SharedArrayBuffer
Baseline Widely available
This feature is well established and works across many devices and browser versions. It’s been available across browsers since December 2021.
The SharedArrayBuffer
object is used to represent a generic raw binary data buffer, similar to the ArrayBuffer
object, but in a way that they can be used to create views on shared memory. A SharedArrayBuffer
is not a Transferable Object, unlike an ArrayBuffer
which is transferable.
Description
To share memory using SharedArrayBuffer
objects from one agent in the cluster to another (an agent is either the web page's main program or one of its web workers), postMessage
and structured cloning is used.
The structured clone algorithm accepts SharedArrayBuffer
objects and typed arrays mapped onto SharedArrayBuffer
objects. In both cases, the SharedArrayBuffer
object is transmitted to the receiver resulting in a new, private SharedArrayBuffer
object in the receiving agent (just as for ArrayBuffer
). However, the shared data block referenced by the two SharedArrayBuffer
objects is the same data block, and a side effect to the block in one agent will eventually become visible in the other agent.
const sab = new SharedArrayBuffer(1024);
worker.postMessage(sab);
Shared memory can be created and updated simultaneously in workers or the main thread. Depending on the system (the CPU, the OS, the Browser) it can take a while until the change is propagated to all contexts. To synchronize, atomic operations are needed.
SharedArrayBuffer
objects are used by some web APIs, such as:
Security requirements
Shared memory and high-resolution timers were effectively disabled at the start of 2018 in light of Spectre. In 2020, a new, secure approach has been standardized to re-enable shared memory.
As a baseline requirement, your document needs to be in a secure context.
For top-level documents, two headers need to be set to cross-origin isolate your site:
Cross-Origin-Opener-Policy
withsame-origin
as value (protects your origin from attackers)Cross-Origin-Embedder-Policy
withrequire-corp
orcredentialless
as value (protects victims from your origin)
Cross-Origin-Opener-Policy: same-origin
Cross-Origin-Embedder-Policy: require-corp
To check if cross origin isolation has been successful, you can test against the Window.crossOriginIsolated
property or the WorkerGlobalScope.crossOriginIsolated
property available to window and worker contexts:
const myWorker = new Worker("worker.js");
if (crossOriginIsolated) {
const buffer = new SharedArrayBuffer(16);
myWorker.postMessage(buffer);
} else {
const buffer = new ArrayBuffer(16);
myWorker.postMessage(buffer);
}
With these two headers set, postMessage()
no longer throws for SharedArrayBuffer
objects and shared memory across threads is therefore available.
Nested documents and dedicated workers need to set the Cross-Origin-Embedder-Policy
header as well, with the same value. No further changes are needed for same-origin nested documents and subresources. Same-site (but cross-origin) nested documents and subresources need to set the Cross-Origin-Resource-Policy
header with same-site
as value. And their cross-origin (and cross-site) counterparts need to set the same header with cross-origin
as value. Note that setting the Cross-Origin-Resource-Policy
header to any other value than same-origin
opens up the resource to potential attacks, such as Spectre.
Note that the Cross-Origin-Opener-Policy
header limits your ability to retain a reference to popups. Direct access between two top-level window contexts essentially only work if they are same-origin and carry the same two headers with the same two values.
API availability
Depending on whether the above security measures are taken, the various memory-sharing APIs have different availabilities:
- The
Atomics
object is always available. SharedArrayBuffer
objects are in principle always available, but unfortunately the constructor on the global object is hidden, unless the two headers mentioned above are set, for compatibility with web content. There is hope that this restriction can be removed in the future.WebAssembly.Memory
can still be used to get an instance.- Unless the two headers mentioned above are set, the various
postMessage()
APIs will throw forSharedArrayBuffer
objects. If they are set,postMessage()
onWindow
objects and dedicated workers will function and allow for memory sharing.
WebAssembly shared memory
WebAssembly.Memory
objects can be created with the shared
constructor flag. When this flag is set to true
, the constructed Memory
object can be shared between workers via postMessage()
, just like SharedArrayBuffer
, and the backing buffer
of the Memory
object is a SharedArrayBuffer
. Therefore, the requirements listed above for sharing a SharedArrayBuffer
between workers also apply to sharing a WebAssembly.Memory
.
