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Podcast: “Swift 5.7, generics, and the road to Swift 6” with special guest Ben Cohen
Published on 10 Jun 2022
Listen using: Apple Podcasts Overcast Castro Pocket Casts RSS
Ben Cohen, manager of the Swift team at Apple, joins John on this WWDC22 special to discuss Swift 5.7, how generics have been made more powerful and easy to use, and how the language is expected to evolve towards Swift 6.
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Links
- Another apple interview episode
  69: “Swift Playgrounds” with special guests Holly Borla and Grace Kendall
- Read more about generics
  Specialized extensions using generic type constraints
- Another article about generics
  Using closure types in generic constraints
Using the ‘some’ and ‘any’ keywords to reference generic protocols in Swift 5.7
Published on 09 Jun 2022
Discover page available: Generics
Combining Swift’s flexible generics system with protocol-oriented programming can often lead to some really powerful implementations, all while minimizing code duplication and enabling us to establish clearly defined levels of abstraction across our code bases. However, when writing that sort of code before Swift 5.7, it’s been very common to run into the following compiler error:
```
Protocol 'X' can only be used as a generic constraint because it
has Self or associated type requirements.
```
Let’s take a look at how Swift 5.7 (which is currently in beta as part of Xcode 14) introduces a few key new features that aim to make the above kind error a thing of the past.
Opaque parameter types
Like we took a closer look at in the Q&A article “Why can’t certain protocols, like Equatable and Hashable, be referenced directly?”, the reason why it’s so common to encounter the above compiler error when working with generic protocols is that as soon as a protocol defines an associated type, the compiler starts placing limitations on how that protocol can be referenced.
For example, let’s say that we’re working on an app that deals with various kinds of groups, and to be able to reuse as much of our group handling code as possible, we’ve chosen to define our core Group type as a generic protocol that lets each implementing type define what kind of Item values that it contains:
```
protocol Group {
    associatedtype Item

    var items: [Item] { get }
    var users: [User] { get }
}
```
Now, because of that associated Item type, we can’t reference our Group protocol directly — even within code that has nothing to do with a group’s items, such as this function that computes what names to display from a given group’s list of users:
```
// Error: Protocol 'Group' can only be used as a generic constraint
// because it has Self or associated type requirements.
func namesOfUsers(addedTo group: Group) -> [String] {
    group.users.compactMap { user in
        isUserAnonymous(user) ? nil : user.name
    }
}
```
One way to solve the above problem when using Swift versions lower than 5.7 would be to make our namesOfUsers function generic, and to then do what the above error message tells us, and only use our Group protocol as a generic type constraint — like this:
```
func namesOfUsers<T: Group>(addedTo group: T) -> [String] {
    group.users.compactMap { user in
        isUserAnonymous(user) ? nil : user.name
    }
}
```
There’s of course nothing wrong with that technique, but it does make our function declaration quite a bit more complicated compared to when working with non-generic protocols, or any other form of Swift type (including concrete generic types).
Thankfully, this is a problem that Swift 5.7 neatly solves by expanding the some keyword (that was introduced back in Swift 5.1) to also be applicable to function arguments. So, just like how we can declare that a SwiftUI view returns some View from its body property, we can now make our namesOfUsers function accept some Group as its input:
```
func namesOfUsers(addedTo group: some Group) -> [String] {
    group.users.compactMap { user in
        isUserAnonymous(user) ? nil : user.name
    }
}
```
Just like when using the some keyword to define opaque return types (like we do when building SwiftUI views), the compiler will automatically infer what actual concrete type that’s passed to our function at each call site, without requiring us to write any extra code. Neat!
Primary associated types
Sometimes, though, we might want to add a few more requirements to a given parameter, rather than just requiring it to conform to a certain protocol. For example, let’s say that we’re now working on an app that lets our users bookmark their favorite articles, and that we’ve created a BookmarksController with a method that lets us pass an array of articles to bookmark:
```
class BookmarksController {
    ...

    func bookmarkArticles(_ articles: [Article]) {
        ...
    }
}
```
However, not all of our call sites might store their articles using an array. The following ArticleSelectionController, for instance, uses a ‌dictionary to keep track of what articles that have been selected for what IndexPath within a UITableView or UICollectionView. So, when passing that collection of articles to our bookmarkArticles method, we first need to manually convert it into an array — like this:
```
class ArticleSelectionController {
    var selection = [IndexPath: Article]()
    private let bookmarksController: BookmarksController
    ...

    func bookmarkSelection() {
        bookmarksController.bookmarkArticles(Array(selection.values))
        ...
    }
}
```
But if we instead wanted to update that bookmarkArticles method to work well for any kind of Collection that contains Article values, then we couldn’t simply change its parameter type to some Collection, since that wouldn’t be enough to specify that we’re looking for a collection that has a specific Element type as input.
We could, however, once again use a set of generic type constraints to solve that problem:
```
class BookmarksController {
    ...

    func bookmarkArticles<T: Collection>(
        _ articles: T
    ) where T.Element == Article {
        ...
    }
}
```
Again, nothing wrong with that — but Swift 5.7 once again introduces a much more lightweight way to express the above kind of declaration, which works the exact same way as when specializing a concrete generic type (such as Array<Article>). That is, we now can simply tell the compiler what Element type that we’d like our input Collection to contain by adding that type within angle brackets right after the protocol name:
```
class BookmarksController {
    ...

    func bookmarkArticles(_ articles: some Collection<Article>) {
        ...
    }
}
```
Very cool! We can even nest those kinds of declarations — so if we wanted to make our BookmarksController capable of bookmarking any kind of value that conforms to a generic ContentItem protocol, then we could specify some ContentItem as our collection’s expected Element type, rather than using the concrete Article type:
```
protocol ContentItem: Identifiable where ID == UUID {
    var title: String { get }
    var imageURL: URL { get }
}

class BookmarksController {
    ...

    func bookmark(_ items: some Collection<some ContentItem>) {
        ...
    }
}
```
The above works thanks to a new Swift feature called primary associated types, and the fact that Swift’s Collection protocol declares Element as such an associated type, like this:
```
protocol Collection<Element>: Sequence {
    associatedtype Element
    ...
}
```
Of course, being a proper Swift feature, we can also use primary associated types within our own protocols as well, using the exact same kind of syntax.
Existentials and the ‘any’ keyword
Finally, let’s take things one step further by also turning our ArticleSelectionController into a generic type that can be used to select any ContentItem-conforming value, rather than just articles. As we’re now looking to mix multiple concrete types that all conform to the same protocol, the some keyword won’t do the trick — since, like we saw earlier, it works by having the compiler infer a single concrete type for each call site, not multiple ones.
This is where the new any keyword (which was introduced in Swift 5.6) comes in, which enables us to refer to our ContentItem protocol as an existential. Now, doing that does have certain performance and memory implications, as it effectively works as an automatic form of type erasure, but in situations where we want to be able to dynamically store a heterogeneous collection of elements, it can be incredibly useful.
For example, by simply using any ContentItem as our selection dictionary’s value type, we’ll now be able to store any value conforming to that protocol within that dictionary:
```
class ContentSelectionController {
    var selection = [IndexPath: any ContentItem]()
    private let bookmarksController: BookmarksController
    ...

    func bookmarkSelection() {
        bookmarksController.bookmark(selection.values)
        ...
    }
}
```
However, making that change does introduce a new compiler error, since our BookmarksController is expecting to receive a collection that contains values that all have the exact same type — which isn’t the case within our new ContentSelectionController implementation.
Thankfully, fixing that issue is as simple as replacing some ContentItem with any ContentItem within our bookmark method declaration:
```
class BookmarksController {
    ...

    func bookmark(_ items: some Collection<any ContentItem>) {
        ...
    }
}
```
We’re even able to mix any and some references, and the compiler will automatically help us translate between the two. For example, if we wanted to introduce a second, single-element bookmark method overload, which our first one then simply calls, then we could do so like this (even though the first method’s items collection contains any ContentItem and the second method accepts some ContentItem):
```
class BookmarksController {
    ...

    func bookmark(_ items: some Collection<any ContentItem>) {
        for item in items {
            bookmark(item)
        }
    }

    func bookmark(_ item: some ContentItem) {
        ...
    }
}
```
Again, it’s important to emphasize the using any does introduce type erasure under the hood, even if it’s all done automatically by the compiler — so using static types (which is still the case when using the some keyword) is definitely the preferred way to go whenever possible.
Conclusion
Swift 5.7 doesn’t just make Swift’s generics system more powerful, it arguably makes it much more accessible as well, as it reduces the need to use generic type constraints and other more advanced generic programming techniques just to be able to refer to certain protocols.
Generics is definitely not the right tool for every single problem, but when it turns out to be, being able to use Swift’s generics system in a much more lightweight way is definitely a big win.
I hope that you found this article useful. If you have any questions, comments, or feedback, then feel free to reach out via either Twitter or email. For more information about these new generics features, I recommend watching the excellent “What’s new in Swift” and “Embrace Swift generics” sessions from this year’s WWDC.
Thanks for reading!
- Generics
  Learn how to fully utilize Swift’s powerful generics system.
- Read more about protocols
  Combining protocols in Swift
- Another article about protocols
  Creating a dedicated identifier type

