One challenge when it comes to concurrency on Apple’s platforms is that an app’s UI can, for the most part, only be updated on the main thread. So, whenever we’re performing any kind of work on a background thread (either directly or indirectly), then we always have to make sure to jump back to the main queue before accessing any property, method, or function that has to do with rendering our UI.

In theory, that might sound simple. In practice, it’s very common to accidentally perform UI updates on a background queue — which can cause glitches, or even put an app in an inconsistent or undefined state, which in turn might lead to crashes and other errors.

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Manual main queue dispatching

So far, the most commonly used solution to this problem has been to wrap all UI-related updates in asynchronous calls to DispatchQueue.main, when there’s any chance that those updates will be triggered on a background queue — for example in situations like this:

class ProfileViewController: UIViewController {
    private let userID: User.ID
    private let loader: UserLoader
    private lazy var nameLabel = UILabel()
    private lazy var biographyLabel = UILabel()
    ...

    private func loadUser() {
        loader.loadUser { [weak self] result in
            DispatchQueue.main.async {
                switch result {
                case .success(let user):
                    self?.nameLabel.text = user.name
                    self?.biographyLabel.text = user.biography
                case .failure(let error):
                    self?.showError(error)
                }
            }
        }
    }
}

While the above pattern certainly works, always having to remember to perform those DispatchQueue.main calls is definitely not very convenient, and quite error-prone as well. That’s especially true in situations when it might not be completely obvious that a given piece of code could indeed be run on a background queue, such as when observing Combine publishers, or when implementing certain delegate methods.

The main actor

Thankfully, Swift 5.5 is introducing what will likely become a much more robust and almost entirely automatic solution to this very common problem — the main actor. While we’ll explore Swift’s implementation of the Actor pattern in much more detail in future articles, for this particular use case, all that we really need to know is that this new, built-in actor implementation ensures that all work that’s being run on it is always performed on the main queue.

Please note that, at the time of writing, Swift 5.5 is currently in beta as part of Xcode 13.

So how exactly do we “run” our code on that main actor? The first thing that we have to do is to make our asynchronous code use the new async/await pattern, which is also being introduced as part of Swift 5.5’s suite of concurrency features. In this case, that could be done by creating a new, async/await-powered version of the loadUser method that our above view controller is calling — which simply involves wrapping a call to its default, completion handler-based version using Swift’s new continuation API:

extension UserLoader {
    func loadUser() async throws -> User {
        try await withCheckedThrowingContinuation { continuation in
            loadUser { result in
                switch result {
                case .success(let user):
                    continuation.resume(returning: user)
                case .failure(let error):
                    continuation.resume(throwing: error)
                }
            }
        }
    }
}

To learn more about the above pattern, check out my friend Vincent Pradeilles’ WWDC by Sundell & Friends article “Wrapping completion handlers into async APIs”.

With the above in place, we can now use an async block, along with Swift’s standard do, try catch error handling mechanism, to call our loader’s new async/await-powered API from within our ProfileViewController:

class ProfileViewController: UIViewController {
    ...
    
    private func loadUser() {
        async {
            do {
                let user = try await loader.loadUser()
                nameLabel.text = user.name
                biographyLabel.text = user.biography
            } catch {
                showError(error)
            }
        }
    }
}

But wait, how can the above work without any calls to DispatchQueue.main.async? If loadUser performs its work on a background queue, won’t that mean that our UI will now be incorrectly updated on a background queue as well?

That’s where the main actor comes in. If we take a look at the declarations for both UILabel and UIViewController, we can see that they’ve both been annotated with the new @MainActor attribute:

@MainActor class UILabel: UIView
@MainActor class UIViewController: UIResponder

What that means is that, when using Swift’s new concurrency system, all properties and methods on those classes (and any of their subclasses, including our ProfileViewController) will automatically be set, called, and accessed on the main queue. All those calls will automatically be routed through the system-provided MainActor, which always performs all of its work on the main thread — completely eliminating the need for us to manually call DispatchQueue.main.async. Really cool!

Custom UI-related classes

But what if we’re instead working on a completely custom type that we’d also like to gain the above kind of capability? For example, when implementing an ObservableObject that’s used within a SwiftUI view, we need to make sure to only assign its @Published-marked properties on the main queue, so wouldn’t it be great if we could also leverage the MainActor in those cases as well?

The good news is — we can! Just like how many of UIKit’s built-in classes are now annotated with @MainActor, we can apply that attribute to our own classes as well — giving them that same automatic main thread-dispatching behavior:

@MainActor class ListViewModel: ObservableObject {
    @Published private(set) var result: Result<[Item], Error>?
    private let loader: ItemLoader
    ...

    func load() {
        async {
            do {
                let items = try await loader.loadItems()
                result = .success(items)
            } catch {
                result = .failure(error)
            }
        }
    }
}

One thing that’s very important to point out, though, is that all of this only works when we’re using Swift’s new concurrency system. So when using other concurrency patterns, for example completion handlers, then the @MainActor attribute has no effect — meaning that the following code will still cause our result property to be incorrectly assigned on a background queue:

@MainActor class ListViewModel: ObservableObject {
    ...

    func load() {
        loader.loadItems { [weak self] result in
    self?.result = result
}
    }
}

At first, that might seem like a strange limitation, but it does make sense when considering that actors can only be accessed asynchronously, using the new async/await system. So if we’re operating in a completely synchronous context (which our above completion handler actually is, even if it might be called on a background thread) there’s no way for the system to automatically dispatch that code onto the main actor.

