Prioritized Task Scheduling API
Limited availability
This feature is not Baseline because it does not work in some of the most widely-used browsers.
Note: This feature is available in Web Workers.
The Prioritized Task Scheduling API provides a standardized way to prioritize all tasks belonging to an application, whether they are defined in a website developer's code or in third-party libraries and frameworks.
The task priorities are very coarse-grained and based around whether tasks block user interaction or otherwise impact the user experience, or can run in the background. Developers and frameworks may implement more fine-grained prioritization schemes within the broad categories defined by the API.
The API is promise-based and supports the ability to set and change task priorities, to delay tasks being added to the scheduler, to abort tasks, and to monitor for priority change and abort events.
In this page, we also include information about the navigator.scheduling.isInputPending()
method, which was defined in a different API specification but is very closely related to task scheduling. This method allows you to check whether there are pending input events in the event queue, and therefore handle task queues efficiently, only yielding to the main thread when it is needed.
Concepts and usage
Prioritized task scheduling
The Prioritized Task Scheduling API is available in both window and worker threads using the scheduler
property on the global object.
The main API method is Scheduler.postTask()
, which takes a callback function ("the task") and returns a promise that resolves with the return value of the function, or rejects with an error.
The simplest form of the API is shown below. This creates a task with default priority user-visible
that has a fixed priority and cannot be aborted.
const promise = scheduler.postTask(myTask);
Because the method returns a promise you can wait on its resolution asynchronously using then
, and catch errors thrown by the task callback function (or when the task is aborted) using catch
. The callback function can be any kind of function (below we demonstrate an arrow function).
scheduler
.postTask(() => "Task executing")
// Promise resolved: log task result when promise resolves
.then((taskResult) => console.log(`${taskResult}`))
// Promise rejected: log AbortError or errors thrown by task
.catch((error) => console.error(`Error: ${error}`));
The same task might be waited on using await
/async
as shown below (note, this is run in an Immediately Invoked Function Expression (IIFE)):
(async () => {
try {
const result = await scheduler.postTask(() => "Task executing");
console.log(result);
} catch (error) {
// Log AbortError or error thrown in task function
console.error(`Error: ${error}`);
}
})();
You can also specify an options object to the postTask()
method if you want to change the default behavior.
The options are:
-
priority
This allows you to specify a particular immutable priority. Once set, the priority cannot be changed. -
signal
This allows you to specify a signal, which may be either aTaskSignal
orAbortSignal
The signal is associated with a controller, which can be used to abort the task. ATaskSignal
can also be used to set and change the task priority if the task is mutable. delay
This allows you to specify the delay before the task is added for scheduling, in milliseconds.
The same example as above with a priority option would look like this:
scheduler
.postTask(() => "Task executing", { priority: "user-blocking" })
.then((taskResult) => console.log(`${taskResult}`)) // Log the task result
.catch((error) => console.error(`Error: ${error}`)); // Log any errors
Task priorities
Scheduled tasks are run in priority order, followed by the order that they were added to the scheduler queue.
There are just three priorities, which are listed below (ordered from highest to lowest):
user-blocking
-
Tasks that stop users from interacting with the page. This includes rendering the page to the point where it can be used, or responding to user input.
user-visible
-
Tasks that are visible to the user but not necessarily blocking user actions. This might include rendering non-essential parts of the page, such as non-essential images or animations.
This is the default priority.
background
-
Tasks that are not time-critical. This might include log processing or initializing third party libraries that aren't required for rendering.
Mutable and immutable task priority
There are many use cases where the task priority never needs to change, while for others it does.
For example fetching an image might change from a background
task to user-visible
as a carousel is scrolled into the viewing area.
Task priorities can be set as static (immutable) or dynamic (modifiable) depending on the arguments passed to Scheduler.postTask()
.
Task priority is immutable if a value is specified in the options.priority
argument.
The given value will be used for the task priority and cannot be changed.
The priority is modifiable only if a TaskSignal
is passed to the options.signal
argument and options.priority
is not set.
In this case the task will take its initial priority from the signal
priority, and the priority can subsequently be changed by calling TaskController.setPriority()
on the controller associated with the signal.
If the priority is not set with options.priority
or by passing a TaskSignal
to options.signal
then it defaults to user-visible
(and is by definition immutable).
Note that a task that needs to be aborted must set options.signal
to either TaskSignal
or AbortSignal
.
However for a task with an immutable priority, AbortSignal
more clearly indicates that the task priority cannot be changed using the signal.
isInputPending()
The isInputPending()
API is intended to help with task execution, enabling you to make task runners more efficient by yielding to the main thread only when the user is trying to interact with your app, rather than having to do it at arbitrary intervals.
Let's run through an example to demonstrate what we mean by this. When you have several tasks that are of roughly the same priority, it makes sense to break them down into separate functions to aid with maintenance, debugging, and many other reasons.