Swift 5.7’s new optional unwrapping syntax

Published on 07 Jun 2022

Swift 5.7 introduces a new, more concise way to unwrap optional values using if let and guard let statements. Before, we always had to explicitly name each unwrapped value, for example like this:

class AnimationController {
    var animation: Animation?

    func update() {
        if let animation = animation {
            // Perform updates
            ...
        }
    }
}

But now, we can simply drop the assignment after our if let statement, and the Swift compiler will automatically unwrap our optional into a concrete value with the exact same name:

class AnimationController {
    var animation: Animation?

    func update() {
        if let animation {
            // Perform updates
            ...
        }
    }
}

Neat! The above new syntax also works with guard statements:

class AnimationController {
    var animation: Animation?

    func update() {
        guard let animation else {
            return
        }

        // Perform updates
        ...
    }
}

It can also be used to unwrap multiple optionals all at once:

struct Message {
    var title: String?
    var body: String?
    var recipient: String?

    var isSendable: Bool {
        guard let title, let body, let recipient else {
            return false
        }

        return ![title, body, recipient].contains(where: \.isEmpty)
    }
}

A small, but very welcome feature. Of course, we still have the option to explicitly name each unwrapped optional if we wish to do so — either for code style reasons, or if we want to give a certain optional a different name when unwrapped.

