- Proposal: SE-0304
- Authors: John McCall, Joe Groff, Doug Gregor, Konrad Malawski
- Review Manager: Ben Cohen
- Status: Implemented (Swift 5.5) Acceptance post
- Implementation: Available in recent
main
snapshots behind the flag-Xfrontend -enable-experimental-concurrency
- Review: (first pitch) (second pitch) (third pitch) (first review) (second review) (third review) (fourth review) (acceptance) (revision)
- Previous revisions: (first review) (second review) (third review) (fourth review) (as accepted)
- Introduction
- Motivation
- Structured concurrency
- Proposed solution
- Detailed design
- Source compatibility
- Effect on ABI stability
- Effect on API resilience
- Revision history
- Alternatives Considered
- Future directions
async
/await
is a language mechanism for writing natural, efficient asynchronous code. Asynchronous functions (introduced with async
) can give up the thread on which they are executing at any given suspension point (marked with await
), which is necessary for building highly-concurrent systems.
However, the async
/await
proposal does not introduce concurrency per se: ignoring the suspension points within an asynchronous function, it will execute in essentially the same manner as a synchronous function. This proposal introduces support for structured concurrency in Swift, enabling concurrent execution of asynchronous code with a model that is ergonomic, predictable, and admits efficient implementation.
Swift-evolution threads:
For a simple example, let's make dinner, asynchronously:
func chopVegetables() async throws -> [Vegetable] { ... }
func marinateMeat() async -> Meat { ... }
func preheatOven(temperature: Double) async throws -> Oven { ... }
// ...
func makeDinner() async throws -> Meal {
let veggies = try await chopVegetables()
let meat = await marinateMeat()
let oven = try await preheatOven(temperature: 350)
let dish = Dish(ingredients: [veggies, meat])
return try await oven.cook(dish, duration: .hours(3))
}
Each step in our dinner preparation is an asynchronous operation, so there are numerous suspension points. While waiting for the vegetables to be chopped, makeDinner
won't block a thread: it will suspend until the vegetables are available, then resume. Presumably, many dinners could be in various stages of preparation, with most suspended until their current step is completed.
However, even though our dinner preparation is asynchronous, it is still sequential. It waits until the vegetables have been chopped before starting to marinate the meat, then waits again until the meat is ready before preheating the oven. Our hungry patrons will be very hungry indeed by the time dinner is finally done.
To make dinner preparation go faster, we need to perform some of these steps concurrently. To do so, we can break down our recipe into different tasks that can happen in parallel. The vegetables can be chopped at the same time that the meat is marinating and the oven is preheating. Sometimes there are dependencies between tasks: as soon as the vegetables and meat are ready, we can combine them in a dish, but we can't put that dish into the oven until the oven is hot. All of these tasks are part of the larger task of making dinner. When all of these tasks are complete, dinner is served.
This proposal aims to provide the necessary tools to carve work up into smaller tasks that can run concurrently, to allow tasks to wait for each other to complete, and to effectively manage the overall progress of a task.
Any concurrency system must offer certain basic tools. There must be some way to create a new thread that will run concurrently with existing threads. There must also be some way to make a thread wait until another thread signals it to continue. These are powerful tools, and you can write very sophisticated systems with them. But they're also very primitive tools: they make very few assumptions, but in return they give you very little support.
Imagine there's a function which does a large amount of work on the CPU. We want to optimize it by splitting the work across two cores; so now the function creates a new thread, does half the work in each thread, and then has its original thread wait for the new thread to finish. (In a more modern system, the function might add a task to a global thread pool, but the basic concept is the same.) There is a relationship between the work done by these two threads, but the system doesn't know about it. That makes it much harder to solve systemic problems.
For example, suppose a high-priority operation needs the function to hurry up and finish. The operation might know to escalate the priority of the first thread, but really it ought to escalate both. At best, it won't escalate the second thread until the first thread starts waiting for it. It's relatively easy to solve this problem narrowly, maybe by letting the function register a second thread that should be escalated. But it'll be an ad-hoc solution that might need to be repeated in every function that wants to use concurrency.
Structured concurrency solves this by asking programmers to organize their use of concurrency into high-level tasks and their child component tasks. These tasks become the primary units of concurrency, rather than lower-level concepts like threads. Structuring concurrency this way allows information to naturally flow up and down the hierarchy of tasks which would otherwise require carefully-written support at every level of abstraction and on every thread transition. This in turn permits many high-level problems to be addressed with relative ease.
For example:
-
It's common to want to limit the total time spent on a task. Some APIs support this by allowing a timeout to be passed in, but it takes a lot of work to propagate timeouts down correctly through every level of abstraction. This is especially true because end-programmers typically want to write timeouts as relative durations (e.g. 20ms), but the correctly-composing representation for libraries to pass around internally is an absolute deadline (e.g. now + 20ms). Under structured concurrency, a deadline can be installed on a task and naturally propagate through arbitrary levels of API, including to child tasks.
-
Similarly, it's common to want to be able to cancel an active task. Asynchronous interfaces that support this often do so by synchronously returning a token object that provides some sort of
cancel()
method. This significantly complicates the design of an API and so often isn't provided. Moreover, propagating tokens, or composing them to cancel all of the active work, can create significant engineering challenges for a program. Under structured concurrency, cancellation naturally propagates through APIs and down to child tasks, and APIs can install handlers to respond instantaneously to cancellation. -
Graphical user interfaces often rely on task prioritization to ensure timely refreshes and responses to events. Under structured concurrency, child tasks naturally inherit the priority of their parent tasks. Furthermore, when higher-priority tasks wait for lower-priority tasks to complete, the lower-priority task and all of its child tasks can be escalated in priority, and this will reliably persist even if the task is briefly suspended.
-
Many systems want to maintain their own contextual information for an operation without having to pass it through every level of abstraction, such as a server that records information for the connection currently being serviced. Structured concurrency allows this to naturally propagate down through async operations as a sort of "task-local storage" which can be picked up by child tasks.
-
Systems that rely on queues are often susceptible to queue-flooding, where the queue accepts more work than it can actually handle. This is typically solved by introducing "back-pressure": a queue stops accepting new work, and the systems that are trying to enqueue work there respond by themselves stopping accepting new work. Actor systems often subvert this because it is difficult at the scheduler level to refuse to add work to an actor's queue, since doing so can permanently destabilize the system by leaking resources or otherwise preventing operations from completing. Structured concurrency offers a limited, cooperative solution by allowing systems to communicate up the task hierarchy that they are coming under distress, potentially allowing parent tasks to stop or slow the creation of presumably-similar new work.
This proposal doesn't propose solutions for all of these, but early investigations show promise.
A task is the basic unit of concurrency in the system. Every asynchronous function is executing in a task. In other words, a task is to asynchronous functions, what a thread is to synchronous functions. That is:
- All asynchronous functions run as part of some task.
- A task runs one function at a time; a single task has no concurrency.
- When a function makes an
async
call, the called function is still running as part of the same task (and the caller waits for it to return). - Similarly, when a function returns from an
async
call, the caller resumes running on the same task.
Synchronous functions do not necessarily run as part of a task.
Swift assumes the existence of an underlying thread system. Tasks are scheduled by the system to run on these system threads. Tasks do not require special scheduling support from the underlying thread system, although a good scheduler could take advantage of some of the interesting properties of Swift's task scheduling.
A task can be in one of three states:
- A suspended task has more work to do but is not currently running.
- It may be schedulable, meaning that it’s ready to run and is just waiting for the system to instruct a thread to begin executing it,
- or it may be waiting on some external event before it can become schedulable.
- A running task is currently running on a thread.
- It will run until it either returns from its initial function (and becomes completed) or reaches a suspension point (and becomes suspended). At a suspension point, it may become immediately schedulable if, say, its execution just needs to change actors.
- A completed task has no more work to do and will never enter any other state.
- Code can wait for a task to become completed in various ways, most notably by
await
-ing on it.
- Code can wait for a task to become completed in various ways, most notably by
The way we talk about execution for tasks and asynchronous functions is more complicated than it is for synchronous functions. An asynchronous function is running as part of a task. If the task is running, it and its current function are also running on a thread.
Note that, when an asynchronous function calls another asynchronous function, we say that the calling function is suspended, but that doesn’t mean the entire task is suspended. From the perspective of the function, it is suspended, waiting for the call to return. From the perspective of the task, it may have continued running in the callee, or it may have been suspended in order to, say, change to a different execution context.