For example:
function main() {
a();
b();
c();
d();
e();
}
However, this kind of structure doesn't help with main thread blocking. Since all five of the tasks are being run inside one main function, the browser runs them all as a single task.
To handle this, we tend to run a function periodically to get the code to yield to the main thread. This means that our code is split into multiple tasks, between the execution of which the browser is given the opportunity to handle high-priority tasks such as updating the UI. A common pattern for this function uses setTimeout()
to postpone execution into a separate task:
function yield() {
return new Promise((resolve) => {
setTimeout(resolve, 0);
});
}
This can be used inside a task runner pattern like so, to yield to the main thread after each task has been run:
async function main() {
// Create an array of functions to run
const tasks = [a, b, c, d, e];
// Loop over the tasks
while (tasks.length > 0) {
// Shift the first task off the tasks array
const task = tasks.shift();
// Run the task
task();
// Yield to the main thread
await yield();
}
}
This helps with the main thread-blocking problem, but it could be better — we can use navigator.scheduling.isInputPending()
to run the yield()
function only when the user is attempting to interact with the page:
async function main() {
// Create an array of functions to run
const tasks = [a, b, c, d, e];
while (tasks.length > 0) {
// Yield to a pending user input
if (navigator.scheduling.isInputPending()) {
await yield();
} else {
// Shift the first task off the tasks array
const task = tasks.shift();
// Run the task
task();
}
}
}
This allows you to avoid blocking the main thread when the user is actively interacting with the page, potentially providing a smoother user experience. However, by only yielding when necessary, we can continue running the current task when there are no user inputs to process. This also avoids tasks being placed at the back of the queue behind other non-essential browser-initiated tasks that were scheduled after the current one.
Interfaces
Scheduler
-
Contains the
postTask()
method for adding prioritized tasks to be scheduled. An instance of this interface is available on theWindow
orWorkerGlobalScope
global objects (this.scheduler
). Scheduling
-
Contains the
isInputPending()
method for checking whether there are pending input events in the event queue. TaskController
-
Supports both aborting a task and changing its priority.
TaskSignal
-
A signal object that allows you to abort a task and change its priority, if required, using a
TaskController
object. TaskPriorityChangeEvent
-
The interface for the
prioritychange
event, which is sent when the priority for a task is changed.
Note: If the task priority never needs to be changed, you can use an AbortController
and its associated AbortSignal
instead of TaskController
and TaskSignal
.
Extensions to other interfaces
-
This property is the entry point for using the
Scheduling.isInputPending()
method. Window.scheduler
andWorkerGlobalScope.scheduler
-
These properties are the entry points for using the
Scheduler.postTask()
method in a window or a worker scope, respectively.
Examples
Note that the examples below use mylog()
to write to a text area.
The code for the log area and method is generally hidden to not distract from more relevant code.
// hidden logger code - simplifies example
let log = document.getElementById("log");
function mylog(text) {
log.textContent += `${text}\n`;
}
Feature checking
Check whether prioritized task scheduling is supported by testing for the scheduler
property in the global "this
" exposed to the current scope.
The code below prints "Feature: Supported" if the API is supported on this browser.
// Check that feature is supported
if ("scheduler" in this) {
mylog("Feature: Supported");
} else {
mylog("Feature: NOT Supported");
}
Basic usage
Tasks are posted using Scheduler.postTask()
, specifying a callback function (task) in the first argument, and an optional second argument that can be used to specify a task priority, signal, and/or delay.
The method returns a Promise
that resolves with the return value of the callback function, or rejects with either an abort error or an error thrown in the function.
Because it returns a promise, Scheduler.postTask()
can be chained with other promises.
Below we show how to wait on the promise to resolve using then
.
This uses the default priority (user-visible
).
// A function that defines a task
function myTask() {
return "Task 1: user-visible";
}
if ("scheduler" in this) {
// Post task with default priority: 'user-visible' (no other options)
// When the task resolves, Promise.then() logs the result.
scheduler.postTask(myTask).then((taskResult) => mylog(`${taskResult}`));
}
The method can also be used with await
inside an async function.
The code below shows how you might use this approach to wait on a user-blocking
task.
function myTask2() {
return "Task 2: user-blocking";
}
async function runTask2() {
const result = await scheduler.postTask(myTask2, {
priority: "user-blocking",
});
mylog(result); // Logs 'Task 2: user-blocking'.
}
runTask2();
In some cases you might not need to wait on completion at all. For simplicity many of the examples here simply log the result as the task executes.
// A function that defines a task
function myTask3() {
mylog("Task 3: user-visible");
}
if ("scheduler" in this) {
// Post task and log result when it runs
scheduler.postTask(myTask3);
}
The log below shows the output of the three tasks above. Note that the order they are run depends on the priority first, and then the declaration order.
Permanent priorities
Task priorities may be set using priority
parameter in the optional second argument.