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Conclusion

Over time, once most of our asynchronous code has been migrated to Swift’s new concurrency system, the MainActor is hopefully going to more or less eliminate the need for us to manually dispatch our UI updates on the main queue. Of course, that doesn’t mean that we no longer have to consider threading and other concurrency issues when designing our APIs and our architecture — but at least that very common issue of accidentally performing UI updates on a background queue can, at some point, hopefully become a problem of the past.

For much more on Swift’s new concurrency system, make sure to listen to my podcast conversation with Doug Gregor from Apple, and stay tuned to Swift by Sundell for many more articles on async/await, actors, and structured concurrency within the coming weeks and months.

Thanks for reading!

With the start of WWDC21 just around the corner, I’d like to continue the tradition that I started in 2019, and share some of my biggest hopes and dreams for this year’s edition of the conference.

Note that these are really not predictions, nor are they based on any kind of insider information. It’s just me sharing some of my personal Swift-related WWDC dreams with you.

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Powerful SwiftUI customization

I absolutely love SwiftUI (so much so that I’m kind of porting it to the web), but that doesn’t mean that it’s perfect. In fact, being just shy of two years old at this point, it’s still a very young framework that has yet to become as feature-complete, flexible and powerful as tools like UIKit and AppKit are.

One of the key improvements that I’d like to see this year — that would unlock a lot of that additional power and flexibility — is for Apple to add proper, fully baked customization APIs to the entire suite of system views that the framework ships with.

For example, like we took a look at in “Encapsulating SwiftUI view styles”, the ButtonStyle protocol already enables us to perform very custom, finely grained customization when it comes to how Button views are styled:

struct ActionButtonStyle: ButtonStyle {
    func makeBody(configuration: Configuration) -> some View {
        configuration.label
            .foregroundColor(.white)
            .font(Font.body.bold())
            .padding(10)
            .padding(.horizontal, 20)
            .background(Color.blue)
            .cornerRadius(10)
    }
}

What makes styles defined using the above protocol so powerful is that they can be applied to an entire view hierarchy at once — making it possible to very neatly separate an app’s styling and theming code from the specific logic that’s contained within each individual view. In fact, if we wanted to, we could even style all of the buttons within an entire SwiftUI-based application simply by doing this:

@main struct MyApp: App {
    var body: some Scene {
        WindowGroup {
            RootView().buttonStyle(ActionButtonStyle())
        }
    }
}

However, while SwiftUI already ships with a number of other styling protocols that work the exact same way as ButtonStyle, many of them are currently not available for us third-party developers to implement. Take the NavigationViewStyle protocol, for example. If we take a look at its public definition by command-clicking it in Xcode, all that we’ll see is this:

public protocol NavigationViewStyle {
}

The same thing is true for other, similar protocols as well — including ListStyle, MenuButtonStyle, PickerStyle, and so on. So, my wish would be for Apple to open up those protocols so that we’ll be able to write custom styles for more or less any built-in SwiftUI view, not just for a few select ones, like Button and Label. I think that could solve many of the styling-related issues that lots of developers (myself included) have faced when adopting SwiftUI within apps that require more custom-looking UIs.

For example, the above kind of customization APIs could enable us to style navigation and tab bars, to (finally) be able to remove list cell separators, and to perform other kinds of common tweaks that UIKit and AppKit make super simple, but SwiftUI currently makes close to impossible (without resorting to some form of UIAppearance or subview hacking).

I think that SwiftUI already has a quite broad coverage when it comes to the types of views that it supports, so (at least from my perspective) it would make a ton of sense for Apple to instead focus on depth this year — to make the views that SwiftUI already offers much more flexible, powerful, and customizable.

Async/await all the things!

With concurrency being such a strong focus of Swift 5.5 (which I’ll cover in much more detail once I’ve had a chance to use it to write proper production code), I’d love to see Apple update many of the asynchronous APIs that ship as part of their SDKs to take full advantage of features like async/await.

For example, imagine being able to perform a URLSession-based network call like this:

let response = try await URLSession.shared.dataTask(for: url)

Or to request push notification permissions like this:

let center = UNUserNotificationCenter.current()
let isAuthorized = try await center.requestAuthorization()

While Combine already enables us to perform many kinds of asynchronous tasks in really powerful ways, if Apple were to fully embrace Swift’s new first-class concurrency features, I think that would both serve as great examples for the community to follow, and would make it much easier for us to adopt those features within our own code as well.