The WebAssembly Threads proposal also defines a new set of atomic instructions. Just as SharedArrayBuffer
and its methods are unconditionally enabled (and only sharing between threads is gated on the new headers), the WebAssembly atomic instructions are also unconditionally allowed.
Growing SharedArrayBuffers
SharedArrayBuffer
objects can be made growable by including the maxByteLength
option when calling the SharedArrayBuffer()
constructor. You can query whether a SharedArrayBuffer
is growable and what its maximum size is by accessing its growable
and maxByteLength
properties, respectively. You can assign a new size to a growable SharedArrayBuffer
with a grow()
call. New bytes are initialized to 0.
These features make growing SharedArrayBuffer
s more efficient — otherwise, you have to make a copy of the buffer with a new size. It also gives JavaScript parity with WebAssembly in this regard (Wasm linear memory can be resized with WebAssembly.Memory.prototype.grow()
).
For security reasons, SharedArrayBuffer
s cannot be reduced in size, only grown.
Constructor
-
Creates a new
SharedArrayBuffer
object.
Static properties
-
Returns the constructor used to construct return values from
SharedArrayBuffer
methods.
Instance properties
These properties are defined on SharedArrayBuffer.prototype
and shared by all SharedArrayBuffer
instances.
-
The size, in bytes, of the array. This is established when the array is constructed and can only be changed using the
SharedArrayBuffer.prototype.grow()
method if theSharedArrayBuffer
is growable. -
The constructor function that created the instance object. For
SharedArrayBuffer
instances, the initial value is theSharedArrayBuffer
constructor. -
Read-only. Returns
true
if theSharedArrayBuffer
can be grown, orfalse
if not. -
The read-only maximum length, in bytes, that the
SharedArrayBuffer
can be grown to. This is established when the array is constructed and cannot be changed. -
The initial value of the
[Symbol.toStringTag]
property is the string"SharedArrayBuffer"
. This property is used inObject.prototype.toString()
.
Instance methods
-
Grows the
SharedArrayBuffer
to the specified size, in bytes. -
Returns a new
SharedArrayBuffer
whose contents are a copy of thisSharedArrayBuffer
's bytes frombegin
, inclusive, up toend
, exclusive. If eitherbegin
orend
is negative, it refers to an index from the end of the array, as opposed to from the beginning.
Examples
Creating a new SharedArrayBuffer
const sab = new SharedArrayBuffer(1024);
Slicing the SharedArrayBuffer
sab.slice(); // SharedArrayBuffer { byteLength: 1024 }
sab.slice(2); // SharedArrayBuffer { byteLength: 1022 }
sab.slice(-2); // SharedArrayBuffer { byteLength: 2 }
sab.slice(0, 1); // SharedArrayBuffer { byteLength: 1 }
Using it in a WebGL buffer
const canvas = document.querySelector("canvas");
const gl = canvas.getContext("webgl");
const buffer = gl.createBuffer();
gl.bindBuffer(gl.ARRAY_BUFFER, buffer);
gl.bufferData(gl.ARRAY_BUFFER, sab, gl.STATIC_DRAW);
Specifications
Specification |
---|
ECMAScript Language Specification # sec-sharedarraybuffer-objects |
Browser compatibility
BCD tables only load in the browser
See also
Atomics
ArrayBuffer
- JavaScript typed arrays guide
- Web Workers
- Shared Memory – a brief tutorial in the TC39 ecmascript-sharedmem proposal
- A Taste of JavaScript's New Parallel Primitives on hacks.mozilla.org (2016)
- COOP and COEP explained by the Chrome team (2020)
Cross-Origin-Opener-Policy
Cross-Origin-Embedder-Policy
Cross-Origin-Resource-Policy
Window.crossOriginIsolated
andWorkerGlobalScope.crossOriginIsolated
- SharedArrayBuffer updates in Android Chrome 88 and Desktop Chrome 92 on developer.chrome.com (2021)