- Read more about Swift’s language features
  Equality
- Another article about Swift’s language features
  Organizing default argument values
- Continue exploring Swift’s language features
  Using ‘@unknown default’ within switch statements
Rendering SwiftUI views within UITableView or UICollectionView cells on iOS 16
Published on 07 Jun 2022
Discover page available: SwiftUI
Ever since its original introduction in 2019, SwiftUI has had really strong interoperability with UIKit. Both UIView and UIViewController instances can be wrapped to become fully SwiftUI-compatible, and UIHostingController lets us render any SwiftUI view within a UIKit-based view controller.
However, even though macOS has had an NSHostingView for inlining SwiftUI views directly within any NSView (no view controller required) since the very beginning, there has never been a built-in way to do the same thing on iOS. Sure, we could always grab the underlying view from a UIHostingController instance, or add our hosting controller to a parent view controller in order to be able to use its view deeper within a UIView-based hierarchy — but neither of those solutions have ever felt entirely smooth.
That brings us to iOS 16 (which is currently in beta at the time of writing). Although Apple haven’t introduced a fully general-purpose UIHostingView as part of this release, they have addressed one of the most common challenges that the lack of such a view presents us with — which is how to render a SwiftUI view within either a UITableViewCell or UICollectionViewCell.
Just a quick note before we begin: All of this article’s code samples will be entirely UITableView-based, but the exact same techniques can also be used with UICollectionView as well.
Say hello to UIHostingConfiguration
In iOS 14, Apple introduced a new way to configure cells that are being rendered as part of a UITableView or UICollectionView, which lets us use so-called content configurations to decouple the content that we’re rendering from the actual subviews that our cells contain. This API has now been extended with a new UIHostingConfiguration type, which lets us define a cell’s content using any SwiftUI view hierarchy.
So wherever we’re configuring our cells — for example using the good-old-fashioned UITableViewDataSource dequeuing method — we can now opt to assign such a hosting configuration to a given cell’s contentConfiguration property, and UIKit will automatically render the SwiftUI views that we provide within that cell:
```
class ListViewController: UIViewController, UITableViewDataSource {
    private var items: [Item]
    private let databaseController: DatabaseController
    private let cellReuseID = "cell"
    private lazy var tableView = UITableView()
    ...

    func tableView(_ tableView: UITableView,
                   cellForRowAt indexPath: IndexPath) -> UITableViewCell {
        let cell = tableView.dequeueReusableCell(
            withIdentifier: cellReuseID,
            for: indexPath
        )

        let item = items[indexPath.row]

        cell.contentConfiguration = UIHostingConfiguration {
            HStack {
                Text(item.title)
                Spacer()
                Button(action: { [weak self] in
                    if let indexPath = self?.tableView.indexPath(for: cell) {
                        self?.toggleFavoriteStatusForItem(atIndexPath: indexPath)
                    }
                }, label: {
                    Image(systemName: "star" + (item.isFavorite ? ".fill" : ""))
                        .foregroundColor(item.isFavorite ? .yellow : .gray)
                })
            }
        }

        return cell
    }

    private func toggleFavoriteStatusForItem(atIndexPath indexPath: IndexPath) {
        items[indexPath.row].isFavorite.toggle()
        databaseController.update(items[indexPath.row])
    }
}
```
Neat! As the above code sample shows, we can easily send events back from our cell’s SwiftUI views to our view controller using closures, but there are a few things that are good to keep in mind when doing so.
First, you might’ve noticed that we’re asking the table view for our cell’s current index path before passing it to our toggleFavoriteStatusForItem method. That’s because, if our table view supports operations such as moves and deletions, our cell might be at a different index path once our favorite button is tapped — so if we were to capture and use the indexPath parameter that was passed into our cell configuration method, then we might accidentally end up updating the wrong model.
Second, we have to remember that we still very much remain in the world of UIKit, which means that we have to take memory management into account (at least, more so than when operating in the wonderful value type-based world of SwiftUI). Hence the above [weak self] closure capture, in order to avoid retain cycles between our view controller and its UITableView.
Finally, there’s state management, and just like when bridging the gap between UIKit and SwiftUI using tools like UIHostingController or UIViewRepresentable, we probably need to write a little bit of custom code to ensure that our cell’s SwiftUI view hierarchy is rendering the latest version of our view controller’s data.
Managing state updates
For example, when the user taps our cell’s favorite button, our cell is not currently updated to reflect its Item model’s new state. That’s because we’re not actually using SwiftUI’s declarative state management system to drive those updates, so there’s no way for our nested SwiftUI view hierarchy to know that its data model was modified.
One way to address that would be to use UIKit to react to those changes, rather than using SwiftUI’s view updating mechanisms. We could, for instance, call our table view’s reloadRows method whenever an item’s favorite status was changed — like this:
```
class ListViewController: UIViewController, UITableViewDataSource {
    ...

    private func toggleFavoriteStatusForItem(atIndexPath indexPath: IndexPath) {
        items[indexPath.row].isFavorite.toggle()
        databaseController.update(items[indexPath.row])
        tableView.reloadRows(at: [indexPath], with: .none)
    }
}
```
That works great, since it’ll make the table view call our data source cell configuration method, which’ll give us a chance to update the changed item’s cell and the SwiftUI views that are embedded within it.
But let’s say that we instead wanted to use SwiftUI’s state management system to keep track of when our cell’s state was modified. One way to make that happen would be to introduce some form of ObservableObject that our view controller could then inject into each cell’s SwiftUI view hierarchy.
A side-benefit of introducing such a type in this case is that it’ll also give us a neat place to encapsulate all view-related logic that’s tied to our Item model, such as the code that’s used to compute our favorite button’s title and foreground color. Let’s go ahead and introduce such a class, which we’ll call ItemViewModel:
```
class ItemViewModel: ObservableObject {
    @Published private(set) var item: Item
    private let onItemChange: (Item) -> Void

    init(item: Item, onItemChange: @escaping (Item) -> Void) {
        self.item = item
        self.onItemChange = onItemChange
    }

    func toggleFavoriteStatus() {
        item.isFavorite.toggle()
        onItemChange(item)
    }
}

extension ItemViewModel {
    var favoriteButtonIconName: String {
        "star" + (item.isFavorite ? ".fill" : "")
    }

    var favoriteButtonColor: Color {
        item.isFavorite ? .yellow : .gray
    }
}
```
Note that we’re enabling an onItemChange closure to be passed into our view model, which’ll let our view controller observe whenever the view model’s copy of the underlying Item model was modified. We could definitely have chosen to use Combine here instead, by having our view controller hook into the publisher that’s connected to the view model’s item property, but a simple closure will get the job done in this case.
Next, let’s extract our cell-embedded SwiftUI code into a dedicated View type, which will let us make our view hierarchy observe our new view model as an ObservedObject:
```
struct ItemView: View {
    @ObservedObject var viewModel: ItemViewModel

    var body: some View {
        HStack {
            Text(viewModel.item.title)
            Spacer()
            Button(action: viewModel.toggleFavoriteStatus) {
                Image(systemName: viewModel.favoriteButtonIconName)
                    .foregroundColor(viewModel.favoriteButtonColor)
            }
        }
    }
}
```
Finally, all that remains is to update our view controller to use our newly introduced types, which will also let us remove the toggleFavoriteStatusForItem method that we were previously using to manage each item’s favorite status:
```
class ListViewController: UIViewController, UITableViewDataSource {
    ...

    func tableView(_ tableView: UITableView,
                   cellForRowAt indexPath: IndexPath) -> UITableViewCell {
        let cell = tableView.dequeueReusableCell(
            withIdentifier: cellReuseID,
            for: indexPath
        )

        let viewModel = ItemViewModel(
            item: items[indexPath.row],
            onItemChange: { [weak self] item in
                guard let indexPath = self?.tableView.indexPath(for: cell) else {
                    return
                }
            
                self?.items[indexPath.row] = item
                self?.databaseController.update(item)
            }
        )

        cell.contentConfiguration = UIHostingConfiguration {
    ItemView(viewModel: viewModel)
}

        return cell
    }
}
```
Very nice! Of course, the above implementation only handles internal data model changes that are performed by our view controller and its nested SwiftUI views. If those models could also be modified elsewhere, then we’d have to notify our view controller whenever that happens, and reload our table view’s data accordingly. However, the fact that we’re using SwiftUI and the new UIHostingConfiguration API doesn’t really affect the way we’d do that, since any such external updates would lead to us re-configuring our cells anyway.