Plus, those new APIs would very likely be purely additive to the existing ones, meaning that (just like when Combine was introduced) we’d be able to migrate to them piece-by-piece, at our own pace.

Interactive widgets

To say that iOS 14’s introduction of WidgetKit has turned out to be successful is almost an understatement — with the new home screen widgets reaching very widespread adoption, not just among developers and tech enthusiasts, but also within the wider iOS user base (in big part thanks to the incredible work by Widgetsmith creator David Smith, who I had the true pleasure of talking to on the podcast a while back).

However, in their current shape, widgets are quite limited in terms of what kinds of user interactions that they can accept — with deep links into the host application being the only real way to implement custom interaction logic. Now, I completely understand why Apple made that decision. After all, like Eliza Block explained when she was a guest on the podcast last year, a widget’s UI isn’t actually constantly running on the home screen, but is rather rendered by the system based on serialized snapshots that are stored on disk, mostly for performance and energy efficiency reasons.

So if the system is essentially rendering all widgets as completely static view hierarchies that are computed up-front (by a widget’s backing TimelineProvider), how could Apple enable us to write custom interaction code within that context, without fundamentally changing the way widgets work?

One idea that comes to mind is that some form of event-based message-passing system could be introduced, that would enable a given widget’s timeline entry views to trigger custom events, for example using something like a built-in EventButton:

struct ArticleWidgetEntryView: View {
    var entry: ArticleEntry

    var body: some View {
        VStack(alignment: .leading, spacing: 5) {
            Text(entry.article.title)
                .bold()
            Text(entry.article.description)
                .foregroundColor(.secondary)
                .font(.footnote)
            EventButton(
    systemImage: "heart.fill",
    event: ArticleWidget.Event.toggleFavorite
)
        }
        .padding()
    }
}

Since the above doesn’t involve executing any arbitrary view-level code in response to user interactions, it would still let the system remain in complete control over the rendering and lifecycle of all widget UIs.

Because WidgetKit is Swift(UI)-only, the above Event type could then very likely be referenced by both the main Widget definition, and its TimelineProvider, in a completely type-safe way — rather than having to pass either raw strings or userInfo-style dictionaries around.

For example, perhaps the TimelineProvider protocol (or a specialized version of it) could gain a new method that would be passed any Event that was triggered (as well as the entry that triggered it), which in turn would let us run completely custom code in response to that, while still enabling the system to keep using its snapshot-based rendering strategy.

Rock-solid tooling

Although the overall quality of Swift’s tooling and the way it’s integrated into Xcode has certainly improved since when the language was first introduced, it remains one of the most significant drawbacks of Swift as a whole. It’s still, in 2021, very common for autocomplete to completely stop working, for syntax highlighting to disappear, and for obscure error messages to be shown when a compilation failure occurred — even within relatively simple projects.

I realize that these are not easy problems to solve, especially given Swift’s overall complexity and very rapid evolution, but if I could just pick a single item from this list of dreams, then it’d be this one. There’s just so many things to like about Swift, UIKit, SwiftUI, and the rest of Apple’s frameworks and SDKs, and for all of its flaws, I think that Xcode is actually a quite fantastic development environment overall — I just really wish that the basic editing experience would get elevated to the very high level of quality that I’ve come to expect from Apple products.

That’s not to say that all of Swift’s tooling is flawed. Take the Swift Package Manager for example — overall, it’s by far the most stable and easy-to-use dependency management system that I’ve ever used (and I don’t mean that as an insult to any of the other package managers out there). Basically, when using SwiftPM, dependency management has mostly become a solved problem, at least for me and the teams that I work with. It’s fast, reliable, and powerful. The same thing can now also be said for Xcode’s new build system, and many other parts of the overall experience of developing apps for Apple’s platforms.

So, what I’m hoping for is for some of the rough edges to be smoothened out, and I’m sure that we’ll get there one day. Let’s see if Xcode 13’s release day will be that day.

Remaining 2020 dreams

Finally, I’d also still love to see some of my remaining 2020 dreams eventually become reality.

Xcode on iPad is something that I’ve long been wishing for. I know that not everyone wants to write code on an iPad, but I really do, especially when traveling or when working outside. That doesn’t mean that I’d stop using my M1 Mac mini if an iPad version of Xcode would be released next week — it would just mean that I’d have an additional device that I, and others, could build apps and libraries on.

Swift Playgrounds is an amazing tool for learning, prototyping and experimentation — but it’s not an IDE for building proper apps and Swift packages, and it was never intended to be. I think at this point in its lifecycle, the iPad should become a computing platform that’s not just capable of running apps — it should also enable us to build and deploy them.

