Revealed on: September 13, 2022
One of many objectives of the Swift crew with Swift’s concurrency options is to offer a mannequin that permits developer to write down secure code by default. Which means that there’s a whole lot of time and vitality invested into ensuring that the Swift compiler helps builders detect, and forestall complete lessons of bugs and concurrency points altogether.
One of many options that helps you forestall information races (a standard concurrency challenge) comes within the type of actors which I’ve written about earlier than.
Whereas actors are nice whenever you need to synchronize entry to some mutable state, they don’t resolve each attainable challenge you may need in concurrent code.
On this put up, we’re going to take a better have a look at the Sendable protocol, and the @Sendable annotation for closures. By the tip of this put up, it’s best to have an excellent understanding of the issues that Sendable (and @Sendable) intention to resolve, how they work, and the way you should utilize them in your code.
Understanding the issues solved by Sendable
One of many trickiest features of a concurrent program is to make sure information consistency. Or in different phrases, thread security. After we move cases of lessons or structs, enum circumstances, and even closures round in an utility that doesn’t do a lot concurrent work, we don’t want to fret about thread security loads. In apps that don’t actually carry out concurrent work, it’s unlikely that two duties try to entry and / or mutate a bit of state at the very same time. (However not unattainable)
For instance, you may be grabbing information from the community, after which passing the obtained information round to a few features in your important thread.
As a result of nature of the principle thread, you’ll be able to safely assume that your whole code runs sequentially, and no two processes in your utility shall be engaged on the identical referencea on the similar time, doubtlessly creating an information race.
To briefly outline an information race, it’s when two or extra components of your code try to entry the identical information in reminiscence, and at the very least one in every of these accesses is a write motion. When this occurs, you’ll be able to by no means be sure in regards to the order through which the reads and writes occur, and you’ll even run into crashes for dangerous reminiscence accesses. All in all, information races aren’t any enjoyable.
Whereas actors are a implausible option to construct objects that appropriately isolate and synchronize entry to their mutable state, they’ll’t resolve all of our information races. And extra importantly, it won’t be cheap so that you can rewrite your whole code to utilize actors.
Think about one thing like the next code:
class FormatterCache {
var formatters = [String: DateFormatter]()
func formatter(for format: String) -> DateFormatter {
if let formatter = formatters[format] {
return formatter
}
let formatter = DateFormatter()
formatter.dateFormat = format
formatters[format] = formatter
return formatter
}
}
func performWork() async {
let cache = FormatterCache()
let possibleFormatters = ["YYYYMMDD", "YYYY", "YYYY-MM-DD"]
await withTaskGroup(of: Void.self) { group in
for _ in 0..<10 {
group.addTask {
let format = possibleFormatters.randomElement()!
let formatter = cache.formatter(for: format)
}
}
}
}On first look, this code won’t look too dangerous. We now have a category that acts as a easy cache for date formatters, and we’ve a job group that can run a bunch of code in parallel. Every job will seize a random date format from the record of attainable format and asks the cache for a date formatter.
Ideally, we anticipate the formatter cache to solely create one date formatter for every date format, and return a cached formatter after a formatter has been created.
Nevertheless, as a result of our duties run in parallel there’s an opportunity for information races right here. One fast repair could be to make our FormatterCache an actor and this is able to resolve our potential information race. Whereas that will be an excellent answer (and truly one of the best answer in the event you ask me) the compiler tells us one thing else once we attempt to compile the code above:
Seize of ‘cache’ with non-sendable kind ‘FormatterCache’ in a
@Sendableclosure
This warning is making an attempt to inform us that we’re doing one thing that’s doubtlessly harmful. We’re capturing a worth that can not be safely handed via concurrency boundaries in a closure that’s purported to be safely handed via concurrency boundaries.
⚠️ If the instance above doesn’t produce a warning for you, you will need to allow strict concurrency checking in your undertaking’s construct settings for stricter Sendable checks (amongst different concurrency checks). You possibly can allow strict concurrecy settings in your goal’s construct settings. Check out this web page in the event you’re undecided how to do that.
With the ability to be safely handed via concurrency boundaries basically signifies that a worth could be safely accessed and mutated from a number of duties concurrently with out inflicting information races. Swift makes use of the Sendable protocol and the @Sendable annotation to speak this thread-safety requirement to the compiler, and the compiler can then examine whether or not an object is certainly Sendable by assembly the Sendable necessities.
What these necessities are precisely will differ a bit relying on the kind of objects you take care of. For instance, actor objects are Sendable by default as a result of they’ve information security built-in.
Let’s check out different forms of objects to see what their Sendable necessities are precisely.
Sendable and worth sorts
In Swift, worth sorts present a whole lot of thread security out of the field. Once you move a worth kind from one place to the following, a duplicate is created which signifies that every place that holds a duplicate of your worth kind can freely mutate its copy with out affecting different components of the code.
This an enormous advantage of structs over lessons as a result of they permit use to purpose regionally about our code with out having to think about whether or not different components of our code have a reference to the identical occasion of our object.
Due to this habits, worth sorts like structs and enums are Sendable by default so long as all of their members are additionally Sendable.
Let’s have a look at an instance:
// This struct shouldn't be sendable
struct Film {
let formatterCache = FormatterCache()
let releaseDate = Date()
var formattedReleaseDate: String {
let formatter = formatterCache.formatter(for: "YYYY")
return formatter.string(from: releaseDate)
}
}
// This struct is sendable
struct Film {
var formattedReleaseDate = "2022"
}I do know that this instance is a bit bizarre; they don’t have the very same performance however that’s not the purpose.