Tasks serve three high-level purposes:
- They carry scheduling information, such as the task's priority.
- They serve as a handle through which the operation can be cancelled, queried, or manipulated.
- They can carry user-provided task-local data.
At a lower level, the task allows the implementation to optimize the allocation of local memory, such as for asynchronous function contexts. It also allows dynamic tools, crash reporters, and debuggers to discover how a function is being used.
An asynchronous function can create a child task. Child tasks inherit some of the structure of their parent task, including its priority, but can run concurrently with it. However, this concurrency is bounded: a function that creates a child task must wait for it to end before returning. This structure means that functions can locally reason about all the work currently being done for the current task, anticipate the effects of cancelling the current task, and so on. It also makes creating the child task substantially more efficient.
Of course, a function’s task may itself be a child of another task, and its parent may have other children; a function cannot reason locally about these. But the features of this design that apply to an entire task tree, such as cancellation, only apply “downwards” and don’t automatically propagate upwards in the task hierarchy, and so the child tree still can be statically reasoned about. If child tasks did not have bounded duration and so could arbitrarily outlast their parents, the behavior of tasks under these features would not be easily comprehensible.
In this proposal, the way to create child tasks is only within a TaskGroup
, however there will be a follow-up proposal that enables creation of child tasks in any asynchronous context.
The execution of a task can be seen as a succession of periods where the task was running, each of which ends at a suspension point or — finally — at the completion of the task. These periods are called jobs. Jobs are the basic units of schedulable work in the system. They are also the primitive through which asynchronous functions interact with the underlying synchronous world. For the most part, programmers should not have to work directly with jobs unless they are implementing a custom executor.
An executor is a service which accepts the submission of jobs and arranges for some thread to run them. The system assumes that executors are reliable and will never fail to run a job.
An asynchronous function that is currently running always knows the executor that it's running on. This allows the function to avoid unnecessarily suspending when making a call to the same executor, and it allows the function to resume executing on the same executor it started on.
An executor is called exclusive if the jobs submitted to it will never be run concurrently. (Specifically, the jobs must be totally ordered by the happens-before relationship: given any two jobs that were submitted and run, the end of one must happen-before the beginning of the other.) Executors are not required to run jobs in the order they were submitted; in fact, they should generally honor task priority over submission order.
Swift provides a default executor implementation, but both actors and global actors (described in separate proposals) can suppress this and provide their own implementation.
Generally end-users need not interact with executors directly, but rather use them implicitly by invoking functions which happen to use executors to perform the invoked asynchronous functions.
A task is associated with a specific priority.
Task priority may inform decisions an executor makes about how and when to schedule tasks submitted to it. An executor may utilize priority information to attempt to run higher priority tasks first, and then continuing to serve lower priority tasks. It may also use priority information to affect the platform thread priority.
The exact semantics of how priority is treated are left up to each platform and specific executor implementation.
Child tasks automatically inherit their parent task's priority. Detached tasks do not inherit priority (or any other information) because they semantically do not have a parent task.
The priority of a task does not necessarily match the priority of its executor. For example, the UI thread on Apple platforms is a high-priority executor; any task submitted to it will be run with high priority for the duration of its time on the thread. This helps to ensure that the UI thread will be available to run higher-priority work if it is submitted later. This does not affect the formal priority of the task.
In some situations the priority of a task must be escalated in order to avoid a priority inversion:
-
If a task is running on behalf of an actor, and a higher-priority task is enqueued on the actor, the task may temporarily run at the priority of the higher-priority task. This does not affect child tasks or the reported priority; it is a property of the thread running the task, not the task itself.
-
If a task is created with a task handle, and a higher-priority task waits for that task to complete, the priority of the task will be permanently increased to match the higher-priority task. This does affect child tasks and the reported task priority.
Our approach follows the principles of structured concurrency described above. All asynchronous functions run as part of an asynchronous task. Tasks can make child tasks that will perform work concurrently. This creates a hierarchy of tasks, and information can naturally flow up and down the hierarchy, making it convenient to manage the whole thing holistically.
A task group defines a scope in which one can create new child tasks programmatically. As with all child tasks, the child tasks within the task group scope must complete when the scope exits, and will be implicitly cancelled first if the scope exits with a thrown error.
To illustrate task groups, let's start by showing how we can introduce some
real concurrency to our makeDinner
example:
func makeDinner() async throws -> Meal {
// Prepare some variables to receive results from our concurrent child tasks
var veggies: [Vegetable]?
var meat: Meat?
var oven: Oven?
enum CookingStep {
case veggies([Vegetable])
case meat(Meat)
case oven(Oven)
}
// Create a task group to scope the lifetime of our three child tasks
try await withThrowingTaskGroup(of: CookingStep.self) { group in
group.addTask {
try await .veggies(chopVegetables())
}
group.addTask {
await .meat(marinateMeat())
}
group.addTask {
try await .oven(preheatOven(temperature: 350))
}
for try await finishedStep in group {
switch finishedStep {
case .veggies(let v): veggies = v
case .meat(let m): meat = m
case .oven(let o): oven = o
}
}
}
// If execution resumes normally after `withTaskGroup`, then we can assume
// that all child tasks added to the group completed successfully. That means
// we can confidently force-unwrap the variables containing the child task
// results here.
let dish = Dish(ingredients: [veggies!, meat!])
return try await oven!.cook(dish, duration: .hours(3))
}
Note that it would be illegal to say:
var veggies: [Vegetable]?
try await withThrowingTaskGroup(of: Void.self) { group in
group.addTask {
// error: mutation of captured var 'veggies' in concurrently-executing code
veggies = try await chopVegetables()
}
}
let dish = Dish(ingredients: [veggies!])
This may be surprising, because the child tasks are guaranteed to have
completed in one way or another by the end of withTaskGroup
, so it would
theoretically be safe for them to modify variables captured from their parent
context as long as sibling tasks or the parent task itself do not
simultaneously access those same variables until the task group completes.
However, Swift's @Sendable
closure checking has to be conservative, unless
we give it special knowledge of task groups' semantics. We leave that to a
later proposal.
The withTaskGroup
API gives us access to a task group, and governs the
lifetime of the child tasks we subsequently add to the group using its
addTask()
method. By the time withTaskGroup
finishes executing, we know that all of
the subtasks have completed. A child task does not persist beyond the scope in
which it was created. By the time the scope exits, the child task must either
have completed, or it will be implicitly awaited. When the scope exits via a
thrown error, the child task will be implicitly cancelled before it is awaited.
These properties allow us to nicely contain the effects of the concurrency we
introduce inside the task group: although chopVegetables
, marinateMeat
,
and preheatOven
will run concurrently, and may make progress in any order,
we can be sure that they have all finished executing in one way or another
by the time withTaskGroup
returns or throws an error. In either case, task groups
naturally propagate status from child tasks to the parent; in this example,
the chopVegetables()
function might throw an error if, say, there is an
incident with the kitchen knife. That thrown error completes the child task for
chopping the vegetables. The error will then be propagated out of the
makeDinner()
function, as expected. On exiting the body of the makeDinner()
function with this error, any child tasks that have not yet completed
(marinating the meat or preheating the oven, maybe both) will be automatically
cancelled. Structured concurrency means we don't have to manually propagate
errors and manage cancellation; if execution continues normally after a call
into withTaskGroup
, we can assume that all of its child tasks completed
successfully.
Let's stretch our example even further and focus in on our chopVegetables()
operation, which produces an array of Vegetable
values. With enough cooks, we could chop our vegetables even faster if we divided up the chopping for each kind of vegetable. Let's start with a sequential version of chopVegetables()
:
/// Sequentially chop the vegetables.
func chopVegetables() async throws -> [Vegetable] {
let rawVeggies: [Vegetable] = gatherRawVeggies()
var choppedVeggies: [Vegetable] = []
for v in rawVeggies {
choppedVeggies.append(try await v.chopped())
}
return choppedVeggies
}
Unlike the top-level makeDinner
task, here we have a dynamic amount of
potential concurrency; depending on how many vegetables we can get from
gatherRawVeggies
, each vegetable could in principle be chopped in parallel
with the rest. We also don't need to necessarily gather the chopped vegetables
in any specific order, and can collect the results as they become ready.