End-to-end Swift, or some form of Swift-based cloud functions, was also one of my 2020 dreams. So many apps need to run server-side logic, but not all of them really need a completely custom server. Sure, there are lots of third-party tools available that lets us deploy individual pieces of logic, such as Cloudflare Workers (which is what powers this site’s search feature), but it would be incredible to see a completely integrated, Swift-based server-less system from Apple that would let us accomplish similar things.

I’d also still very much like to be able to use the Swift Package Manager to define entire app projects, rather than just libraries and command line tools. Like I mentioned earlier, SwiftPM is one of my favorite parts of Swift’s overall toolchain, so I’d be delighted to see it expand to cover even more use cases this year.

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Conclusion

Those are my biggest Swift-related dreams for WWDC21. What do you think? Do you share some of my dreams, or are there any other Swift-related announcements that you’d like to see next week? Let me know via either Twitter or email.

If you enjoyed this article, then make sure to check out WWDC by Sundell & Friends, on which I and some of my friends will cover WWDC21 in great detail all throughout the week of the conference.

Thanks for reading!

Swift’s implementation of enums is, without a doubt, one of the most beloved and powerful features that the language has to offer. The fact that Swift enums go way beyond simple enumerations of integer-based constants, and support things like associated values and sophisticated pattern matching, makes them a great candidate for solving many different kinds of problems.

However, there are certain kinds of enum cases that can arguably be good to avoid, as they could lead us to some tricky situations, or make our code feel less “idiomatic” that what we intended. Let’s take a look at a few such cases and how they could be refactored using some of Swift’s other language features.

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Representing the lack of a value

As an example, let’s say that we’re working on a podcast app, and that we’ve implemented the various categories that our app supports using an enum. That enum currently contains cases for each category, as well as two somewhat special cases that’s used for podcasts that don’t have a category at all (none), as well as a category that can be used to reference all categories at once (all):

extension Podcast {
    enum Category: String, Codable {
        case none
case all
        case entertainment
        case technology
        case news
        ...
    }
}

Then, when implementing features such as filtering, we can use the above enum to perform pattern matching against the Category value that the user selected within the UI (which is encapsulated within a Filter model):

extension Podcast {
    func matches(filter: Filter) -> Bool {
        switch filter.category {
        case .all, category:
            return name.contains(filter.string)
        default:
            return false
        }
    }
}

At first glance, the above two pieces of code might look perfectly fine. But, if we think about it, the fact that we’ve currently added a specific none case for representing the lack of a category is arguably a bit strange, given that Swift does have a built-in language feature that’s tailor-made for that purpose — optionals.

So, if we instead were to turn our Podcast model’s category property into an optional, then we’d get support for representing missing categories completely for free — plus we could now leverage all of the features that Swift optionals support (such as if let statements) when dealing with such missing values:

struct Podcast {
    var name: String
    var category: Category?
    ...
}

Something that’s really interesting about the above change is that any exhaustive switch statements that we were previously using on Podcast.Category values will still keep working just as they did before — since it turns out that the Optional type itself is also, in fact, an enum that uses a none case to represent the lack of a value — meaning that code like the following function can remain completely unchanged (apart from modifying its argument to be an optional):

func title(forCategory category: Podcast.Category?) -> String {
    switch category {
    case .none:
    return "Uncategorized"
    case .all:
        return "All"
    case .entertainment:
        return "Entertainment"
    case .technology:
        return "Technology"
    case .news:
        return "News"
    ...
    }
}

The above works thanks to a bit of Swift compiler magic that automatically flattens optionals when they’re used in pattern matching contexts (such as switch statements), which lets us both address cases within the Optional type itself, as well as cases defined within our own Podcast.Category enum, all within the same statement.

If we wanted to, we could’ve also used case nil instead of case .none, since those are functionally identical in the above type of situation.

Domain-specific enums

Next, let’s turn our attention to our Podcast.Category enum’s all case, which is also a bit strange if we think about it. After all, a podcast can’t belong to all categories simultaneously, so that all case really only makes sense within the context of filtering.

So, rather than including that case within our main Category enum, let’s instead create a dedicated type that’s specific to the domain of filtering. That way, we can achieve a quite neat separation of concerns, and since we’re using nested types, we can have our new enum use the same Category name, only this time it’ll be nested within our Filter model — like this:

extension Filter {
    enum Category {
        case any
        case uncategorized
        case specific(Podcast.Category)
    }
}

Worth noting is that we could’ve chosen to use the optional approach here as well, with nil representing either any or uncategorized, but since there are two potential candidates in this case, we’re arguably making our intent much more clear by using dedicated cases here.

What’s really nice about the above approach is that we can now implement our entire filtering logic using Swift’s pattern matching capabilities — by switching on the filtered category and by then using where clauses to attach additional logic to each case:

extension Podcast {
    func matches(filter: Filter) -> Bool {
        switch filter.category {
        case .any where category != nil,
             .uncategorized where category == nil,
             .specific(category):
            return name.contains(filter.string)
        default:
            return false
        }
    }
}

With all of the above changes in place, we can now go ahead and remove the none and all cases from our main Podcast.Category enum — leaving us with a much more straightforward list of each of the categories that our app supports:

extension Podcast {
    enum Category: String, Codable {
        case entertainment
        case technology
        case news
        ...
    }
}

Custom cases and custom types

When it comes to enums like Podcast.Category, it’s incredibly common to (at some point) introduce some kind of custom case that can be used to handle one-off cases, or to provide forward compatibility by gracefully handling cases that might be added server-side in the future.