The purpose is that the primary struct does probably not maintain mutable state; all of its properties are both constants, or they’re computed properties. Nevertheless, FormatterCache is a category that is not Sendable. Since our Film struct doesn’t maintain a duplicate of the FormatterCache however a reference, all copies of Film could be wanting on the similar cases of the FormatterCache, which signifies that we may be information races if a number of Film copies would try to, for instance, work together with the formatterCache.
The second struct solely holds Sendable state. String is Sendable and because it’s the one property outlined on Film, film can be Sendable.
The rule right here is that every one worth sorts are Sendable so long as their members are additionally Sendable.
Typically talking, the compiler will infer your structs to be Sendable when wanted. Nevertheless, you’ll be able to manually add Sendable conformance if you would like:
struct Film: Sendable {
let formatterCache = FormatterCache()
let releaseDate = Date()
var formattedReleaseDate: String {
let formatter = formatterCache.formatter(for: "YYYY")
return formatter.string(from: releaseDate)
}
}Sendable and lessons
Whereas each structs and actors are implicitly Sendable, lessons will not be. That’s as a result of lessons are loads much less secure by their nature; everyone that receives an occasion of a category really receives a reference to that occasion. Which means that a number of locations in your code maintain a reference to the very same reminiscence location and all mutations you make on a category occasion are shared amongst everyone that holds a reference to that class occasion.
That doesn’t imply we will’t make our lessons Sendable, it simply signifies that we have to add the conformance manually, and manually be certain that our lessons are literally Sendable.
We will make our lessons Sendable by including conformance to the Sendable protocol:
closing class Film: Sendable {
let formattedReleaseDate = "2022"
}The necessities for a category to be Sendable are much like these for a struct.
For instance, a category can solely be Sendable if all of its members are Sendable. Which means that they need to both be Sendable lessons, worth sorts, or actors. This requirement is equivalent to the necessities for Sendable structs.
Along with this requirement, your class should be closing. Inheritance may break your Sendable conformance if a subclass provides incompatible overrides or options. For that reason, solely closing lessons could be made Sendable.
Lastly, your Sendable class mustn’t maintain any mutable state. Mutable state would imply that a number of duties can try to mutate your state, main to a knowledge race.
Nevertheless, there are cases the place we’d know a category or struct is secure to be handed throughout concurrency boundaries even when the compiler can’t show it.
In these circumstances, we will fall again on unchecked Sendable conformance.
Unchecked Sendable conformance
Once you’re working with codebases that predate Swift Concurrency, likelihood is that you just’re slowly working your manner via your app with the intention to introduce concurrency options. Which means that a few of your objects might want to work in your async code, in addition to in your sync code. Which means that utilizing actor to isolate mutable state in a reference kind won’t work so that you’re caught with a category that may’t conform to Sendable. For instance, you may need one thing like the next code:
class FormatterCache {
privatevar formatters = [String: DateFormatter]()
non-public let queue = DispatchQueue(label: "com.dw.FormatterCache.(UUID().uuidString)")
func formatter(for format: String) -> DateFormatter {
return queue.sync {
if let formatter = formatters[format] {
return formatter
}
let formatter = DateFormatter()
formatter.dateFormat = format
formatters[format] = formatter
return formatter
}
}
}This formatter cache makes use of a serial queue to make sure synchronized entry to its formatters dictionary. Whereas the implementation isn’t best (we could possibly be utilizing a barrier or possibly even a plain outdated lock as an alternative), it really works. Nevertheless, we will’t add Sendable conformance to our class as a result of formatters isn’t Sendable.
To repair this, we will add @unchecked Sendable conformance to our FormatterCache:
class FormatterCache: @unchecked Sendable {
// implementation unchanged
}By including this @unchecked Sendable we’re instructing the compiler to imagine that our FormatterCache is Sendable even when it doesn’t meet the entire necessities.
Having this function in our toolbox is extremely helpful whenever you’re slowly phasing Swift Concurrency into an current undertaking, however you’ll need to assume twice, or possibly even thrice, whenever you’re reaching for @unchecked Sendable. You need to solely use this function whenever you’re actually sure that your code is definitely secure for use in a concurrent setting.
Utilizing @Sendable on closures
There’s one final place the place Sendable comes into play and that’s on features and closures.
Numerous closures in Swift Concurrency are annotated with the @Sendable annotation. For instance, right here’s what the declaration for TaskGroup‘s addTask appears like:
public mutating func addTask(precedence: TaskPriority? = nil, operation: @escaping @Sendable () async -> ChildTaskResult)The operation closure that’s handed to addTask is marked with @Sendable. Which means that any state that the closure captures should be Sendable as a result of the closure may be handed throughout concurrency boundaries.
In different phrases, this closure will run in a concurrent method so we need to make it possible for we’re not by chance introducing an information race. If all state captured by the closure is Sendable, then we all know for positive that the closure itself is Sendable. Or in different phrases, we all know that the closure can safely be handed round in a concurrent setting.
Tip: to be taught extra about closures in Swift, check out my put up that explains closures in nice element.
Abstract
On this put up, you’ve realized in regards to the Sendable and @Sendable options of Swift Concurrency. You realized why concurrent packages require additional security round mutable state, and state that’s handed throughout concurrency boundaries with the intention to keep away from information races.
You realized that structs are implicitly Sendable if all of their members are Sendable. You additionally realized that lessons could be made Sendable so long as they’re closing, and so long as all of their members are additionally Sendable.
Lastly, you realized that the @Sendable annotation for closures helps the compiler be certain that all state captured in a closure is Sendable and that it’s secure to name that closure in a concurrent context.
I hope you’ve loved this put up. When you’ve got any questions, suggestions, or options to assist me enhance the reference then be happy to succeed in out to me on Twitter.