Priorities that are set in this way are immutable (cannot be changed).
Below we post two groups of three tasks, each member in reverse order of priority. The final task has the default priority. When run, each task simply logs it's expected order (we're not waiting on the result because we don't need to in order to show execution order).
if ("scheduler" in this) {
// three tasks, in reverse order of priority
scheduler.postTask(() => mylog("bckg 1"), { priority: "background" });
scheduler.postTask(() => mylog("usr-vis 1"), { priority: "user-visible" });
scheduler.postTask(() => mylog("usr-blk 1"), { priority: "user-blocking" });
// three more tasks, in reverse order of priority
scheduler.postTask(() => mylog("bckg 2"), { priority: "background" });
scheduler.postTask(() => mylog("usr-vis 2"), { priority: "user-visible" });
scheduler.postTask(() => mylog("usr-blk 2"), { priority: "user-blocking" });
// Task with default priority: user-visible
scheduler.postTask(() => mylog("usr-vis 3 (default)"));
}
The output below shows that the tasks are executed in priority order, and then declaration order.
Changing task priorities
Task priorities can also take their initial value from a TaskSignal
passed to postTask()
in the optional second argument.
If set in this way, the priority of the task can then be changed using the controller associated with the signal.
Note: Setting and changing task priorities using a signal only works when the options.priority
argument to postTask()
is not set, and when the options.signal
is a TaskSignal
(and not an AbortSignal
).
The code below first shows how to create a TaskController
, setting the initial priority of its signal to user-blocking
in the TaskController()
constructor.
The code then uses addEventListener()
to add an event listener to the controller's signal (we could alternatively use the TaskSignal.onprioritychange
property to add an event handler).
The event handler uses previousPriority
on the event to get the original priority and TaskSignal.priority
on the event target to get the new/current priority.
The task is then posted, passing in the signal, and then we immediately change the priority to background
by calling TaskController.setPriority()
on the controller.
if ("scheduler" in this) {
// Create a TaskController, setting its signal priority to 'user-blocking'
const controller = new TaskController({ priority: "user-blocking" });
// Listen for 'prioritychange' events on the controller's signal.
controller.signal.addEventListener("prioritychange", (event) => {
const previousPriority = event.previousPriority;
const newPriority = event.target.priority;
mylog(`Priority changed from ${previousPriority} to ${newPriority}.`);
});
// Post task using the controller's signal.
// The signal priority sets the initial priority of the task
scheduler.postTask(() => mylog("Task 1"), { signal: controller.signal });
// Change the priority to 'background' using the controller
controller.setPriority("background");
}
The output below demonstrates that the priority was successfully changed to background
from user-blocking
.
Note that in this case the priority is changed before the task is executed, but it could equally have been changed while the task was running.
Aborting tasks
Tasks can be aborted using either TaskController
and AbortController
, in exactly the same way.
The only difference is that you must use TaskController
if you also want to set the task priority.
The code below creates a controller and passes its signal to the task.
The task is then immediately aborted.
This causes the promise to be rejected with an AbortError
, which is caught in the catch
block and logged.
Note that we could also have listened for the abort
event fired on the TaskSignal
or AbortSignal
and logged the abort there.
if ("scheduler" in this) {
// Declare a TaskController with default priority
const abortTaskController = new TaskController();
// Post task passing the controller's signal
scheduler
.postTask(() => mylog("Task executing"), {
signal: abortTaskController.signal,
})
.then((taskResult) => mylog(`${taskResult}`)) // This won't run!
.catch((error) => mylog(`Error: ${error}`)); // Log the error
// Abort the task
abortTaskController.abort();
}
The log below shows the aborted task.
Delaying tasks
Tasks can be delayed by specifying an integer number of milliseconds in the options.delay
parameter to postTask()
.
This effectively adds the task to the prioritized queue on a timeout, as might be created using setTimeout()
.
The delay
is the minimum amount of time before the task is added to the scheduler; it may be longer.
The code below shows two tasks added (as arrow functions) with a delay.
if ("scheduler" in this) {
// Post task as arrow function with delay of 2 seconds
scheduler
.postTask(() => "Task delayed by 2000ms", { delay: 2000 })
.then((taskResult) => mylog(`${taskResult}`));
scheduler
.postTask(() => "Next task should complete in about 2000ms", { delay: 1 })
.then((taskResult) => mylog(`${taskResult}`));
}
Refresh the page. Note that the second string appears in log after about 2 seconds.
Specifications
Specification |
---|
Prioritized Task Scheduling # scheduler |
Early detection of input events # the-scheduling-interface |
Browser compatibility
api.Scheduler
BCD tables only load in the browser
api.Scheduling
BCD tables only load in the browser
See also
- Building a Faster Web Experience with the postTask Scheduler on the Airbnb blog (2021)
- Optimizing long tasks on web.dev (2022)