One way to implement that would be to use a case that has an associated value — in our case a String representing the raw value of a custom category, like this:

extension Podcast {
    enum Category: Codable {
        case all
        case entertainment
        case technology
        case news
        ...
        case custom(String)
    }
}

Unfortunately, while associated values are incredibly useful in other contexts, this is not really one of them. First of all, by adding such a case, our enum can no longer be String-backed, meaning that we’ll now have to write custom encoding and decoding code, as well as logic for converting instances to and from raw strings.

So let’s explore another approach instead, by converting our Category enum into a RawRepresentable struct, which once again lets us leverage Swift’s built-in logic for encoding, decoding, and handling string conversions for such types:

extension Podcast {
    struct Category: RawRepresentable, Codable, Hashable {
        var rawValue: String
    }
}

Since we’re now free to create Category instances from any custom string that we want, we can easily support both custom and future categories without requiring any additional code on our part. However, to make sure that our code remains backward compatible, and to make it easy to refer to any of our built-in, currently known categories — let’s also extend our new type with static APIs that’ll achieve all of those things:

extension Podcast.Category {
    static var entertainment: Self {
        Self(rawValue: "entertainment")
    }

    static var technology: Self {
        Self(rawValue: "technology")
    }

    static var news: Self {
        Self(rawValue: "news")
    }
    
    ...

    static func custom(_ id: String) -> Self {
        Self(rawValue: id)
    }
}

Although the above change did require some amount of extra code to be added, we’ve now ended up with a much more flexible setup that’s almost entirely backward compatible. In fact, the only updates that we need to make are to code that performs exhaustive switches on Category values.

For example, the title function that we took a look at earlier previously switched on such a value to return a title matching a given category. Since we can no longer get an exhaustive list of each Category value at compile-time, we’d now have to use a different approach to compute those titles. In this particular case we could, for example, see this as an excellent opportunity to move those strings to a Localizable.strings file, and then resolve our titles like this:

func title(forCategory category: Podcast.Category?) -> String {
    guard let id = category?.rawValue else {
        return NSLocalizedString("category-uncategorized", comment: "")
    }

    let key = "category-\(id)"
    let string = NSLocalizedString(key, comment: "")

    // Handling unknown cases by returning a capitalized version
    // of their key as a fallback title:
    guard string != key else {
        return key.capitalized
    }

    return string
}

Another option would be to resolve our localized titles within the Category type itself, and to perhaps also add an optional title property which would enable our server to send pre-localized titles for custom categories that our app doesn’t yet natively support.

Auto-named static properties

As a quick bonus tip, one downside of the above struct-based approach is that we now have to manually define the underlying string raw values for each of our static properties, but that’s something that we could solve using Swift’s #function keyword. Since that keyword will be automatically replaced by the name of the function (or, in our case, property) that its encapsulating function is being called from, that’ll give us the same automatic raw value mapping as when using an enum:

extension Podcast.Category {
    static func autoNamed(_ rawValue: StaticString = #function) -> Self {
        Self(rawValue: "\(rawValue)")
    }
}

With the above utility in place, we can now simply call autoNamed() within each of our built-in category APIs, and Swift will automatically fill in those raw values for us:

extension Podcast.Category {
    static var entertainment: Self { autoNamed() }
static var technology: Self { autoNamed() }
static var news: Self { autoNamed() }
    ...

    static func custom(_ id: String) -> Self {
        Self(rawValue: id)
    }
}

Worth noting, though, is that we have to be a bit careful not to rename any of the above static properties when using that #function-based technique, since doing so will also change the underlying raw value for that property’s Category. However, that’s also the case when using enums, and on the flip side, we’re now also preventing typos and other mistakes that can happen when defining each raw string manually.

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Conclusion

Swift enums are awesome (in fact, I’ve written over 15 articles on that topic alone), but there are certain situations in which another language mechanism might be a better choice for what we’re looking to build, and it’s always possible that we might need to switch between several different mechanisms and approaches as our project grows and evolves.

Hopefully, this article has given you a few ideas on how those kinds of situations and problems could be solved, and if you have any questions, comments, or feedback, then feel free to reach out via either Twitter or email.

Thanks for reading!

In general, using computed properties can be a great way to model view-specific data that we want to create on-demand, when need — especially within SwiftUI views, since each such view already uses a computed property (body) to implement its actual UI.