To create a dynamic number of child tasks and gather their results, we still introduce a new task group via withTaskGroup
, specifying a ChildTaskResult.Type
for the child tasks, and using the group's next
method to collect those
results as they become ready:
/// Concurrently chop the vegetables.
func chopVegetables() async throws -> [Vegetable] {
// Create a task group where each child task produces a Vegetable.
try await withThrowingTaskGroup(of: Vegetable.self) { group in
var rawVeggies: [Vegetable] = gatherRawVeggies()
var choppedVeggies: [Vegetable] = []
// Create a new child task for each vegetable that needs to be chopped.
for v in rawVeggies {
group.addTask {
try await v.chopped()
}
}
// Wait for all of the chopping to complete, collecting the veggies into
// the result array in whatever order they're ready.
while let choppedVeggie = try await group.next() {
choppedVeggies.append(choppedVeggie)
}
return choppedVeggies
}
}
As in the first example, if the closure passed to withTaskGroup
exited without having completed all its child tasks, the task group will still wait until all child tasks have completed before returning. If the closure exits with a thrown error, the outstanding child tasks will first be cancelled before propagating
the error to the parent.
By contrast with future-based task APIs, there is no way in which a reference to the child task can escape the scope in which the child task is created. This ensures that the structure of structured concurrency is maintained. It both makes it easier to reason about the concurrent tasks that are executing within a given scope, and also unlocks numerous optimization opportunities for the compiler and runtime.
A program can use @main
with a main()
function that is async
:
@main
struct Eat {
static func main() async throws {
let meal = try await makeDinner()
print(meal)
}
}
Semantically, Swift will create a new task that will execute main()
. Once that task completes, the program terminates.
Top-level code can also make use of asynchronous calls. For example:
// main.swift or a Swift script
let meal = try await makeDinner()
print(meal)
The model is the same as for @main
: Swift creates a task to execute top-level code, and completion of that task terminates the program.
A task can be cancelled asynchronously by any context that has a reference to a task or one of its parent tasks. Cancellation can be triggered explicitly by calling cancel()
on the task handle. Cancellation can also trigger automatically, for example when a parent task throws an error out of a scope with unawaited child tasks.
The effect of cancellation within the cancelled task is fully cooperative and synchronous. That is, cancellation has no effect at all unless something checks for cancellation. Conventionally, most functions that check for cancellation report it by throwing CancellationError()
; accordingly, they must be throwing functions, and calls to them must be decorated with some form of try
. As a result, cancellation introduces no additional control-flow paths within asynchronous functions; you can always look at a function and see the places where cancellation can occur. As with any other thrown error, defer
blocks can be used to clean up effectively after cancellation.
With that said, the general expectation is that asynchronous functions should attempt to respond to cancellation by promptly throwing or returning. In most functions, it should be sufficient to rely on lower-level functions that can wait for a long time (for example, I/O functions or Task.value
) to check for cancellation and abort early. Functions which perform a large amount of synchronous computation may wish to periodically check for cancellation explicitly.
Cancellation has two effects which trigger immediately with the cancellation:
-
A flag is set in the task which marks it as having been cancelled; once this flag is set, it is never cleared. Operations running synchronously as part of the task can check this flag and are conventionally expected to throw a
CancellationError
. -
Any cancellation handlers which have been registered on the task are immediately run. This permits functions which need to respond immediately to do so.
We can illustrate cancellation with a version of the chopVegetables()
function we saw previously:
func chopVegetables() async throws -> [Vegetable] {
return try await withThrowingTaskGroup(of: Vegetable.self) { group in
var veggies: [Vegetable] = []
group.addTask {
try await chop(Carrot()) // (1) throws UnfortunateAccidentWithKnifeError()
}
group.addTask {
try await chop(Onion()) // (2)
}
for try await veggie in group { // (3)
veggies.append(veggie)
}
return veggies
}
}
On line (1), we start a new child task to chop a carrot. Suppose that this call to the chop
function throws an error. Because this is asynchronous, that error is not immediately observed in chopVegetables
, and we proceed to start a second child task to chop an onion (2). On line (3), we await the next
completed task, which could be either of the child tasks we created, but for the sake of discussion we'll say happens to be the chop(Carrot())
child task from (1). This causes us to throw the error that was thrown from chop
. Since we do not handle this error, we exit the scope without having yet awaited the onion-chopping task. This causes that task to be automatically cancelled. Because cancellation is cooperative, and because structured concurrency does not allow child tasks to outlast their parent context, control does not actually return until the onion-chopping task actually completes; any value it returns or throws will be discarded.
As we mentioned before, the effect of cancellation on a task is synchronous and cooperative. Functions which do a lot of synchronous computation may wish to check explicitly for cancellation. They can do so by inspecting the task's cancelled status:
func chop(_ vegetable: Vegetable) async throws -> Vegetable {
try Task.checkCancellation() // automatically throws `CancellationError`
// chop chop chop ...
// ...
guard !Task.isCancelled else {
print("Cancelled mid-way through chopping of \(vegetable)!")
throw CancellationError()
}
// chop some more, chop chop chop ...
}
Note also that no information is passed to the task about why it was cancelled. A task may be cancelled for many reasons, and additional reasons may accrue after the initial cancellation (for example, if the task fails to immediately exit, it may pass a deadline). The goal of cancellation is to allow tasks to be cancelled in a lightweight way, not to be a secondary method of inter-task communication.
So far all types of tasks we discussed were child-tasks and respected the primary rule of structured concurrency: that a child task cannot live longer than the parent task (or scope) in which it was created. This is both true for task groups as well as SE-0317 async let
.
Sometimes however, these rigid rules end up being too restrictive. We might need to create new tasks whose lifetime is not bound to the creating task, for example in order to fire-and-forget some operation or to initiate asynchronous work from synchronous code. Unstructured tasks are not able to utilize some of the optimization techniques wrt. allocation and metadata propagation as child-tasks are, however they remain a very important building block especially for more free-form usages and integration with legacy APIs.
All unstructured tasks are represented by a task handle, which can be used to retrieve the value (or thrown error) produced by the task, cancel the task, or perform queries of the task's status. A new task can be created with the Task { ... }
initializer. For example:
let dinnerHandle = Task {
try await makeDinner()
}
The initializer creates a new task that begins executing the provided closure. That new task is represented by the constructed task handle (in this case, Task<Meal, Error>
) referencing the newly-launched task. Task handles can be used to await the result of the task, e.g.,
let dinner = try await dinnerHandle.value
Tasks run to completion even if there are no remaining uses of their task handle, so it is not necessary to retain the task handle or observe its value for the task to complete. However, the task handle can be used to explicitly cancel the operation, e.g.,
dinnerHandle.cancel()
Unstructured tasks created with the Task
initializer inherit important metadata information from the context in which it is created, including priority, task-local values, and actor isolation.
If called from the context of an existing task:
- inherit the priority of the current task the synchronous function is executing on
- inherit all task-local values by copying them to the new unstructured task
- if executed within the scope of a specific actor function:
- inherit the actor's execution context and run the task on its executor, rather than the global concurrent one,
- the closure passed to
Task {}
becomes actor-isolated to that actor, allowing access to the actor-isolated state, including mutable properties and non-sendable values.
If called from a context that is not running inside a task:
- consult the runtime and infer the best possible priority to use (e.g. by asking for current thread priority),
- even though there is no
Task
to inherit task-local values from, check the fallback mechanism for any task-locals stored for the current synchronous context (this is discussed in depth in the SE-0311 proposal) - execute on the global concurrent executor and be non-isolated with regard to any actor.
A detached task is an unstructured task that is independent of the context in which it is created, meaning that it does not inherit priority, task-local values, or the actor context. A new detached task can be created with the Task.detached
function:
let dinnerHandle = Task.detached {
try await makeDinner()
}
The Task.detached
operation produces a new task instance (in this case, Task<Meal, Error>
), in the same manner as the Task
initializer.
Much of the proposed implementation of structured concurrency is in the APIs for creating, querying, and managing tasks.
