Promise. all([
window. fakeWorklet1. addModule( 'script1.mjs' ),
window. fakeWorklet2. addModule( 'script2.mjs' )
]). then(() => {
// Do something which relies on those scripts being loaded.
});
Another important point about script-loading is that loaded scripts can be run in multiple
WorkletGlobalScope
s per Worklet
, as discussed in the section on code idempotence. In particular, the specification above
for fake worklet 1 and fake worklet 2 require this. So, consider a
scenario such as the following:
// script.mjs
console. log( "Hello from a FakeWorkletGlobalScope!" );
// app.mjs
window. fakeWorklet1. addModule( "script.mjs" );
This could result in output such as the following from a user agent's console:
[fakeWorklet1#1] Hello from a FakeWorkletGlobalScope!
[fakeWorklet1#4] Hello from a FakeWorkletGlobalScope!
[fakeWorklet1#2] Hello from a FakeWorkletGlobalScope!
[fakeWorklet1#3] Hello from a FakeWorkletGlobalScope!
If the user agent at some point decided to kill and restart the third instance of
FakeWorkletGlobalScope
, the console would again print [fakeWorklet1#3] Hello from a FakeWorkletGlobalScope!
when this occurs.
This section is non-normative.
Let's say that one of the intended usages of our fake worklet by web developers is to allow them to customize the highly-complex process of boolean negation. They might register their customization as follows:
// script.mjs
registerFake( 'negation-processor' , class {
process( arg) {
return ! arg;
}
});
// app.mjs
window. fakeWorklet1. addModule( "script.mjs" );
To make use of such registered classes, the specification for fake worklets could define a find the opposite of true algorithm, given a
Worklet
worklet:
Optionally, create a worklet global scope for worklet.
Let workletGlobalScope be one of worklet's global scopes, chosen in an implementation-defined manner.
Let classConstructor be workletGlobalScope's registered class
constructors map["negation-processor
"].
Let classInstance be the result of constructing classConstructor, with no arguments.
Let function be Get(classInstance,
"process
"). Rethrow any exceptions.
Let callback be the result of converting function to a Web IDL Function
instance.
Return the result of invoking callback with the arguments « true » and with classInstance as the callback this value.
Another, perhaps better, specification architecture would be to extract the "process
" property and convert it into a Function
at registration time, as part of the registerFake()
method steps.
Subclasses of WorkletGlobalScope
are used to create global objects wherein code loaded into a particular Worklet
can
execute.
[Exposed =Worklet , SecureContext ]
interface WorkletGlobalScope {};
Other specifications are intended to subclass WorkletGlobalScope
,
adding APIs to register a class, as well as other APIs specific for their worklet type.
Each WorkletGlobalScope
has an associated module map. It is a module map,
initially empty.
This section is non-normative.
Each WorkletGlobalScope
is contained in its own worklet agent, which
has its corresponding event loop. However, in
practice, implementation of these agents and event loops is expected to be different from most
others.
A worklet agent exists for each WorkletGlobalScope
since, in theory,
an implementation could use a separate thread for each WorkletGlobalScope
instance,
and allowing this level of parallelism is best done using agents. However, because their
[[CanBlock]] value is false, there is no requirement that agents and threads are one-to-one. This
allows implementations the freedom to execute scripts loaded into a worklet on any thread,
including one running code from other agents with [[CanBlock]] of false, such as the thread of a
similar-origin window agent ("the main thread"). Contrast this with dedicated worker agents, whose true value for [[CanBlock]]
effectively requires them to get a dedicated operating system thread.
Worklet event loops are also somewhat special. They are only
used for tasks associated with addModule()
, tasks wherein the user agent invokes
author-defined methods, and microtasks. Thus, even though the event loop processing model specifies that all event loops
run continuously, implementations can achieve observably-equivalent results using a simpler
strategy, which just invokes author-provided
methods and then relies on that process to perform a microtask checkpoint.
To create a worklet global scope for a Worklet
worklet:
Let outsideSettings be worklet's relevant settings object.
Let agent be the result of obtaining a worklet agent given outsideSettings. Run the rest of these steps in that agent.