For example, here we’re using two computed properties to determine what title and button text that a UserSessionView should render based on the app’s current LoginState:

struct UserSessionView: View {
    var buttonAction: () -> Void
    @Environment(\.loginState) private var state

    var body: some View {
        VStack {
            Text(title)
                .font(.headline)
                .foregroundColor(.white)
            Button(buttonText, action: buttonAction)
                .padding()
                .background(Color.white)
                .cornerRadius(10)
        }
        .padding()
        .background(Color.blue)
        .cornerRadius(15)
    }

    private var title: String {
        switch state {
        case .loggedIn(let user):
            return "Welcome back, \(user.name)!"
        case .loggedOut:
            return "Not logged in"
        }
    }

    private var buttonText: String {
        switch state {
        case .loggedIn:
            return "Log out"
        case .loggedOut:
            return "Log in"
        }
    }
}

To learn more about the Environment property wrapper that’s being used above, check out my guide to SwiftUI’s state management system.

Implementing a SwiftUI view like that, using multiple computed properties, can often be a great approach — as it lets us keep our body implementations as simple as possible, and since it gives us a clear overview of how we’re computing the different content that a given view will render.

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Recomputed properties

But, we also have to keep in mind that computed properties are just that — computed — there’s no form of caching or other kind of in-memory storage involved, meaning that each such values will always be recomputed each time that it’s being accessed.

That’s not an issue in our first example, because each of our properties can be quickly computed with constant (or O(1)) time complexity. However, let’s now take a look at another example, which is quite different in terms of performance characteristics, since we’re now computing a property by sorting a collection:

struct RemindersList: View {
    var items: [Reminder.ID: Reminder]

    var body: some View {
        List(sortedItems) { reminder in
            ...
        }
    }

    private var sortedItems: [Reminder] {
        items.values.sorted(by: {
    $0.dueDate < $1.dueDate
})
    }
}

On one hand, the above implementation could become quite problematic if the passed items dictionary ends up containing a very large amount of items, since that collection will be re-sorted every single time that we’ll access the sortedItems property. But, on the other hand, it’s a private property that’s only accessed from within our view’s body, and since our view doesn’t have any kind of mutable state, it’s not very likely that our property will actually be accessed that often.

However, that could quickly change if we were to add any kind of local state to our view — for example to enable the user to add a new Reminder using an inline TextField:

struct RemindersList: View {
    var items: [Reminder.ID: Reminder]
    var newItemHandler: (Reminder) -> Void

    @State private var newItemName = ""

    var body: some View {
        VStack {
            List(sortedItems) { reminder in
                ...
            }
            HStack {
    TextField("Add a new reminder", text: $newItemName)
    Button("Add") {
        newItemHandler(Reminder(name: newItemName))
    }
    .disabled(newItemName.isEmpty)
}
.padding()
        }
    }

    private var sortedItems: [Reminder] {
        items.values.sorted(by: {
            $0.dueDate < $1.dueDate
        })
    }
}

Now, every time that the user types a new character into the text field, our sortedItems property will be called and our items dictionary will be re-sorted. While that might not initially cause any obvious dips in performance, it’s a very inefficient implementation, and it’s very likely to cause problems at one point or another, especially for users with a large amount of reminders.

It’s important to remember that, although SwiftUI does use a type-based diffing algorithm to determine what underlying views to redraw for each state change, and does what it can to ensure that our UI remains performant, it’s not magic — if we write highly inefficient code, there’s not much that SwiftUI can do to fix that.

Going back to the source

So how can we fix this issue? One way would be to go back to the root source of our items data and update it to perform the necessary sorting right up front. Doing that has two main benefits — one, it lets us perform that operation once, instead of during every single view update, and two, it moves what is essentially a model-level operation into our actual model layer. Big win! Here’s what that could look like if we’re using Combine to load our items through some form of model controller:

func loadItems() -> AnyPublisher<[Item], Error> {
    controller
        .loadReminders()
        .map { items in
    items.values.sorted(by: {
        $0.dueDate < $1.dueDate
    })
}
        ...
        .eraseToAnyPublisher()
}

With the above change in place, we can now simply make our RemindersList view accept a pre-sorted array of reminders which we can just render as-is:

struct RemindersList: View {
    var items: [Reminder]
    ...

    var body: some View {
        VStack {
            List(items) { reminder in
                ...
            }
            ...
        }
    }
}

However, while the above approach is certainly preferable in many cases, there might be good reasons why we were modeling our core model collection as a dictionary, rather than using an array, and changing that might not be so simple, or even feasible at all. So let’s also explore a few other options as well.

Initialization logic

One way that we could solve our problem at the view level itself is by still having our RemindersList view accept a dictionary, just like before, but to instead perform our sorting within our view’s initializer, rather than using a computed property — for example like this:

struct RemindersList: View {
    var items: [Reminder]
    var newItemHandler: (Reminder) -> Void

    init(items: [Reminder.ID: Reminder],
     newItemHandler: @escaping (Reminder) -> Void) {
    self.items = items.values.sorted(by: {
        $0.dueDate < $1.dueDate
    })
    self.newItemHandler = newItemHandler
}

    @State private var newItemName = ""

    ...
}

With the above change in place, we’re now only sorting our collection once per RemindersList instance, rather than after every key stroke, without actually having to change the way our view is created or how our app’s data is managed. So while my general recommendation is to keep initializers focused on simple setup work, rather than performing data mutations, that’s a tradeoff that we might be willing to make in this case.