Bridged swipe actions
Another neat aspect of the new UIHostingConfiguration API and the way it bridges the gap between UIKit and SwiftUI is that it’ll automatically convert any SwiftUI swipeActions that our view hierarchy contains into UIKit-based swipe actions.
So for example, if we wanted to add a delete swipe action to each of our item cells, then we could do that using a modifier placed right within our UIHostingConfiguration closure — like this:
```
cell.contentConfiguration = UIHostingConfiguration {
    ItemView(viewModel: viewModel).swipeActions {
        Button(role: .destructive, action: { [weak self] in
            guard let indexPath = self?.tableView.indexPath(for: cell) else {
                return
            }

            self?.items.remove(at: indexPath.row)
            self?.databaseController.delete(viewModel.item)
            self?.tableView.deleteRows(at: [indexPath], with: .automatic)
        }, label: {
            Label("Delete", systemImage: "trash")
        })
    }
}
```
However, while the above is really neat, it’s important to point out that (at the time of writing) not every aspect of SwiftUI is automatically bridged that way. For example, if we were to place a NavigationLink within our UIHostingConfiguration, then that wouldn’t automatically be wired up to any UINavigationController that our view controller is embedded in (which does happen when using UIHostingController). Hopefully that’s something that’ll be addressed at a later time.
Conclusion
The interoperability between SwiftUI and UIKit keeps getting more and more powerful, which in turn enables us to continue mixing the two UI frameworks within the apps that we build. The introduction of UIHostingConfiguration is especially welcome, since UITableView and UICollectionView (which supports this new hosting configuration API in the exact same way) still offer much more functionality than their SwiftUI counterparts — so being able to inline SwiftUI views within them should definitely prove to be very useful.
If you have any questions, comments, or feedback, then feel free to reach out via either Twitter or email.
Thanks for reading!
- Read more about swiftui
  A first look at SwiftUI’s new StateObject property wrapper
  Managing internal reference types.
- Another article about uikit
  Handling keyUp and keyDown events on iOS 13.4 and later
  Keyboard events are finally here!
- Continue exploring swiftui
  SwiftUI is a game changer
Podcast: “The evolution of SwiftUI” with special guest Chris Eidhof
- swiftui
- architecture
Published on 18 May 2022
Listen using: Apple Podcasts Overcast Castro Pocket Casts RSS
Chris Eidhof returns to the podcast to talk about how SwiftUI has evolved since its initial release, to share several key learnings from using it over the past few years, and to discuss concepts like app architecture and state management.
Sponsors
- Judo: Quickly build native, server-driven UI for iOS and Android, and publish instantly, without having to submit updates to the App Store. Try it for free today, by going to judo.app/sundell.
- RevenueCat: In-app subscriptions made easy. RevenueCat handles the pain points of implementing in-app purchases and subscriptions, so that you can get back to building your app. Learn more at revenuecat.com.
Links
- SwiftUI
  Get the most out of Apple’s new UI framework.
- Another episode about architecture
  45: “That’s why we refactor” with special guests Chris Eidhof and Matt Gallagher
- Read more about swiftui
  Creating custom SwiftUI container views
  Using a dedicated protocol to make it easy to define new containers.
Swift by Sundell turns five years old today! Here’s what’s next for the website and the podcast
Published on 05 May 2022
Today it’s been exactly five years since this website first launched, and what a journey it has been! When I started this website after having published weekly articles on Medium for a few months, I honestly had no idea what to expect. I wasn’t even sure if anyone would even find the site to begin with, let alone be interested in coming back week after week to read my new articles.
But now, five years later, and with over 550 articles and 115 podcast episodes published, this website has been visited by over a million Swift developers from all around the world, and hundreds of thousands of people come back to read new articles and listen to new podcast episodes every single month. To see this website grow like that has been absolutely incredible, and I’m eternally grateful for all of the amazing support that you — the Swift community — have given me over these first five years.
During these first few years, the amount of time that I’ve been able to spend working on my articles and podcast episodes has varied quite a lot. In the beginning, I was simply working on Swift by Sundell during my spare time, as a hobby project, and I had no plans or intentions to ever scale the project much beyond that. But at the same time, the website kept growing, and so did my ambitions, and at the start of 2019 (two years after the initial launch) I made the rather bold decision to turn Swift by Sundell into my full-time job.
In retrospect, I’m incredibly happy that I made that decision, not only because it enabled me to produce a much larger number of more detailed articles, and spend more time on podcast editing to make each episode sound great — but also because it led to the creation of Ink, Plot, and Publish, and the current iteration of this website which uses those tools to produce a fast, easy to use, statically generated site that I’m super proud of.
Working full-time on your own projects, as amazing as it in many ways is, also comes with quite a few downsides, though. In particular, I really started to miss working with other people, to be a part of a team, and to do actual iOS and macOS app development. Building Publish and my other open source tools was a lot of fun, and involved solving a ton of interesting problems, but it just wasn’t the same as working on complex app projects with dedicated co-workers.
So in 2020 I decided to start freelancing again, part-time, while still keeping Swift by Sundell as my main, full-time job — which worked out great. In fact, it worked out so great that I started taking on more freelancing work throughout 2021, and for a while, I was incredibly happy with how my work was progressing. Business was great, with income from both this website’s sponsorships and from my freelancing work, I got to work on some incredibly cool projects, plus those projects gave me such a huge amount of inspiration for both my articles and podcast episodes. It all turned out to be one big, positive feedback loop.
However, towards the end of 2021, I started to feel that something was wrong. I very often felt incredibly stressed, and sometimes even deeply disappointed in myself for not writing enough articles, for not publishing podcast episodes frequently enough, for not reviewing open source pull requests fast enough, or for not working enough hours on a given project.
Looking back, it’s quite obvious what had happened. As I kept constantly expanding all of my projects and client work over time, I had ended up with more or less two full-time jobs, and it became clear that I was at the edge (or, some may say, even past the edge) of being burned out. Something had to change.
So, at the beginning of this year, I sat down and started making a plan. I knew that I didn’t want to stop doing client work (I still work on some really nice projects with incredible teams), and I also knew that I didn’t want to quit working on this website, the podcast, Stacktrace (my other podcast), or my open source projects. So I just needed to come up with some kind of compromise, a schedule that would let me keep working on all of those things that I’m super passionate about, while also making that schedule much more sustainable and healthy.
What I’ve come up with will likely disappoint some of you, since it does involve a reduction of the amount of time that I’ll be able to spend on Swift by Sundell going forward (and the number of articles and podcast episodes that I’ll be able to make as a result), but I want to make it crystal clear that I’m making these changes because I want to keep working on Swift by Sundell for many more years to come. I love this website and the wonderful community that exists around Swift and Apple’s platforms, and I want to continue contributing to that community as much as I possibly can far into the future.
So, what changes am I making? First, I’m removing all sorts of publishing schedules, and will instead post new articles and podcast episodes on a more infrequent basis. While I’m aiming to publish at least one new article and one podcast episode per month, there might occasionally be some periods of time where not much is happening on this website, but that doesn’t mean that I’ve abandoned it, I might just be busy with other work. I’ve always prioritized quality over quantity, and I’d much rather take my time writing a really great article than rush one out just to meet a specific schedule.
Next, I’m removing all ads from the website, starting next week, on the 9th of May. That’s right, you’ll soon be able to enjoy all of this website’s hundreds of articles and all of my Discover guides completely ad-free, all free of charge. While I might occasionally publish a (clearly marked) sponsored post, and there will still be sponsorships on the podcast, I want to turn my articles back to what they started out as — a way for me to share my thoughts and learnings with the community without any kind of commercial motives or pressure.
I truly appreciate all of the sponsors that have advertised on this website over the past three and a half years, and I’m not saying that I’ll never do website sponsorships again, but not having to book, schedule and manage weekly website sponsorships is going to free up a lot of time (and remove a ton of stress), so it feels like the right move to make at this point.