Let realmExecutionContext be the result of creating a new JavaScript realm given agent and the following customizations:
For the global object, create a new object of the type given by worklet's worklet global scope type.
Let workletGlobalScope be the global object of realmExecutionContext's Realm component.
Let insideSettings be the result of setting up a worklet environment settings object given realmExecutionContext and outsideSettings.
For each moduleURL of worklet's added modules list:
Fetch a worklet script graph given moduleURL, insideSettings, worklet's worklet destination type, what credentials mode?, insideSettings, and worklet's module responses map. Wait until the algorithm asynchronously completes with script.
This will not actually perform a network request, as it will just reuse responses from worklet's module responses map. The main purpose of this step is to create a new workletGlobalScope-specific module script from the response.
Assert: script is not null, since the fetch succeeded and the source text was successfully parsed when worklet's module responses map was initially populated with moduleURL.
Run a module script given script.
Append workletGlobalScope to
outsideSettings's global object's
associated Document
's worklet global scopes.
Append workletGlobalScope to worklet's global scopes.
Run the responsible event loop specified by insideSettings.
To terminate a worklet global scope given a WorkletGlobalScope
workletGlobalScope:
Let eventLoop be workletGlobalScope's relevant agent's event loop.
If there are any tasks queued in eventLoop's task queues, discard them without processing them.
Wait for eventLoop to complete the currently running task.
If the previous step doesn't complete within an implementation-defined period of time, then abort the script currently running in the worklet.
Destroy eventLoop.
Remove workletGlobalScope from the global scopes of the Worklet
whose
global scopes contains
workletGlobalScope.
Remove workletGlobalScope from the worklet global scopes of the
Document
whose worklet global
scopes contains workletGlobalScope.
To set up a worklet environment settings object, given a JavaScript execution context executionContext and an environment settings object outsideSettings:
Let origin be a unique opaque origin.
Let inheritedAPIBaseURL be outsideSettings's API base URL.
Let inheritedPolicyContainer be a clone of outsideSettings's policy container.
Let realm be the value of executionContext's Realm component.
Let workletGlobalScope be realm's global object.
Let settingsObject be a new environment settings object whose algorithms are defined as follows:
Return executionContext.
Return workletGlobalScope's module map.
Not applicable (the responsible event loop is not a window event loop).
Return UTF-8.
Return inheritedAPIBaseURL.
Unlike workers or other globals derived from a single resource, worklets have
no primary resource; instead, multiple scripts, each with their own URL, are loaded into the
global scope via worklet.addModule()
. So this API base URL
is rather unlike that of other globals. However, so far this doesn't matter, as no APIs
available to worklet code make use of the API base URL.
Return origin.
Return inheritedPolicyContainer.
Return TODO.
Assert: this algorithm is never called, because the time origin is not available in a worklet context.
Set settingsObject's id to a new unique opaque string, creation URL to inheritedAPIBaseURL, top-level creation URL to null, top-level origin to outsideSettings's top-level origin, target browsing context to null, and active service worker to null.
Set realm's [[HostDefined]] field to settingsObject.
Return settingsObject.
Worklet
classSupport in all current engines.
The Worklet
class provides the capability to add module scripts into its
associated WorkletGlobalScope
s. The user agent can then create classes registered on
the WorkletGlobalScope
s and invoke their methods.
[Exposed =Window , SecureContext ]
interface Worklet {
[NewObject ] Promise <undefined > addModule (USVString moduleURL , optional WorkletOptions options = {});
};
dictionary WorkletOptions {
RequestCredentials credentials = "same-origin";
};
Specifications that create Worklet
instances must specify the following for a
given instance:
its worklet global scope type, which must be a Web IDL type that inherits from WorkletGlobalScope
; and
its worklet destination type, which must be a destination, and is used when fetching scripts.
await worklet.addModule(moduleURL[, { credentials }])
Loads and executes the module script given by moduleURL into all of worklet's global scopes. It can also create additional global scopes as part of this process, depending on the worklet type. The returned promise will fulfill once the script has been successfully loaded and run in all global scopes.
The credentials
option can be set to a
credentials mode to modify the
script-fetching process. It defaults to "same-origin
".