Worth keeping in mind, though, is that if the parent of our RemindersList view does update (or more specifically, if that parent’s body property gets re-evaluated), then a new instance of our view is likely going to be created, meaning that we’ll once again perform our item sorting operation.

Basically, when writing code within SwiftUI views, it’s close to impossible to gain complete control over when and how that code will be executed. After all, a core part of the design of a declarative UI framework like SwiftUI is that the framework takes care of orchestrating all of our UI updates for us.

So if we wanted to improve our control over the lifecycle of our actual model logic, then a better approach will likely be to move that logic out from our view implementations and into objects that we have complete control over.

Dedicated model logic

One way to do that would be to use something like a view model to encapsulate the logic associated with handling our items array. If we then make that view model an ObservableObject, then we’ll be able to easily observe it and connect to it within our SwiftUI views:

class RemindersListViewModel: ObservableObject {
    @Published private(set) var items: [Reminder]

    init(items: [Reminder.ID: Reminder]) {
        self.items = items.values.sorted(by: {
            $0.dueDate < $1.dueDate
        })
    }

    func addItem(named name: String) {
        ...
    }
}

With the above in place, we can now simplify our view quite heavily, and we’re also free to choose how we want to manage the above RemindersListViewModel ourselves, without having to take view updates and other SwiftUI implementation details into account:

struct RemindersList: View {
    @ObservedObject var viewModel: RemindersListViewModel
    @State private var newItemName = ""

    var body: some View {
        VStack {
            List(viewModel.items) { reminder in
                ...
            }
            HStack {
                TextField("Add a new reminder", text: $newItemName)
                Button("Add") {
                    viewModel.addItem(named: newItemName)
                }
                .disabled(newItemName.isEmpty)
            }
            .padding()
        }
    }
}

Very nice! That of course doesn’t mean that every single view within our app now needs to have a view model. It just so happens that in this particular case, a view model turned out to be a quite nice solution to our problem, since it enabled us to move our view-related model logic out from our view hierarchy itself (which also heavily improves that code’s testability).

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Conclusion

Recomputing some of our view-related values every time that a SwiftUI view updates is typically not an issue. After all, that’s the way that each view’s body property works, and as long as those computations can happen quickly (and ideally, with constant time complexity) then we’re not very likely to run into any kind of major performance issues.

However, that’s not always the case, and sometimes we might need to be particularly careful with how we consume our model data within our views, especially if doing so involves any kind of potentially heavy operations that could slow down our overall UI performance.

Hopefully this article has illustrated my overall approach to solving those kinds of problems, and if you have any questions, comments or feedback, then feel free to reach out via either Twitter or email.

Thanks for reading!

Today I’m launching a huge update to my suite of Swift static site generation tools — specifically a brand new version of Plot, the library that’s used to generate all of this website’s HTML, which adds a new API for building HTML components in a very SwiftUI-like way.

This new version has been in the works for over a year, and has been properly battle-tested in production. In fact, it was used to render the HTML for the article that you’re reading right now! So I couldn’t be more excited to now finally make it publicly available for the entire Swift community.

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From nodes to components

Up until this point, Plot has been using an API that represents all of the elements and attributes within an HTML page as nodes, which can then be composed and combined in various ways.

For example, here’s how an array of BlogPost models could be turned into a <ul>-element based feed of blog posts:

func makeBlogFeed(containing posts: [BlogPost]) -> Node<HTML.BodyContext> {
    .ul(
        .class("blog-feed"),
        .forEach(posts) { post in
            .li(.article(
                .img(.src(post.imageURL)),
                .h1(.text(post.title)),
                .p(.text(post.description)),
                .a("Continue reading", .href(post.url))
            ))
        }
    )
}

I’m still incredibly happy with the design of the API that’s used above, as it’s in many ways a perfect match for the very hierarchical nature of HTML and XML-based documents — but at the same time, I’ve become increasingly curious to see what a “SwiftUI makeover” of that API could look like.

Now, I don’t mean actually using SwiftUI itself to render HTML. Since it’s a closed-sourced project that was developed exclusively for building native views on Apple’s platforms, there’s really no reasonable way for a third party developer (like myself) to use it to render arbitrary HTML strings.

However, like we’ve taken a look at in articles like “The Swift 5.1 features that power SwiftUI’s API”, the public APIs that SwiftUI offers are all implemented using official language features (as of Swift 5.4 when result builders finally became a proper part of the language). So, rather than attempting to turn SwiftUI into an HTML renderer, I built my own SwiftUI-inspired API that’s been tailor-made for the task of building HTML components.