So, to sum up, Swift by Sundell is here to stay, and while you’ll see new content published on a more infrequent basis going forward, you’ll be able to freely access all of this site’s huge collection of articles completely ad-free. I truly believe that this is the best path forward, both for Swift by Sundell and for me personally, and I hope you’ll keep joining me on this journey for a long time to come.
Thanks so much for reading, happy fifth birthday to Swift by Sundell, and here’s to five more years of articles, podcasts, and more!
Podcast: “A framework and an app” with special guest Simon Støvring
Published on 30 Apr 2022
Listen using: Apple Podcasts Overcast Castro Pocket Casts RSS
Simon Støvring returns to the show to talk about how he built his new text editor Runestone, how to effectively manage an app’s settings, performance tuning, and implementing an app’s core logic as a stand-alone framework.
Sponsors
- Judo: Quickly build native, server-driven UI for iOS and Android, and publish instantly, without having to submit updates to the App Store. Try it for free today, by going to judo.app/sundell.
- Bitrise: Rock-solid continuous integration for your Swift project, which now offers 50% faster builds and ad-ons for things like automatic deployment. Go to bitrise.io/swift to get started for free.
Links
- Another episode about developer tools
  29: “Flexing your learning muscle” with special guest Niels van Hoorn
- Another episode about maintenance
  77: “Adopting new system features” with special guest Jordan Morgan
  Tips for keeping up with platform and SDK changes.
- Read more about performance
  Picking the right data structure in Swift
  How different data structures can have a big impact on performance.
Type placeholders in Swift
- language features
- generics
Published on 14 Apr 2022
Discover page available: Generics
Swift’s type inference capabilities have been a very core part of the language since the very beginning, and heavily reduces the need for us to manually specify types when declaring variables and properties that have default values. For example, the expression var number = 7 doesn’t need to include any type annotations, since the compiler is able to infer that the value 7 is an Int and that our number variable should be typed accordingly.
Swift 5.6, which was released as part of Xcode 13.3, continues to expand these type inference capabilities by introducing the concept of “type placeholders”, which can come very much in handy when working with collections and other generic types.
For example, let’s say that we wanted to create an instance of Combine’s CurrentValueSubject with a default integer value. An initial idea on how to do just that might be to simply pass our default value to that subject’s initializer, and then store the result in a local let (just like when creating a plain Int value). However, doing so gives us the following compiler error:
```
// Error: "Generic parameter 'Failure' could not be inferred"
let counterSubject = CurrentValueSubject(0)
```
That’s because CurrentValueSubject is a generic type that needs to be specialized with not just an Output type, but also with a Failure type — which is the type of error that the subject is capable of throwing.
Since we don’t want our subject to throw any errors in this case, we’ll give it the failure type Never (which is a common convention when using both Combine and Swift concurrency). But in order to do that, prior to Swift 5.6, we would need to explicitly specify our Int output type as well — like this:
```
let counterSubject = CurrentValueSubject<Int, Never>(0)
```
Starting in Swift 5.6, though, that’s no longer the case — as we can now use a type placeholder for our subject’s output type, which lets us once again leverage the compiler to automatically infer that type for us, just like when declaring a plain Int value:
```
let counterSubject = CurrentValueSubject<_, Never>(0)
```
That’s nice, but it’s arguably not the biggest improvement in the world. After all, we’re only saving two characters by replacing Int with _, and it’s not like manually specifying a simple type like Int was something problematic to begin with.
But let’s now take a look at how this feature scales to more complex types, which is where it really starts to shine. For example, let’s say that our project contains the following function that lets us load a user-annotated PDF file:
```
func loadAnnotatedPDF(named: String) -> Resource<PDF<UserAnnotations>> {
    ...
}
```
The above function uses a quite complex generic as its return type, which might be because we’re reusing our Resource type across multiple domains, and because we’ve opted to use phantom types to specify what kind of PDF that we’re currently dealing with.
Now let’s take a look at what our CurrentValueSubject-based code from before would look like if we were to call the above function when creating our subject, rather than just using a simple integer:
```
// Before Swift 5.6:
let pdfSubject = CurrentValueSubject<Resource<PDF<UserAnnotations>>, Never>(
    loadAnnotatedPDF(named: name)
)

// Swift 5.6:
let pdfSubject = CurrentValueSubject<_, Never>(
    loadAnnotatedPDF(named: name)
)
```
That’s quite a huge improvement! Not only does the Swift 5.6-based version save us some typing, but since the type of pdfSubject is now derived completely from the loadAnnotatedPDF function, that’ll likely make iterating on that function (and its related code) much easier — since there will be fewer manual type annotations that will need to be updated if we ever change that function’s return type.
It’s worth pointing out, though, that there’s another way to leverage Swift’s type inference capabilities in situations like the one above — and that’s to use a type alias, rather than a type placeholder. For example, here’s how we could define an UnfailingValueSubject type alias, which we’ll be able to use to easily create subjects that aren’t capable of throwing any errors:
```
typealias UnfailingValueSubject<T> = CurrentValueSubject<T, Never>
```
With the above in place, we’ll now be able to create our pdfSubject without any kind of generic type annotations at all — since the compiler is able to infer what type that T refers to, and since the failure type Never has been hard-coded into our new type alias:
```
let pdfSubject = UnfailingValueSubject(loadAnnotatedPDF(named: name))
```
That doesn’t mean that type aliases are universally better than type placeholders, though, since if we were to define new type aliases for each particular situation, then that could also make our code base much more complicated. Sometimes, specifying everything inline (like when using a type placeholder) is definitely the way to go, as that lets us define expressions that are completely self-contained.
Before we wrap things up, let’s also take a look at how type placeholders can be used with collection literals — for example when creating a dictionary. Here, we’ve opted to manually specify our dictionary’s Key type (in order to be able to use dot-syntax to refer to an enum’s various cases), while using a type placeholder for that dictionary’s values:
```
enum UserRole {
    case local
    case remote
}

let latestMessages: [UserRole: _] = [
    .local: "",
    .remote: ""
]
```
So that’s type placeholders — a new feature introduced in Swift 5.6, which will likely be really useful when dealing with slightly more complex generic types. It’s worth pointing out, though, that these placeholders can only be used at call sites, not when specifying the return types of either functions or computed properties.
I hope you found this article useful, and feel free to let me know if you have any questions, comments, or feedback — either via Twitter or email.
Thanks for reading!
- Generics
  Learn how to fully utilize Swift’s powerful generics system.
- Read more about Swift’s language features
  Chained implicit member expressions in Swift 5.4
- Another article about Swift’s language features
  Custom operators in Swift
Podcast: “Accessibility on Apple’s platforms” with special guest Sommer Panage
- accessibility
- ui development
Published on 21 Mar 2022
Listen using: Apple Podcasts Overcast Castro Pocket Casts RSS
Sommer Panage returns to the show to discuss Apple’s various accessibility APIs and tools, how to incorporate accessibility support into a team’s overall development workflow, and what it was like being an engineering manager at Apple.
Sponsors
- Emerge Tools: Optimize your app’s startup time, binary size, and overall performance using Emerge’s advanced app optimization and monitoring tools. Get started at emergetools.com.
- Bitrise: Rock-solid continuous integration for your Swift project, which now offers 50% faster builds and ad-ons for things like automatic deployment. Go to bitrise.io/swift to get started for free.
Links
- Read more about ui development
  Layout Anchors
- Another article about ui development
  Stacking views in SwiftUI
- Continue exploring ui development
  SwiftUI mix and match
Abstract types and methods in Swift
Published on 15 Mar 2022
Discover page available: Generics
In object-oriented programming, an abstract type provides a base implementation that other types can inherit from in order to gain access to some kind of shared, common functionality. What separates abstract types from regular ones is that they’re never meant to be used as-is (in fact, some programming languages even prevent abstract types from being instantiated directly), since their sole purpose is to act as a common parent for a group of related types.
For example, let’s say that we wanted to unify the way we load certain types of models over the network, by providing a shared API that we’ll be able to use to separate concerns, to facilitate dependency injection and mocking, and to keep method names consistent throughout our project.