The Task
type describes a task and can be used to query or cancel that task. It's also used as a namespace for operations on the currently-executing task.
struct Task<Success: Sendable, Failure: Error>: Equatable, Hashable, Sendable { ... }
An instance of the Task
type can be used to retrieve the result (or thrown error) of executing the task. The operations are always async
:
extension Task {
/// Retrieve the result produced the task, if is the normal return value, or
/// throws the error that completed the task with a thrown error.
var value: Success {
get async throws
}
/// Retrieve the result produced by the task as a \c Result instance.
var result: Result<Success, Failure> { get async }
}
extension Task where Failure == Never {
/// Retrieve the result produced by a task that is known to never throw.
var value: Success {
get async
}
}
The value
property is the primary consumer interface to a task instance: it returns the result produced by the task or (if the task exits via a thrown error) throws the error produced by the task. For example:
func eat(mealHandle: Task<Meal, Error>) async throws {
let meal = try await mealHandle.value
meal.eat() // yum
}
Task instances also provide the ability to cancel a task programmatically:
extension Task {
/// Cancel the task referenced by this handle.
func cancel()
/// Determine whether the task was cancelled.
var isCancelled: Bool { get }
}
As noted elsewhere, cancellation is cooperative: the task will note that it has been cancelled and can choose to return earlier (either via a normal return or a thrown error, as appropriate). isCancelled
can be used to determine whether a particular task was ever cancelled.
The UnsafeCurrentTask
offers non-static functions which may be used to interact with the running task itself. The unsafe task object must never be escaped or accessed from another task, and thus the API to obtain it takes the familiar scoped with...
form of withUnsafeCurrentTask
:
func withUnsafeCurrentTask<T>(
body: (UnsafeCurrentTask?) throws -> T
) rethrows -> T
The withUnsafeCurrentTask
passes the current task into the operation or nil
if the function is called from a context in which a Task is not available. In practice this means that nowhere in the call chain until this invocation, was any asynchronous function involved. If there is an asynchronous function in the call chain until the invocation of unsafeCurrent
, that task will be returned.
The UnsafeCurrentTask
is purposefully named unsafe as it may expose APIs which can only be invoked safely from within task itself, and would exhibit undefined behavior if used from another task. It is therefore unsafe to store and "use later" an UnsafeCurrentTask
. Examples of such unsafe API are interacting with task-local values on a task object, which must be equal to the "current" task to be performed safely. This is by design, and offers the runtime optimization opportunities for the normal, and safe, access patterns to task storage.
Invoking some of its APIs from other tasks/threads will result in undefined behavior.
Accessing this API performs a thread-local lookup of a specific thread-local variable that is maintained by the Swift Concurrency runtime.
The withUnsafeCurrentTask
function may be invoked from synchronous (as well as asynchronous) code:
func synchronous() {
withUnsafeCurrentTask { maybeUnsafeCurrentTask in
if let unsafeCurrentTask = maybeUnsafeCurrentTask {
print("Seems I was invoked as part of a Task!")
} else {
print("Not part of a task.")
}
}
}
func asynchronous() async {
// the following is safe, because withUnsafeCurrentTask is invoked from an 'async' function
withUnsafeCurrentTask { maybeUnsafeCurrentTask in
let task: UnsafeCurrentTask = maybeUnsafeCurrentTask! // always ok
}
}
The withUnsafeCurrentTask
function returns an optional UnsafeCurrentTask
, this is because such synchronous function may be invoked from a task (i.e. from within asynchronous Swift code) or outside of it (e.g. some Task unaware API, like a raw pthread thread calling into Swift code).
The UnsafeCurrentTask
is also Equatable
and Hashable
, whose identity is based on the internal task object which is the same as the one used by Task
.
struct UnsafeCurrentTask: Equatable, Hashable {
public var isCancelled: Bool { get }
public var priority: TaskPriority { get }
public func cancel()
}
UnsafeCurrentTask
has all the same query operations as Task
(i.e. isCancelled
, priority
, ...) and the ability to cancel (cancel()
), which are equally safe to invoke on the unsafe task as on a normal task, however it may define more APIs in the future that are more fragile and must only ever be invoked while executing on the same task (e.g. access to Task-Local Values which are defined in a separate proposal).
The priority of a task is used by the executor to help make scheduling decisions.
The priorities are listed from highest (most important) to lowest (least important).
In order to avoid forcing other platforms to use Darwin specific terminology priorities use generic terms such as "high" and "low". However, the Darwin specific names exist as aliases and may be used interchangeably.
/// Describes the priority of a task.
struct TaskPriority: Codable, Comparable, RawRepresentable, Sendable {
var rawValue: UInt8 { get set }
init(rawValue: UInt8)
}
/// General, platform independent priority values.
///
/// The priorities are ordered from highest to lowest as follows:
/// - `high`
/// - `medium`
/// - `low`
/// - `background`
extension TaskPriority {
static var high: TaskPriority { ... }
static var medium: TaskPriority { ... }
static var low: TaskPriority { ... }
static var background: TaskPriority { ... }
}
/// Apple platform specific priority aliases.
///
/// The priorities are ordered from highest to lowest as follows:
/// - `userInitiated` (alias for `high` priority)
/// - `utility` (alias for `low` priority)
/// - `background`
///
/// The runtime reserves the right to use additional higher or lower priorities than those publicly listed here,
/// e.g. the main thread in an application might run at an user inaccessible `userInteractive` priority, however
/// any task created from it will automatically become `userInitiated`.
extension TaskPriority {
/// The task was initiated by the user and prevents the user from actively using
/// your app.
///
/// Alias for `TaskPriority.high`.
static var userInitiated: TaskPriority { ... }
/// Priority for a utility function that the user does not track actively.
///
/// Alias for `TaskPriority.low`
static var utility: TaskPriority { ... }
}
extension Task where Success == Never, Failure == Never {
/// Returns the `current` task's priority.
///
/// When called from a context with no `Task` available, will return the best
/// approximation of the current thread's priority, e.g. userInitiated for
/// the "main thread" or default if no specific priority can be detected.
static var currentPriority: TaskPriority { ... }
}
The priority
operation queries the priority of the task.
The currentPriority
operation queries the priority of the currently-executing task. Task priorities are set on task creation (e.g., Task.detached
or TaskGroup.addTask
) and can be escalated later, e.g., if a higher-priority task waits on the task handle of a lower-priority task.
Unstructured tasks can be created using the Task
initializer:
extension Task where Failure == Never {
@discardableResult
init(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async -> Success
)
}
extension Task where Failure == Error {
@discardableResult
init(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async throws -> Success
)
}
The initializers are marked with @discardableResult
because the task itself will immediately execute the operation and run to completion when the handle is unused. This is a fairly common use case for fire-and-forget asynchronous operations.
By default, the new task will be initially scheduled on the default global concurrent executor. Once custom executors are introduced in another proposal, these will be able to take an executor parameter to determine on which executor to schedule the new task instead.
The Task
initializer propagates priority from the point where it is called to the detached task that it creates:
- If the synchronous code is running on behalf of a task (i.e.,
withUnsafeCurrentTask
provides a non-nil
task), use the priority of that task; - If the synchronous code is running on behalf of the "UI" thread, use
.userInitiated
; otherwise - Query the system to determine the priority of the currently-executing thread and use that.
The implementation will also propagate any other important OS-specific information from the synchronous code into the asynchronous task.
A closure passed to the Task
initializer will implicitly inherit the actor execution context and isolation of the context in which the closure is formed. For example:
func notOnActor(_: @Sendable () async -> Void) { }
actor A {
func f() {
notOnActor {
await g() // must call g asynchronously, because it's a @Sendable closure
}
Task {
g() // okay to call g synchronously, even though it's @Sendable
}
}
func g() { }
}
In a sense, the Task
initializer counteracts the normal influence of @Sendable
on a closure within an actor. Specifically, SE-0306 states that @Sendable
closures are not actor-isolated:
Actors prevent this data race by specifying that a
@Sendable
closure is always non-isolated.
Such semantics, where the closure is both @Sendable
and actor-isolated, are only possible because the closure is also async
. Effectively, when the closure is called, it will immediately "hop" over to the actor's context so that it runs within the actor.
Closures passed to the Task
initializer are not required to explicitly acknowledge capture of self
with self.
.
func acceptEscaping(_: @escaping () -> Void) { }
class C {
var counter: Int = 0
func f() {
acceptEscaping {
counter = counter + 1 // error: must use "self." because the closure escapes
}
Task {
counter = counter + 1 // okay: implicit "self" is allowed here
}
}
}
The intent behind requiring self.
when capturing self
in an escaping closure is to warn the developer about potential reference cycles. The closure passed to Task
is executed immediately, and the only reference to self
is what occurs in the body. Therefore, the explicit self.
isn't communicating useful information and should not be required.
Note: The same applies to the closure passed to
Task.detached
andTaskGroup.addTask
.
A new, detached task can be created with the Task.detached
operation. The resulting task is represented by a Task
.
extension Task where Failure == Never {
/// Create a new, detached task that produces a value of type `Success`.