This is what our blog feed from before would look like if we instead implemented it using that new component-based API:

struct BlogFeed: Component {
    var posts: [BlogPost]

    var body: Component {
        List(posts) { post in
            Article {
                Image(post.imageURL)
                H1(post.title)
                Paragraph(post.description)
                Link("Continue reading", url: post.url)
            }
        }
        .class("blog-feed")
    }
}

Even though we’re now using a substantially different syntax to render our HTML, the end result will actually be identical to our earlier implementation. What’s really cool, though, is that we no longer need to manually construct elements like the <ul> and <li> tags that’s used to render our list — we can now simply create a List component and Plot will take care of all of those details for us.

Adapting some of SwiftUI’s core concepts for the web

Something that’s very important, though, is that the goal of this project wasn’t simply to copy SwiftUI’s API directly. After all, building statically generated websites is fundamentally different from native app development, so while I wanted this new API to feel familiar to developers who know SwiftUI, I also wanted it to feel right at home within the context of HTML.

One concrete example of that is Plot’s environment API, which — just like the one that SwiftUI offers — lets you modify the behavior of certain components by entering values into the overall environment that they’re being rendered in.

On the surface level, that API works the exact same way as when you apply modifiers like font and foregroundColor to a SwiftUI view hierarchy — you can apply such modifiers to a given component, and they will then be automatically forwarded to that component’s children.

For example, here’s how we could apply a certain list style and link target to every List/Link that appears within a given hierarchy:

struct ExternalLinks: Component {
    var body: Component {
        Div {
            H2("External Links")
            List {
                Link("My apps on the App Store", url: "...")
                Link("Twitter", url: "...")
                Link("GitHub", url: "...")
            }
        }
        .class("external-links")
        .listStyle(.ordered)
.linkTarget(.blank)
    }
}

The result of the above is that our List will be rendered as ordered (using the <ol> element), and that each of the <a> elements that will be generated for our Link components will be assigned the attribute target="_blank", which will make their URLs open in a new tab.

But if we now dive a little bit deeper into this feature and take a look at how we can define our very own environment values and keys, we can see that I made a few different decisions compared to how SwiftUI’s environment API is designed.

As an example, let’s take a look at this simplified version of the Menu component that I use to render the main menu of this very website — which uses Plot’s environment API to retrieve what section that’s currently selected:

// In Plot, environment keys are defined by extending a concrete
// EnvironmentKey type, rather than by conforming to a protocol:
extension EnvironmentKey where Value == SwiftBySundell.SectionID? {
    static var selectedSectionID: Self { Self() }
}

struct Menu: Component {
    // Environment values can be retrieved using the EnvironmentValue
    // property wrapper (which is the Plot equivalent of SwiftUI's
    // Environment wrapper):
    @EnvironmentValue(.selectedSectionID) private var selectedSectionID

    var body: Component {
        Navigation {
            List(SwiftBySundell.SectionID.allCases) { sectionID in
                Link(
                    sectionID.menuTitle,
                    url: sectionID.url
                )
                .class(classForSection(withID: sectionID))
            }
        }
    }

    private func classForSection(
        withID id: SwiftBySundell.SectionID
    ) -> String {
        // We can now use our environment value to make decisions
        // within this component — in this case in order to determine
        // whether a given menu item should be marked as selected:
        id == selectedSectionID ? "selected" : ""
    }
}

So while SwiftUI offers several different ways to interact with its environment API (through the Environment and EnvironmentObject property wrappers, the EnvironmentKey protocol, and so on), I chose to implement a simplified version that still offers enough power to be incredibly useful within the context of static site generation. After all, it wouldn’t make much sense for me to implement support for things like observable objects, since (unlike SwiftUI) Plot is not generating any dynamic views that need to be updated according to state changes.

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Conclusion

So, essentially, this new version of Plot is my take on a SwiftUI-like API that’s specifically made for generating static HTML. It’s not meant to be a replacement for dynamic client-side web frameworks (like React or Vue.js), nor does it offer any APIs for applying custom styles to its components (that still has to be done using CSS).

In the future, I do hope to be able to continue to extend Plot to also support CSS generation, but that’s a project for another day. In the meantime, I’m incredibly excited to share this new component-based API with you and the rest of the Swift community. I hope that you’ll find it useful, and like our friends at Apple always like to say — I can’t wait to see what you’ll build with it!

If you’re looking for more examples of how this new API can be used, check out Plot’s README, or the new version of Publish, which has also been updated to support this new component-based API. In fact, all of Publish’s built-in Foundation theme has been rewritten using this new API. And if you’re an existing user of either Plot or Publish, then you just have to upgrade to the latest version — this new API is fully backward compatible, so you shouldn’t encounter any breaking changes.

I hope you’ll enjoy this new version of Plot, and feel free to send me either a tweet or an email if you have any questions, comments, or feedback.

Thanks for reading!