One abstract type-based way to do that would be to use a base class that’ll act as that shared, unified interface for all of our model-loading types. Since we don’t want that class to ever be used directly, we’ll make it trigger a fatalError if its base implementation is ever called by mistake:
```
class Loadable<Model> {
    func load(from url: URL) async throws -> Model {
        fatalError("load(from:) has not been implemented")
    }
}
```
Then, each Loadable subclass will override the above load method in order to provide its loading functionality — like this:
```
class UserLoader: Loadable<User> {
    override func load(from url: URL) async throws -> User {
        ...
    }
}
```
If the above sort of pattern looks familiar, it’s probably because it’s essentially the exact same sort of polymorphism that we typically use protocols for in Swift. That is, when we want to define an interface, a contract, that multiple types can conform to through distinct implementations.
Protocols do have a significant advantage over abstract classes, though, in that the compiler will enforce that all of their requirements are properly implemented — meaning we no longer have to rely on runtime errors (such as fatalError) to guard against improper use, since there’s no way to instantiate a protocol by itself.
So here’s what our Loadable and UserLoader types from before could look like if we were to go the protocol-oriented route, rather than using an abstract base class:
```
protocol Loadable {
    associatedtype Model
    func load(from url: URL) async throws -> Model
}

class UserLoader: Loadable {
    func load(from url: URL) async throws -> User {
        ...
    }
}
```
Note how we’re now using an associated type to enable each Loadable implementation to decide what exact Model that it wants to load — which gives us a nice mix between full type safety and great flexibility.
So, in general, protocols are definitely the preferred way to declare abstract types in Swift, but that doesn’t mean that they’re perfect. In fact, our protocol-based Loadable implementation currently has two main drawbacks:
- First, since we had to add an associated type to our protocol in order to keep our setup generic and type-safe, that means that Loadable can no longer be referenced directly.
- And second, since protocols can’t contain any form of storage, if we wanted to add any stored properties that all Loadable implementations could make use of, we’d have to re-declare those properties within every single one of those concrete implementations.
That property storage aspect is really a huge advantage of our previous, abstract class-based setup. So if we were to revert Loadable back to a class, then we’d be able to store all objects that our subclasses would need right within our base class itself — removing the need to duplicate those properties across multiple types:
```
class Loadable<Model> {
    let networking: Networking
let cache: Cache<URL, Model>

    init(networking: Networking, cache: Cache<URL, Model>) {
        self.networking = networking
        self.cache = cache
    }

    func load(from url: URL) async throws -> Model {
        fatalError("load(from:) has not been implemented")
    }
}

class UserLoader: Loadable<User> {
    override func load(from url: URL) async throws -> User {
        if let cachedUser = cache.value(forKey: url) {
            return cachedUser
        }

        let data = try await networking.data(from: url)
        ...
    }
}
```
So, what we’re dealing with here is essentially a classic trade-off scenario, where both approaches (abstract classes vs protocols) give us a different set of pros and cons. But what if we could combine the two to sort of get the best of both worlds?
If we think about it, the only real issue with the abstract class-based approach is that fatalError that we had to add within the method that each subclass is required to implement, so what if we were to use a protocol just for that specific method? Then we could still keep our networking and cache properties within our base class — like this:
```
protocol LoadableProtocol {
    associatedtype Model
    func load(from url: URL) async throws -> Model
}

class LoadableBase<Model> {
    let networking: Networking
let cache: Cache<URL, Model>

    init(networking: Networking, cache: Cache<URL, Model>) {
        self.networking = networking
        self.cache = cache
    }
}
```
The main disadvantage of that approach, though, is that all concrete implementations will now have to both subclass LoadableBase and declare that they conform to our new LoadableProtocol:
```
class UserLoader: LoadableBase<User>, LoadableProtocol {
    ...
}
```
That might not be a huge issue, but it does arguably make our code a bit less elegant. The good news, though, is that we can actually solve that issue by using a generic type alias. Since Swift’s composition operator, &, supports combining a class with a protocol, we can re-introduce our Loadable type as a combination between LoadableBase and LoadableProtocol:
```
typealias Loadable<Model> = LoadableBase<Model> & LoadableProtocol
```
That way, concrete types (such as UserLoader) can simply declare that they’re Loadable-based, and the compiler will ensure that all such types implement our protocol’s load method — while still enabling those types to use the properties declared within our base class as well:
```
class UserLoader: Loadable<User> {
    func load(from url: URL) async throws -> User {
        if let cachedUser = cache.value(forKey: url) {
            return cachedUser
        }

        let data = try await networking.data(from: url)
        ...
    }
}
```
Neat! The only real disadvantage of the above approach is that Loadable still can’t be referenced directly, since it’s still partially a generic protocol under the hood. That might not actually be an issue, though — and if that ever becomes the case, then we could always use techniques such as type erasure to get around such problems.
Another slight caveat with our new type alias-based Loadable setup is that such combined type aliases cannot be extended, which could become an issue if we wanted to provide a few convenience APIs that we don’t want to (or can’t) implement directly within our LoadableBase class.
One way to address that issue, though, would be to declare everything that’s needed to implement those convenience APIs within our protocol, which would then enable us to extend that protocol by itself:
```
protocol LoadableProtocol {
    associatedtype Model

    var networking: Networking { get }
var cache: Cache<URL, Model> { get }

    func load(from url: URL) async throws -> Model
}

extension LoadableProtocol {
    func loadWithCaching(from url: URL) async throws -> Model {
        if let cachedModel = cache.value(forKey: url) {
            return cachedModel
        }

        let model = try await load(from: url)
        cache.insert(model, forKey: url)
        return model
    }
}
```
So that’s a few different ways to use abstract types and methods in Swift. Subclassing might not currently be as popular as it once was (and remains to be within other programming languages), but I still think these sorts of techniques are great to have within our overall Swift development toolbox.
If you have any questions, comments, or feedback, then feel free to reach out via either Twitter or email.
Thanks for reading!
- Generics
  Learn how to fully utilize Swift’s powerful generics system.
- Read more about protocols
  Alternatives to protocols in Swift
  Four different ways of defining abstractions in Swift.
- Another article about protocols
  Creating custom SwiftUI container views
  Using a dedicated protocol to make it easy to define new containers.
Judo
- Sponsored
Published on 08 Mar 2022
My thanks to Judo for sponsoring Swift by Sundell — both the website and the podcast — during this first quarter of the year. Those of you who have been following my work for a while might know that I’m a big fan of the concept of “server-driven UIs”, where a UI fetches its entire view configuration from a remote server, rather than just downloading its data models.
While I don’t recommend building an entire app that way — for certain kinds of screens, such as onboarding or payment flows, home screens or feeds, or other kinds of dynamic, content-driven views — being able to instantly change the way a given view is presented can be incredibly powerful. It can help make an app feel much more dynamic and up-to-date, while also letting teams iterate much quicker on such an app’s UI.
However, building all of the infrastructure required to actually implement fully native, server-driven UIs is often incredibly complicated and time-consuming. That’s why, so far, we’ve mostly seen big tech companies adopt that kind of UI paradigm — but now, thanks to Judo, any team can easily start using server-driven UIs within their apps.
Judo essentially consists of two parts. First, you’ve got a really nice, fully native Mac app that lets you build UIs completely visually — think Interface Builder or the SwiftUI canvas, but with a lot more power and flexibility:
Then, Judo also provides SDKs for both iOS and Android that let you dynamically load and configure the experiences you’ve built using that Mac app directly within your mobile app.
That means that you get to decide exactly when and where you want to deploy your Judo-based views, and those views can then seamlessly interact with the rest of your app. Your users won’t even be able to tell the difference between the views that you’ve built from scratch and those that are powered by Judo — since all views remain completely native.
Once those views are in place, you’re then free to iterate on them however you wish, and you can instantly deploy your changes server-side, without requiring you to submit a new binary to the App Store.
If this sounds interesting to you, then head over to judo.app/sundell to try Judo completely for free, and to help support Swift by Sundell in the process.
Basics: Equality
Published on 04 Mar 2022