@discardableResult
static func detached(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async -> Success
) -> Task<Success, Never>
}
extension Task where Failure == Error {
/// Create a new, detached task that produces a value of type `Success` or throws an error.
@discardableResult
static func detached(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async throws -> Success
) -> Task<Success, Failure>
}
Detached tasks will typically be created using a trailing closure, e.g.,
let dinnerHandle: Task<Meal, Error> = Task.detached {
try await makeDinner()
}
try await eat(mealHandle: dinnerHandle)
The isCancelled
property determines whether the given task has been cancelled:
extension Task {
/// Returns `true` if the task is cancelled, and should stop executing.
var isCancelled: Bool { get }
}
It is possible to query for cancellation from within a synchronous task, e.g. while iterating over a loop and wanting to check if we should abort its execution by using the static Task.isCancelled
property:
extension Task where Success == Never, Failure == Never {
/// Returns `true` if the task is cancelled, and should stop executing.
///
/// Always returns `false` when called from code not currently running inside of a `Task`.
static var isCancelled: Bool { get }
}
This works the same as its instance counterpart, except that if invoked from a context that has no Task
available, e.g. if invoked from outside of Swift's concurrency model (e.g. directly from a pthread) a default value is returned.
The static isCancelled
property is implemented as:
extension Task where Success == Never, Failure == Never {
static var isCancelled: Bool {
withUnsafeCurrentTask { task in
task?.isCancelled ?? false
}
}
}
This static isCancelled
property is always safe to invoke, i.e. it may be invoked from synchronous or asynchronous functions and will always return the expected result. Do note however that checking cancellation while concurrently setting cancellation may be slightly racy, i.e. if the cancel
is performed from another thread, the isCancelled
may not return true
.
For tasks that would prefer to immediately exit with a thrown error on cancellation, the task API provides a common error type, CancellationError
, to communicate that the task was cancelled. The Task.checkCancellation()
operation will throw CancellationError
when the task has been cancelled, and is provided as a convenience.
/// The default cancellation thrown when a task is cancelled.
///
/// This error is also thrown automatically by `Task.checkCancellation()`,
/// if the current task has been cancelled.
struct CancellationError: Error {
// no extra information, cancellation is intended to be light-weight
init() {}
}
extension Task where Success == Never, Failure == Never {
/// Returns `true` if the task is cancelled, and should stop executing.
///
/// - SeeAlso: `checkCancellation()`
static func checkCancellation() throws
}
For tasks that want to react immediately to cancellation (rather than, say, waiting until a cancellation error propagates upward), one can install a cancellation handler:
/// Execute an operation with cancellation handler which will immediately be
/// invoked if the current task is cancelled.
///
/// This differs from the operation cooperatively checking for cancellation
/// and reacting to it in that the cancellation handler is _always_ and
/// _immediately_ invoked when the task is cancelled. For example, even if the
/// operation is running code which never checks for cancellation, a cancellation
/// handler still would run and give us a chance to run some cleanup code.
///
/// Does not check for cancellation, and always executes the passed `operation`.
///
/// This function returns instantly and will never suspend.
func withTaskCancellationHandler<T>(
operation: () async throws -> T,
onCancel handler: @Sendable () -> Void
) async rethrows -> T
This function does not, by itself, create a new task, but rather executes the operation
immediately, and once the operation
returns the withTaskCancellationHandler
returns as well (similarly with throwing behaviors).
Note that the handler
runs @Sendable
with the rest of the task, because it
is executed immediately when the task is cancelled, which can happen at any
point. If the task has already been cancelled at the point withTaskCancellationHandler
is called, the cancellation handler is invoked immediately, before the
operation
block is executed.
These properties place rather strict limitations on what a
cancellation handler closure can safely do, but the ability to be triggered at
any point makes cancellation handlers useful for managing the state of related
objects, in cases where either polling cancellation state from within the task
or else propagating it by throwing CancellationError
is not possible. As one
example, cancellation handlers can be useful in conjunction with
continuations to help thread cancellation through
non-async
event-driven interfaces. For example, if one wanted to wrap up
Foundation's URLSession
object in an async function interface, cancelling the
URLSession
if the async task is itself cancelled, then it might look
something like this:
func download(url: URL) async throws -> Data? {
var urlSessionTask: URLSessionTask?
return try withTaskCancellationHandler {
return try await withUnsafeThrowingContinuation { continuation in
urlSessionTask = URLSession.shared.dataTask(with: url) { data, _, error in
if let error = error {
// Ideally translate NSURLErrorCancelled to CancellationError here
continuation.resume(throwing: error)
} else {
continuation.resume(returning: data)
}
}
urlSessionTask?.resume()
}
} onCancel: {
urlSessionTask?.cancel() // runs immediately when cancelled
}
}
For long-running operations, say performing many computations in a tight loop
without natural suspend points, it might be beneficial to occasionally check in if the task should perhaps suspend and offer a chance for other tasks to proceed (e.g. if all are executing on a shared, limited-concurrency pool). For this use case, Task
includes a suspend()
operation, which is a way to explicitly suspend the current task and give other tasks a chance to run for a while.
extension Task where Success == Never, Failure == Never {
static func suspend() async { ... }
}
We also offer an asynchronous sleep function, which accepts the number of nanoseconds to suspend for:
extension Task where Success == Never, Failure == Never {
public static func sleep(nanoseconds duration: UInt64) async throws { ... }
}
The sleep function accepts a plain integer as nanoseconds to sleep for, which mirrors known top-level functions performing the same action in the synchronous world. It will throw CancellationError
if the task is cancelled while it sleeps, without waiting for the full sleep duration.
The
sleep
function will gain nicer overloads once the standard library has time and deadline types, then the sleep will be able to be expressed asawait Task.sleep(until: deadline)
orawait Task.sleep(for: .seconds(1))
or similar. This proposal is not introducing those time types, so for now a bare bones sleep function is proposed.
Task groups are created using withTaskGroup
in any asynchronous context, providing a scope in which new tasks can be created and executed concurrently.
/// Starts a new task group which provides a scope in which a dynamic number of
/// tasks may be created.
///
/// Tasks added to the group by `group.addTask()` will automatically be awaited on
/// when the scope exits. If the group exits by throwing, all added tasks will
/// be cancelled and their results discarded.
///
/// ### Implicit awaiting
/// When the group returns it will implicitly await for all child tasks to
/// complete. The tasks are only cancelled if `cancelAll()` was invoked before
/// returning, the groups' task was cancelled, or the group body has thrown.
///
/// When results of tasks added to the group need to be collected, one can
/// gather their results using the following pattern:
///
/// while let result = await group.next() {
/// // some accumulation logic (e.g. sum += result)
/// }
///
/// It is also possible to collect results from the group by using its
/// `AsyncSequence` conformance, which enables its use in an asynchronous for-loop,
/// like this:
///
/// for await result in group {
/// // some accumulation logic (e.g. sum += result)
/// }
///
/// ### Cancellation
/// If the task that the group is running in is cancelled, the group becomes
/// cancelled and all child tasks created in the group are cancelled as well.
///
/// Since the `withTaskGroup` provided group is specifically non-throwing,
/// child tasks (or the group) cannot react to cancellation by throwing a
/// `CancellationError`, however they may interrupt their work and e.g. return
/// some best-effort approximation of their work.
///
/// If throwing is a good option for the kinds of tasks created by the group,
/// consider using the `withThrowingTaskGroup` function instead.
///
/// Postcondition:
/// Once `withTaskGroup` returns it is guaranteed that the `group` is *empty*.
///
/// This is achieved in the following way:
/// - if the body returns normally:
/// - the group will await any not yet complete tasks,
/// - once the `withTaskGroup` returns the group is guaranteed to be empty.
func withTaskGroup<ChildTaskResult: Sendable, GroupResult>(
of childTaskResult: ChildTaskResult.Type,
returning returnType: GroupResult.Type = GroupResult.self,
body: (inout TaskGroup<ChildTaskResult>) async -> GroupResult
) async -> GroupResult { ... }
/// Starts a new throwing task group which provides a scope in which a dynamic
/// number of tasks may be created.
///
/// Tasks added to the group by `group.addTask()` will automatically be awaited on
/// when the scope exits. If the group exits by throwing, all added tasks will
/// be cancelled and their results discarded.
///
/// ### Implicit awaiting
/// When the group returns it will implicitly await for all created tasks to
/// complete. The tasks are only cancelled if `cancelAll()` was invoked before
/// returning, the groups' task was cancelled, or the group body has thrown.