Any failures in fetching the script or its
dependencies will cause the returned promise to be rejected with an
"AbortError
" DOMException
. Any errors in parsing the
script or its dependencies will cause the returned promise to be rejected with the exception
generated during parsing.
A Worklet
has a list of global scopes, which contains
instances of the Worklet
's worklet global scope type. It is initially
empty.
A Worklet
has an added modules
list, which is a list of URLs, initially empty.
Access to this list should be thread-safe.
A Worklet
has a module
responses map, which is an ordered map from URLs to
responses, initially empty. Access to this map should be
thread-safe.
The added modules list and module responses map exist to ensure that
WorkletGlobalScope
s created at different times get equivalent module scripts run in them, based on the same source text. This allows the
creation of additional WorkletGlobalScope
s to be transparent to the author.
In practice, user agents are not expected to implement these data structures, and the
algorithms that consult them, using thread-safe programming techniques. Instead, when addModule()
is called, user agents can fetch the module
graph on the main thread, and send the fetched source text (i.e., the important data contained in
the module responses map) to each
thread which has a WorkletGlobalScope
.
Then, when a user agent creates a new
WorkletGlobalScope
for a given Worklet
, it can simply send the map of
fetched source text and the list of entry points from the main thread to the thread containing
the new WorkletGlobalScope
.
The addModule(moduleURL,
options)
method steps are:
Let outsideSettings be the relevant settings object of this.
Parse moduleURL relative to outsideSettings.
If this fails, then return a promise rejected with a
"SyntaxError
" DOMException
.
Let moduleURLRecord be the resulting URL record.
Let promise be a new promise.
Run the following steps in parallel:
If this's global scopes is empty, then:
Optionally, create additional global scope instances given this, depending on the specific worklet in question and its specification.
Wait for all steps of the creation process(es) — including those taking place within the worklet agents — to complete, before moving on.
Let pendingTasks be this's global scopes's size.
Let addedSuccessfully be false.
For each workletGlobalScope of this's global scopes, queue a global task on the networking task source given workletGlobalScope to perform the following steps:
Fetch a worklet script graph given moduleURLRecord,
outsideSettings, this's worklet destination type,
options["credentials
"],
workletGlobalScope's relevant settings object, and
this's module responses
map. Wait until the algorithm asynchronously completes with
script.
Only the first of these fetches will actually perform a network request; the
ones for other WorkletGlobalScope
s will reuse reuse responses from this's module responses map.
If script is null, then:
Queue a global task on the networking task source given this's relevant global object to perform the following steps:
If pendingTasks is not −1, then:
Set pendingTasks to −1.
Reject promise with an "AbortError
"
DOMException
.
Abort these steps.
If script's error to rethrow is not null, then:
Queue a global task on the networking task source given this's relevant global object to perform the following steps:
If pendingTasks is not −1, then:
Set pendingTasks to −1.
Reject promise with script's error to rethrow.
Abort these steps.
If addedSuccessfully is false, then:
Append moduleURLRecord to this's added modules list.
Set addedSuccessfully to true.
Run a module script given script.
Queue a global task on the networking task source given this's relevant global object to perform the following steps:
If pendingTasks is not −1, then:
Set pendingTasks to pendingTasks − 1.
If pendingTasks is 0, then resolve promise.
Return promise.
The lifetime of a Worklet
has no special considerations; it is tied to the object
it belongs to, such as the Window
.
Each Document
has a worklet
global scopes, which is a set of WorkletGlobalScope
s, initially
empty.
The lifetime of a WorkletGlobalScope
is, at a minimum, tied to the
Document
whose worklet global
scopes contain it. In particular, discarding the
Document
will terminate the
corresponding WorkletGlobalScope
and allow it to be garbage-collected.
Additionally, user agents may, at any time, terminate a given WorkletGlobalScope
, unless the specification defining
the corresponding worklet type says otherwise. For example, they might terminate them if the
worklet agent's event loop has no
tasks queued, or if the user agent has no pending operations
planning to make use of the worklet, or if the user agent detects abnormal operations such as
infinite loops or callbacks exceeding imposed time limits.
Finally, specifications for specific worklet types can give more specific details on when to
create WorkletGlobalScope
s for a
given worklet type. For example, they might create them during specific processes that call upon
worklet code, as in the example.