Checking whether two objects or values are considered equal is definitely one of the most commonly performed operations in all of programming. So, in this article, let’s take a look at how Swift models the concept of equality, and how that model varies between value and reference types.
One the most interesting aspects of Swift’s implementation of equality is that it’s all done in a very protocol-oriented way — meaning that any type can become equatable by conforming to the Equatable protocol, which can be done like this:
```
struct Article: Equatable {
    static func ==(lhs: Self, rhs: Self) -> Bool {
        lhs.title == rhs.title && lhs.body == rhs.body
    }

    var title: String
    var body: String
}
```
The way that we conform to Equatable in the above example is by implementing an overload of the == operator, which accepts the two values to compare (lhs, the left-hand side value, and rhs, the right-hand side value), and it then returns a boolean result as to whether those two values should be considered equal.
The good news, though, is that we typically don’t have to write those kinds of == operator overloads ourselves, since the compiler is able to automatically synthesize such implementations whenever a type’s stored properties are all Equatable themselves. So in the case of the above Article type, we can actually remove our manual equality checking code, and simply make that type look like this:
```
struct Article: Equatable {
    var title: String
    var body: String
}
```
The fact that Swift’s equality checks are so protocol-oriented also gives us a ton of power when working with generic types. For example, a collection of Equatable-conforming values (such as an Array or Set) are automatically considered equatable as well — without requiring any additional code on our part:
```
let latestArticles = [
    Article(
        title: "Writing testable code when using SwiftUI",
        body: "..."
    ),
    Article(title: "Combining protocols in Swift", body: "...")
]

let basicsArticles = [
    Article(title: "Loops", body: "..."),
    Article(title: "Availability checks", body: "...")
]

if latestArticles == basicsArticles {
    ...
}
```
The way that those kinds of collection equality checks work is through Swift’s conditional conformances feature, which enables a type to conform to a specific protocol only when certain conditions are met. For example, here’s how Swift’s Array type conforms to Equatable only when the elements that are being stored within a given array are also, in turn, Equatable-conforming — which is what makes it possible for us to check whether two Article arrays are considered equal:
```
extension Array where Element: Equatable {
    ...
}
```
Since none of the above logic is hard-coded into the compiler itself, we can also utilize that exact same conditional conformances-based technique if we wanted to make our own generic types conditionally equatable as well. For example, our code base might include some form of Group type that can be used to label a group of related values:
```
struct Group<Value> {
    var label: String
    var values: [Value]
}
```
To make that Group type conform to Equatable when it’s being used to store Equatable values, we simply have to write the following empty extension, which looks almost identical to the Array extension that we took a look at above:
```
extension Group: Equatable where Value: Equatable {}
```
With the above in place, we can now check whether two Article-based Group values are equal, just like we could when using arrays:
```
let latestArticles = Group(
    label: "Latest",
    values: [
        Article(
            title: "Writing testable code when using SwiftUI",
            body: "..."
        ),
        Article(title: "Combining protocols in Swift", body: "...")
    ]
)

let basicsArticles = Group(
    label: "Basics",
    values: [
        Article(title: "Loops", body: "..."),
        Article(title: "Availability checks", body: "...")
    ]
)

if latestArticles == basicsArticles {
    ...
}
```
Just like collections, Swift tuples can also be checked for equality whenever their stored values are all Equatable-conforming:
```
let latestArticles = (
    first: Article(
        title: "Writing testable code when using SwiftUI",
        body: "..."
    ),
    second: Article(title: "Combining protocols in Swift", body: "...")
)

let basicsArticles = (
    first: Article(title: "Loops", body: "..."),
    second: Article(title: "Availability checks", body: "...")
)

if latestArticles == basicsArticles {
    ...
}
```
However, collections containing the above kind of equatable tuples do not automatically conform to Equatable. So, if we were to put the above two tuples into two identical arrays, then those wouldn’t be considered equatable:
```
let firstArray = [latestArticles, basicsArticles]
let secondArray = [latestArticles, basicsArticles]

// Compiler error: Type '(first: Article, second: Article)'
// cannot conform to 'Equatable':
if firstArray == secondArray {
    ...
}
```
The reason why the above doesn’t work (at least not out of the box) is because — like the emitted compiler message alludes to — tuples can’t conform to protocols, which means that the Equatable-conforming Array extension that we took a look at earlier won’t take effect.
There is a way to make the above work, though, and while I realize that the following generic code might not belong in an article labeled as ”Basics”, I still thought it would be worth taking a quick look at — since it illustrates just how flexible Swift’s equality checks are, and that we’re not just limited to implementing a single == overload in order to conform to Equatable.
So if we were to add another, custom == overload, specifically for arrays that contain equatable two-element tuples, then the above code sample will actually compile successfully:
```
extension Array {
    // This '==' overload will be used specifically when two
    // arrays containing two-element tuples are being compared:
    static func ==<A: Equatable, B: Equatable>(
        lhs: Self,
        rhs: Self
    ) -> Bool where Element == (A, B) {
        // First, we verify that the two arrays that are being
        // compared contain the same amount of elements:
        guard lhs.count == rhs.count else {
            return false
        }

        // We then "zip" the two arrays, which will give us
        // a collection where each element contains one element
        // from each array, and we then check that each of those
        // elements pass a standard equality check:
        return zip(lhs, rhs).allSatisfy(==)
    }
}
```
Above we can also see how Swift operators can be passed as functions, since we’re able to pass == directly to our call to allSatisfy.
So far, we’ve been focusing on how value types (such as structs) behave when checked for equality, but what about reference types? For example, let’s say that we’ve now decided to turn our previous Article struct into a class instead, how would that impact its Equatable implementation?
```
class Article: Equatable {
    var title: String
    var body: String
    
    init(title: String, body: String) {
        self.title = title
        self.body = body
    }
}
```
The first thing that we’ll notice when performing the above change is that the compiler is no longer able to automatically synthesize our type’s Equatable conformance — since that feature is limited to value types. So if we wanted our Article type to remain a class, then we’d have to manually implement the == overload that Equatable requires, just like we did at the beginning of this article:
```
class Article: Equatable {
    static func ==(lhs: Article, rhs: Article) -> Bool {
    lhs.title == rhs.title && lhs.body == rhs.body
}

    var title: String
    var body: String

    init(title: String, body: String) {
        self.title = title
        self.body = body
    }
}
```
However, classes that are subclasses of any kind of Objective-C-based class do inherit a default Equatable implementation from NSObject (which is the root base class for almost all Objective-C classes). So, if we were to make our Article class an NSObject subclass, then it would actually become Equatable without strictly requiring us to implement a custom == overload:
```
class Article: NSObject {
    var title: String
    var body: String

    init(title: String, body: String) {
        self.title = title
        self.body = body
        super.init()
    }
}
```
While it might be tempting to use the above subclassing technique to avoid having to write custom equality checking code, it’s important to point out that the only thing that the default Objective-C-provided Equatable implementation will do is to check if two classes are the same instance — not if they contain the same data. So even though the following two Article instances have the same title and body, they won’t be considered equal when using the above NSObject-based approach:
```
let articleA = Article(title: "Title", body: "Body")
let articleB = Article(title: "Title", body: "Body")
print(articleA == articleB) // false
```
Performing those kinds of instance checks can be really useful, though — as sometimes we might want to be able to check whether two class-based references point to the same underlying instance. We don’t need our classes to inherit from NSObject to do that, though, since we can use Swift’s built-in triple-equals operator, ===, to perform such a check between any two references:
```
let articleA = Article(title: "Title", body: "Body")
let articleB = articleA
print(articleA === articleB) // true
```
To learn more about the above concept, check out “Identifying objects in Swift”.
With that, I believe that we’ve covered all of the basics as to how equality works in Swift — for both values and objects, using either custom or automatically generated implementations, as well as how generics can be made conditionally equatable. If you have any questions, comments, or feedback, then feel free to reach out via either Twitter or email.
Thanks for reading!