///
/// When results of tasks added to the group need to be collected, one can
/// gather their results using the following pattern:
///
/// while let result = await try group.next() {
/// // some accumulation logic (e.g. sum += result)
/// }
///
/// It is also possible to collect results from the group by using its
/// `AsyncSequence` conformance, which enables its use in an asynchronous for-loop,
/// like this:
///
/// for try await result in group {
/// // some accumulation logic (e.g. sum += result)
/// }
///
/// ### Thrown errors
/// When tasks are added to the group using the `group.addTask` function, they may
/// immediately begin executing. Even if their results are not collected explicitly
/// and such task throws, and was not yet cancelled, it may result in the `withTaskGroup`
/// throwing.
///
/// ### Cancellation
/// If the task that the group is running in is cancelled, the group becomes
/// cancelled and all child tasks created in the group are cancelled as well.
///
/// If an error is thrown out of the task group, all of its remaining tasks
/// will be cancelled and the `withTaskGroup` call will rethrow that error.
///
/// Individual tasks throwing results in their corresponding `try group.next()`
/// call throwing, giving a chance to handle individual errors or letting the
/// error be rethrown by the group.
///
/// Postcondition:
/// Once `withThrowingTaskGroup` returns it is guaranteed that the `group` is *empty*.
///
/// This is achieved in the following way:
/// - if the body returns normally:
/// - the group will await any not yet complete tasks,
/// - once the `withTaskGroup` returns the group is guaranteed to be empty.
/// - if the body throws:
/// - all tasks remaining in the group will be automatically cancelled.
func withThrowingTaskGroup<ChildTaskResult: Sendable, GroupResult>(
of childTaskResult: ChildTaskResult.Type,
returning returnType: GroupResult.Type = GroupResult.self,
body: (inout ThrowingTaskGroup<ChildTaskResult, Error>) async throws -> GroupResult
) async rethrows -> GroupResult { ... }
/// A group of tasks, each of which produces a result of type `TaskResult`.
struct TaskGroup<ChildTaskResult: Sendable> {
// No public initializers
}
TaskGroup
has no public initializers; instead, an instance of TaskGroup
is passed in to the body
function of withTaskGroup
. This instance should not be copied out of the body
function, because doing so can break the child task structure.
Note: Swift does not currently have a way to ensure that the task group passed into the
body
function is not copied elsewhere, so we therefore rely on programmer discipline in a similar manner to, e.g.,Array.withUnsafeBufferPointer
. However, in the case of task groups, we can at least provide a runtime assertion if one attempts to use the task group instance after its corresponding scope has ended.
The result of withTaskGroup
is the result produced by the body
function. The withThrowingTaskGroup
version of the function allows for the task group to throw, and if that happens all tasks it contained are implicitly cancelled (and awaited on) before rethrowing the error.
Note: Sadly it is not presently possible to implement this throwing/non-throwing functionality with a single function. The complex relationship of throwing
group.addTask
with a throwingnext
as well as corresponding throwing/non-throwingAsyncSequence
conformances make it impossible to implement all in one function/type today.
Note also that the withThrowingTaskGroup
uses a ThrowingTaskGroup<ChildTaskResult, Error>
, however specifying the type of that error is not possible. This is because this Failure parameter on the ThrowingTaskGroup
in only used as future-proof API in case Swift were to gain typed throwing at some point in time. This design makes no promises nor does it assume typed throws are actually going to happen though.
A task group guarantees that it will await
all tasks that were added to it before it returns.
This waiting can be performed either:
- by the code within the task group itself (e.g., using
next()
repeatedly until it returnsnil
, described below), or - implicitly in the task group itself when returning from the
body
.
By default, the task group will schedule child tasks added to the group on the default global concurrent executor. In the future it is likely that it will be possible to customize the executor tasks are started on with an optional executor parameter to addTask
.
Within the body
function, tasks may be added dynamically with the addTask
operation. Each task produces a value of the same type (the ChildTaskResult
generic parameter):
extension TaskGroup {
/// Unconditionally create a child task in the group.
///
/// The child task will be executing concurrently with the group, and its result
/// may be collected by calling `group.next()` or iterating over the group gathering
/// all submitted task results from the group.
mutating func addTask(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async -> ChildTaskResult
)
/// Attempts to create a child task in the group, unless the group is already cancelled.
///
/// If the task that initiates the call to `addTaskUnlessCancelled` was already cancelled,
/// or if the group was explicitly cancelled by invoking `group.cancelAll()`, no child
/// task will be created.
///
/// The child task will be executing concurrently with the group, and its result
/// may be collected by calling `group.next()` or iterating over the group gathering
/// all submitted task results from the group.
///
/// Returns true if the task was created successfully, and false otherwise.
mutating func addTaskUnlessCancelled(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async -> ChildTaskResult
) -> Bool
}
extension ThrowingTaskGroup {
mutating func addTask(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async throws -> ChildTaskResult
)
mutating func addTaskUnlessCancelled(
priority: TaskPriority? = nil,
operation: @Sendable @escaping () async throws -> ChildTaskResult
) -> Bool
}
group.addTask
creates a child task in the task group to execute the given operation
function concurrently. The task will be a child of the task that initially created the task group (via withTaskGroup
), and will have the same priority as that task unless given a new priority with as an argument. Generally, it is recommended to not specify priority manually.
The addTask
operation always succeeds in adding a new child task to the group, even if the task running the group has been cancelled or the group was cancelled explicitly with group.cancelAll
. In cases where the task group has already
been cancelled, the new child task will be created in the cancelled
state.
To avoid this, the addTaskUnlessCancelled
function checks if a group is cancelled before attempting to create the task, and returns a Bool
that is true if
the task was successfully created. This allows for simple implementation of groups which should "keep creating tasks until cancelled".
Cancelling a specific task group child task does not cancel the entire group or any of its siblings.
Previously the
group.addTask
operation was designed to be a suspension point, which was intended to be a simple form of back-pressure where the group could decide to not allow more than N tasks to be running concurrently. This has not been fully designed nor implemented though, so currently has been moved to a future direction.
The next()
operation allows one to gather the results from the tasks that have been created in the group. It produces the result from one of the tasks in the group, whether it is the normal result or a thrown error.
extension TaskGroup: AsyncSequence {
/// Wait for the a child task that was added to the group to complete,
/// and return (or rethrow) the value it completed with. If no tasks are
/// pending in the task group this function returns `nil`, allowing the
/// following convenient expressions to be written for awaiting for one
/// or all tasks to complete:
///
/// Await on a single completion:
///
/// if let first = try await group.next() {
/// return first
/// }
///
/// Wait and collect all group child task completions:
///
/// while let first = try await group.next() {
/// collected += value
/// }
/// return collected
///
/// Awaiting on an empty group results in the immediate return of a `nil`
/// value, without the group task having to suspend.
///
/// It is also possible to use `for await` to collect results of a task groups:
///
/// for await value in group {
/// collected += value
/// }
///
/// ### Thread-safety
/// Please note that the `group` object MUST NOT escape into another task.
/// The `group.next()` MUST be awaited from the task that had originally
/// created the group. It is not allowed to escape the group reference.
///
/// Note also that this is generally prevented by Swift's type-system,
/// as the `add` operation is `mutating`, and those may not be performed
/// from concurrent execution contexts, such as child tasks.
///
/// ### Ordering
/// Order of values returned by next() is *completion order*, and not
/// submission order. I.e. if tasks are added to the group one after another:
///
/// group.addTask { 1 }
/// group.addTask { 2 }
///
/// print(await group.next())
/// /// Prints "1" OR "2"
mutating func next() async -> ChildTaskResult? { ... }
/// Wait for all of the child tasks to complete.
///
/// This operation is the equivalent of
///
/// for await _ in self { }
///
mutating func waitForAll() async { ... }
/// Query whether the group has any remaining tasks.
///
/// Task groups are always empty upon entry to the `withTaskGroup` body, and
/// become empty again when `withTaskGroup` returns (either by awaiting on all
/// pending tasks or cancelling them).
///
/// - Returns: `true` if the group has no pending tasks, `false` otherwise.
var isEmpty: Bool { ... }
}
extension ThrowingTaskGroup: AsyncSequence {
/// Wait for the a child task that was added to the group to complete,
/// and return (or rethrow) the value it completed with. If no tasks are
/// pending in the task group this function returns `nil`, allowing the
/// following convenient expressions to be written for awaiting for one
/// or all tasks to complete:
///
/// Await on a single completion:
///
/// if let first = try await group.next() {
/// return first
/// }
///
/// Wait and collect all group child task completions:
///
/// while let first = try await group.next() {
/// collected += value
/// }
/// return collected
///
/// Awaiting on an empty group results in the immediate return of a `nil`
/// value, without the group task having to suspend.