Podcast episode
113: “Where is Swift headed in 2022?” with special guest JP Simard
Published on 27 Feb 2022
On this 2022 season premiere, JP Simard returns to the show to discuss what’s next for Swift in 2022, and what kinds of improvements and new features that might be coming to the language during the year.
Article
Writing testable code when using SwiftUI
- swiftui
- unit testing
Published on 17 Feb 2022
Let’s take a look at how we can make our UI-related logic fully testable, even when that logic is primarily used within SwiftUI-based views.
Article
Combining protocols in Swift
- protocols
- generics
Published on 09 Feb 2022
Let’s take a look at various ways to combine multiple protocols into new functionality, either by using protocol extensions, composition, or by defining dedicated types.
Article
Memory management when using async/await in Swift
- concurrency
- memory management
Published on 03 Feb 2022
Managing an app’s memory is something that tends to be especially tricky when it comes to asynchronous code, so let’s take a look at how to do just that when using async/await.
Article
Automatically retrying an asynchronous Swift Task
- concurrency
Published on 25 Jan 2022
A few examples on how to use Swift Concurrency to write asynchronous operations that are automatically retried if an error was encountered.
Article
Backgrounds and overlays in SwiftUI
- swiftui
Published on 20 Jan 2022
How SwiftUI enables us to stack views along the Z axis, which in turn makes it possible to create all sorts of backgrounds, overlays, and other effects.
Basics article
Loops
Published on 13 Jan 2022
A look at many different built-in ways to iterate over arrays, dictionaries, and other Swift collections.
Article
Creating Combine-compatible versions of async/await-based APIs
- combine
- concurrency
Published on 05 Jan 2022
Creating convenience APIs that make it possible to convert async/await-based functions into Combine publishers.

SwiftUI

Concurrency

Generics

Unit Testing

Recently published

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69: “Swift Playgrounds” with special guests Holly Borla and Grace Kendall

Specialized extensions using generic type constraints

Using closure types in generic constraints

Opaque parameter types

Primary associated types

Existentials and the ‘any’ keyword

Conclusion

Generics

Combining protocols in Swift

Creating a dedicated identifier type

Equality

Organizing default argument values

Using ‘@unknown default’ within switch statements

Say hello to UIHostingConfiguration

Managing state updates

Bridged swipe actions

Conclusion

A first look at SwiftUI’s new StateObject property wrapper

Handling keyUp and keyDown events on iOS 13.4 and later

SwiftUI is a game changer

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SwiftUI

45: “That’s why we refactor” with special guests Chris Eidhof and Matt Gallagher

Creating custom SwiftUI container views

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29: “Flexing your learning muscle” with special guest Niels van Hoorn

77: “Adopting new system features” with special guest Jordan Morgan

Picking the right data structure in Swift

Generics

Chained implicit member expressions in Swift 5.4

Custom operators in Swift

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Layout Anchors

Stacking views in SwiftUI

SwiftUI mix and match

Generics

Alternatives to protocols in Swift

Creating custom SwiftUI container views

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