///
/// It is also possible to use `for await` to collect results of a task groups:
///
/// for await try value in group {
/// collected += value
/// }
///
/// ### Thread-safety
/// Please note that the `group` object MUST NOT escape into another task.
/// The `group.next()` MUST be awaited from the task that had originally
/// created the group. It is not allowed to escape the group reference.
///
/// Note also that this is generally prevented by Swift's type-system,
/// as the `add` operation is `mutating`, and those may not be performed
/// from concurrent execution contexts, such as child tasks.
///
/// ### Ordering
/// Order of values returned by next() is *completion order*, and not
/// submission order. I.e. if tasks are added to the group one after another:
///
/// group.addTask { 1 }
/// group.addTask { 2 }
///
/// print(await group.next())
/// /// Prints "1" OR "2"
///
/// ### Errors
/// If an operation added to the group throws, that error will be rethrown
/// by the next() call corresponding to that operation's completion.
///
/// It is possible to directly rethrow such error out of a `withTaskGroup` body
/// function's body, causing all remaining tasks to be implicitly cancelled.
mutating func next() async throws -> ChildTaskResult? { ... }
/// Wait for a task to complete and return the result or thrown error packaged in
/// a `Result` instance. Returns `nil` only when there are no tasks left in the group.
mutating func nextResult() async -> Result<ChildTaskResult, Error>?
/// Wait for all of the child tasks to complete, or throws an error if any of the
/// child tasks throws.
///
/// This operation is the equivalent of
///
/// for try await _ in self { }
///
mutating func waitForAll() async throws { ... }
/// Query whether the task group has any remaining tasks.
var isEmpty: Bool { ... }
}
The next()
operation may typically be used within a while
loop to gather the results of all outstanding tasks in the group, e.g.,
while let result = await group.next() {
// some accumulation logic (e.g. sum += result)
}
// OR
while let result = try await group.next() {
// some accumulation logic (e.g. sum += result)
}
TaskGroup
also conforms to the AsyncSequence
protocol, allowing the child tasks' results to be iterated in a for await
loop:
for await result in group { // non-throwing TaskGroup
// some accumulation logic (e.g. sum += result)
}
// OR
for try await result in group { // ThrowingTaskGroup
// some accumulation logic (e.g. sum += result)
}
With this pattern, if a single task throws an error, the error will be propagated out of the body
function and the task group itself.
To handle errors from individual tasks, one can use a do-catch block or the nextResult()
method. For example, one might want to implement a function which starts N
tasks, and reports back the first m
successful results. This is simple to implement with a task group, by means of collecting results until the results
array have accumulated m
results, at which point we can cancel all remaining tasks and return from the group:
func gather(first m: Int, of work: [Work]) async throws -> [WorkResult] {
assert(m <= work.count)
return withTaskGroup(of: WorkResult.self) { group in
for w in work {
group.addTask { await w.doIt() } // create child tasks to perform the work
}
var results: [WorkResult] = []
while results.count <= m {
switch try await group.nextResult() {
case nil: return results
case .success(let r): results.append(r)
case .failure(let e): print("Ignore error: \(e)")
}
}
}
}
There are several ways in which a task group can be cancelled. In all cases, all of the tasks in the group are cancelled, and any new tasks created in the group will start out cancelled. The three ways in which a task group can be cancelled are:
- When an error is thrown out of the
body
ofwithTaskGroup
, - When the task in which the task group itself was created is cancelled, or
- When the
cancelAll()
operation is invoked.
A group's cancellation state can be queried by reading the isCancelled
property.
extension TaskGroup {
/// Cancel all the remaining tasks in the group.
///
/// A cancelled group will not will NOT accept new tasks being added into it.
///
/// Any results, including errors thrown by tasks affected by this
/// cancellation, are silently discarded.
///
/// This function may be called even from within child (or any other) tasks,
/// and will reliably cause the group to become cancelled.
///
/// - SeeAlso: `Task.isCancelled`
/// - SeeAlso: `TaskGroup.isCancelled`
func cancelAll() { ... }
/// Returns `true` if the group was cancelled, e.g. by `cancelAll`.
///
/// If the task currently running this group was cancelled, the group will
/// also be implicitly cancelled, which will be reflected in the return
/// value of this function as well.
///
/// - Returns: `true` if the group (or its parent task) was cancelled,
/// `false` otherwise.
var isCancelled: Bool { get }
}
For example:
func chopVegetables() async throws -> [Vegetable] {
var veggies: [Vegetable] = []
try await withThrowingTaskGroup(of: Vegetable.self) { group in
print(group.isCancelled) // prints false
group.addTask {
group.cancelAll() // Cancel all work in the group
throw UnfortunateAccidentWithKnifeError()
}
group.addTask {
return try await chop(Onion())
}
do {
while let veggie = try await group.next() {
veggies.append(veggie)
}
} catch {
print(group.isCancelled) // prints true now
let added = group.addTaskUnlessCancelled {
try await chop(SweetPotato())
}
print(added) // prints false, no child was added to the cancelled group
}
}
return veggies
}
This change is purely additive to the source language.
This change is purely additive to the ABI.
All of the changes described in this document are additive to the language and are locally scoped, e.g., within function bodies. Therefore, there is no effect on API resilience.
Changes after the fourth review:
- added
UnsafeCurrentTask.cancel()
to cancel the task.
Changes after the third review:
- renamed
Task.sleep(_:)
toTask.sleep(nanoseconds:)
. This makes it clear that the wait is in nanoseconds, and leaves API space open for asleep(_:)
based on a better duration type in the future. - made
Task.sleep(nanoseconds:)
throwing; it will throwCancellationError
if the sleeping task was cancelled. - renamed
TaskGroup.async
andTaskGroup.asyncUnlessCancelled
toTaskGroup.addTask
andTaskGroup.addTaskUnlessCancelled
. The fundamental behavior here is that we're adding a task to the group.add
by itself does not suffice, because we aren't adding a value (accessible vianext()
), we are adding a task whose value will be accessible vianext()
. It also parallels the use ofTask { ... }
to create top-level tasks. - renamed
TaskPriority.default
toTaskPriority.medium
, becausenil
passed in to aTaskPriority?
parameter is effectively the default for most APIs. - added
TaskGroup.waitForAll
andThrowingTaskGroup.waitForAll
. - renamed
Task.yield()
toTask.suspend()
, which more accurately represents what this operation action does, and leaves the name "yield" for future work on generators.
Changes after the second review:
- remove
Priority.unspecified
and usenil
as unspecified value. - introduce platform independent priority names:
high
,default
,low
,background
. The Apple platform specific names remain as aliases and can be used on apple platforms where they make sense. These names have a long history and were even originally used in dispatch itself. We discussed and confirmed with various teams inside Apple that those names work well for the future evolution of the platform. - future-proof the
TaskPriority
type by changing it to aRawRepresentable
struct
with static computed properties. We do not immediately have any plans to introduce new priorities, but want to allow for such future extension if necessary. - remove the ability to create new tasks at the
userInteractive
priority. This priority will be used only be the runtime itself, e.g. by the main thread and automatically inherited properly by any other tasks (and downgraded touserInitiated
) TaskGroup.spawn
andTaskGroup.spawnUnlessCancelled
have been renamed toTaskGroup.async
andTaskGroup.asyncUnlessCancelled
.- remove
Task.current
and the general ability to get hold of a child task instance. This change unlocks important optimizations in the compiler and runtime - collapse
Task.Handle<Success, Failure>
intoTask<Success, Failure>
. This is the most-used type in the Task API and should have the shortest name. - merge the
async { }
proposal (pitched here) into this proposal, such that we have always to create tasks in this proposal to review at-once, and make it the task instance initializerTask { ... }
- rename
detach
toTask.detached
as it is similar, but less favored to use that API. - re-order parameters of
withTaskCancellationHandler
fromhandler, operation
to(operation, onCancel handler)
which seems to be a more common pattern for such APIs where the "main closure" (the operation) comes first - move
Task.Priority
out toTaskPriority
andTask.CancellationError
out to the top-levelCancellationError
- replace
get()
with an async propertyvalue
, andgetResult()
with an async propertyresult
Changes after first review:
Task.current
now returns an optionalTask
:var current: Task? { get }
, which depending on context it is called from might benil
.- This API is not intended to be used "a lot", and if sure a task will be available one can always force unwrap it.
- Most usages of tasks are rather intended to go through the static functions/properties on Task which implicitly works on the current task.
Task.unsafeCurrent
becomes a top-levelwithUnsafeCurrentTask { maybeUnsafeTask in }
- This better explains the intended semantics of not escaping storing the unsafe task reference.
- Adopt
spawn...
terminology for "spawning tasks"TaskGroup
'sgroup.add
becomesgroup.spawn
- Creating a child task will eventually be
spawn <something>
- Based on feedback,
runDetached
becomesdetach
because of how often it may be necessary to reach for. - Moving away from using
Task
as namespace for everything- rename
TaskGroup
toTaskGroup
, and introduceThrowingTaskGroup
- make
Task.unsafeCurrent
a free functionwithUnsafeCurrentTask
- rename
- Task group type parameter renames:
TaskGroup<TaskResult>
becomesChildTaskResult
resulting in:public func withTaskGroup<ChildTaskResult, GroupResult>(of childTaskResultType: ChildTaskResult.Type, returning returnType: GroupResult.Type = GroupResult.self, body: (inout TaskGroup<ChildTaskResult>) async throws -> GroupResult) async rethrows -> GroupResult
resulting in a more readable call site:withTaskGroup(of: Int.self)
and optionallywithTaskGroup(of: Int.self, returning: Int.self)
- For now remove
startingChildTasksOn
fromwithTaskGroup
since this is only doable with Custom Executors which are pending review still. - Move
Task.withCancellationHandler
to a top level functionwithTaskCancellationHandler
which reads more logically, as it does not create a task by itself. - Make
group.spawn
returnTaskGroup.Spawned
that serves both the purpose of knowing if the task wasspawned.successfully
and also obtaining theTask.Handle
of a successfully spawned task. Thanks to Paulo Faria for reminding us to revisit this topic. - The spawn parameter
overridingPriority
has been renamed topriority
not to confuse existing users on Apple platforms where "override" has the specific meaning more similar to what we call "priority escalation". - Task group
spawn
now always spawns a child task rather than only when the group is not cancelled. - Task groups gain
spawnUnlessCancelled -> Bool
which explains the semantics intended by the previous spawn signature more clearly. The returned value is just a boolean signalling if the spawn was successfully or not. - Some functions were accepting
Task.Priority?
which is unnecessary because we have.unspecified
, so those functions now acceptTask.Priority
defaulting it to.unspecified
- Changes in the third pitch:
- Factored
with*Continuation
into its own proposal. - Factored
async let
into its own proposal. Task
becomes astruct
with instance functions, introduction ofTask.current
,Task.unsafeCurrent
and theUnsafeCurrentTask
APIsTask.Group
now conforms to theAsyncSequence
protocol.runDetached
andTask.Group.add
now accept executor arguments to specify where the newly-spawned tasks are initially scheduled.
- Factored
- Changes in the second pitch:
- Added a "desugaring" of
async let
to task groups and more motivation for the structured-concurrency parts of the design. - Reflowed the entire proposal to focus on the general description of structured concurrency first, the programming model with syntax next, and then details of the language features and API design last.
- Reworked the presentation of the Task APIs with more rationale for the design.
- Added more discussion of why futures aren't more prominent.
- "Task nursery" has been replaced with "task group".
- Added support for asynchronous
@main
and top-level code. - Specify that
try
is not required in the initializer of anasync let
, because the thrown error is only observable when reading from one of the variables. withUnsafe(Throwing)Continuation
functions have been moved out of theTask
type.- Note that an
async let
variable can only be captured by a non-escaping closure. - Removed the requirement that an
async let
variable be awaited on all paths.
- Added a "desugaring" of
- Original pitch document
The design of task groups intentionally avoids exposing any task handles (futures) for child tasks. This ensures that the structure of structured concurrency, where all child tasks complete before their parent task, is maintained. That helps various properties such as priorities, deadlines, and cancellation to propagate in a meaningful way down the task tree.
However, an alternative design would bring futures to the forefront. One could introduce a new runChild
operation that creates a new child task (of the current task), and then retrieve the result of that child task using the provided Task
. To ensure that child tasks complete before the scope exits, we would require some kind of scoping mechanism that provides similar behavior to task groups. For example, the makeDinner
example would be something like:
func makeDinner() async throws -> Meal {
Task.withChildScope { scope in
let veggiesHandle = scope.runChild { try await chopVegetables() }
let meatHandle = scope.runChild { await marinateMeat() }
let ovenHandle = scope.runChild { await preheatOven(temperature: 350) }
let dish = Dish(ingredients: await [try veggiesHandle.get(), meatHandle.get()])
return try await ovenHandle.get().cook(dish, duration: .hours(3))
}
}
The task handles produced by runChild
should never escape the scope in which they are created, although there is no language mechanism to enforce this. Moreover, the difference between detached and child tasks becomes blurred: both return the same Task
type, but some have extra restrictions while others don't. So while it is possible to maintain structured concurrency with a future-centric design, it requires more programmer discipline (even for otherwise simple tasks), and provides less structure for the Swift compiler, optimizer, and runtime to use to provide an efficient implementation of child tasks.
Although our design de-emphasizes futures for structured tasks, for the reasons
delineated above, we acknowledge that it will be common to want to pass
heterogeneous values up from child tasks to their parent. This is possible
within the existing task group APIs, though not ideal, as illustrated by the
original makeDinner
example.
SE-0317 async let
provides syntactic sugar for the
creation of heterogenous child tasks, capturing their values in local
variables that use effectful properties
to wait for the result of the child task's completion. For example, this allows
the makeDinner
example to be written as:
func makeDinner() async throws -> Meal {
async let veggies = chopVegetables()
async let meat = marinateMeat()
async let oven = preheatOven(temperature: 350)
let dish = Dish(ingredients: await [try veggies, meat])
return await oven.cook(dish, duration: .hours(3))
}
This provides a lightweight syntax for a very common dataflow pattern between child tasks and parents within a task group.
In addition to async let
, the scoped nature of task groups and child tasks would make it natural for child tasks to be able to do more ad-hoc mutation of captured state from their captured context. Because child tasks are guaranteed to
have completed by the time a withTaskGroup
block finishes executing, it would theoretically be safe to allow them to mutate captured local variables, as long as every child task captures a disjoint set of variables, and the variables are not referenced in the enclosing context until the task group completes, as in:
var numApplesProcessed = 0
var numBananasProcessed = 0
withTaskGroup { group in
// One child task handles apples:
group.addTask {
for apple in apples {
await processApple(apple)
numApplesProcessed += 1
}
}
// And one child task handles bananas:
group.addTask {
for banana in bananas {
await processBanana(banana)
numBananasProcessed += 1
}
}
}
print("\(numApplesProcessed + numBananasProcessed) fruits processed")
However, Swift's type checker does not have any special knowledge of withTaskGroup
, and a conservative analysis of the @Sendable
closures for each child
task has to assume that the closures could be executed at any time, and so apply
the usual rules banning capture of mutated variables. To allow for a more
natural coding style in these situations, it would be useful if the analysis
understood the special behavior of task groups and allowed for mutation in
captures when it's safe in cases like this.
Initially the group.addTask
operation was designed with the idea of being an asynchronous function which might suspend if the group determined that it is "too full" and should apply this naive form of back-pressure to the task creating more tasks into the group.
This was not implemented nor is it clear how efficient and meaningful this form of back-pressure really would be. A naive version of these semantics is possible to implement by balancing pending and completed task counts in the group by plain variables, so removing this implementation does not prevent developers from implementing such "width limited" operations per se.
The way to back-pressure submissions should also be considered in terms of how it relates to async let and general task creation mechanisms, not only groups. We have not figured this out completely, and rather than introduce an not-implemented API which may or may not have the right shape, for now we decided to punt on this feature until we know precisely if and how to apply this style of back-pressure on creating tasks throughout the system.
When this proposal was originally accepted, the description of withThrowingTaskGroup
stated that any remaining tasks in the group will be cancelled if any task throws after the body function returns normally. This behavior was never implemented; throws from tasks are ignored in this state. By the time this discrepancy was detected, several years had passed, and the Language Steering Group decided that restoring the proposed behavior (if desired) would require a new proposal. This document has been revised to reflect the implemented behavior.