Starting in Xcode 13, SwiftUI views can now be previewed in landscape orientation using the new previewInterfaceOrientation modifier. For example, here we’re previewing a MenuView in both portrait and landscape by creating two instances of our view within its PreviewProvider:

struct MenuView_Previews: PreviewProvider {
    static var previews: some View {
        MenuView()
        MenuView().previewInterfaceOrientation(.landscapeRight)
    }
}

Note how we only need to apply the above modifier when we want to preview a given view using an orientation other than portrait, since that orientation is used by default.

However, while the above code works perfectly fine when working on a project that has iOS 15 as its minimum deployment target, we’ll end up getting a compiler error if our app also supports earlier system versions, since (even though this is preview-specific code) we’re using an API that was introduced in iOS 15.

To solve that problem, we could either use an inline availability check:

struct MenuView_Previews: PreviewProvider {
    static var previews: some View {
        MenuView()

        if #available(iOS 15, *) {
            MenuView().previewInterfaceOrientation(.landscapeRight)
        }
    }
}

Or, we could make our entire preview provider require iOS 15:

@available(iOS 15.0, *)
struct MenuView_Previews: PreviewProvider {
    static var previews: some View {
        MenuView()
        MenuView().previewInterfaceOrientation(.landscapeRight)
    }
}

Both of the above solutions work, but it would arguably be quite inconvenient to have to insert those availability statements every single time that we want to preview one of our views in landscape.

One way to address that would be to wrap the new previewInterfaceOrientation modifier in a custom method that performs the required availability check, and then falls back to simply rendering our view as-is if previewing on an older OS version (which, at the time of writing, doesn’t even seem to be possible when using Xcode 13):

extension View {
    @ViewBuilder
    func previewInLandscape() -> some View {
        if #available(iOS 15, *) {
            previewInterfaceOrientation(.landscapeRight)
        } else {
            self
        }
    }
}

To learn more about annotating functions with the @ViewBuilder attribute, and why doing so is required in the above kind of situation, check out this short article.

With the above in place, we can now simply use our new, custom modifier method whenever we want to preview one of our views in landscape, without having to add any availability checks at each call site:

struct MenuView_Previews: PreviewProvider {
    static var previews: some View {
        MenuView()
        MenuView().previewInLandscape()
    }
}

Being able to preview SwiftUI views in landscape is a fantastic addition to Xcode’s preview system, and using the above extension we’ll be able to use this new feature without having to make our preview code any more complicated.

Hope you’ll find this tip useful, and thanks for reading!

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When writing asynchronous code using Combine, we might sometimes want to share the result of a given set of concurrent operations, rather than performing duplicate work for each one. Let’s take a look at how the share operator can enable us to do that in a really neat way.

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Duplicate, concurrent network calls

As an example, let’s say that we’re working on the following ArticleLoader, which uses URLSession to load an Article model from a given URL:

class ArticleLoader {
    private let urlSession: URLSession
    private let decoder: JSONDecoder

    init(urlSession: URLSession = .shared,
         decoder: JSONDecoder = .init()) {
        self.urlSession = urlSession
        self.decoder = decoder
    }

    func loadArticle(from url: URL) -> AnyPublisher<Article, Error> {
        urlSession
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Article.self, decoder: decoder)
            .eraseToAnyPublisher()
    }
}

Now let’s say that we’re expecting the above loadArticle method to be called multiple times, in either parallel or quick succession, with the same URL — which currently would lead to duplicate network requests, as each call to our method produces a brand new publisher.

Reusing publishers

To address that, let’s store each of the publishers that we create within a dictionary (keyed by the URL that each publisher is for), and then when we receive a loadArticle call, we’ll first check if that dictionary contains an existing publisher that can be reused — like this:

class ArticleLoader {
    typealias Publisher = AnyPublisher<Article, Error>

    private let urlSession: URLSession
    private let decoder: JSONDecoder
    private var publishers = [URL: Publisher]()
    ...

    func loadArticle(from url: URL) -> Publisher {
        if let publisher = publishers[url] {
    return publisher
}

        let publisher = urlSession
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Article.self, decoder: decoder)
            .handleEvents(receiveCompletion: { [weak self] _ in
                self?.publishers[url] = nil
            })
            .eraseToAnyPublisher()

        publishers[url] = publisher
        return publisher
    }
}

Note how we also remove each publisher from our dictionary once it completes, as to avoid keeping old publishers around in memory. We use receiveCompletion, rather than receiveOutput, to also be notified whenever an error was encountered.

Now, looking at the above code, it might initially seem like we’ve solved our problem. However, if we look at our network logs (or simply put a print("Done") call within our handleEvents closure), then it turns out that we’re actually still performing multiple, duplicate operations. How can that be?

It turns out that even if we are indeed reusing our publisher instances, that doesn’t guarantee that we’re actually reusing the work that those publishers are performing. In fact, by default, each publisher will run through our entire data pipeline for each subscriber that attaches to it. That might initially seem rather odd, so let’s examine that behavior from a slightly different angle.

New subscriber, new values

As another quick example, here we’re creating a publisher that uses a Timer to publish a new random number every second, and we’re then attaching two separate subscribers to that publisher, both of which simply print the numbers that they receive:

var cancellables = Set<AnyCancellable>()

let randomNumberGenerator = Timer
        .publish(every: 1, on: .main, in: .common)
        .autoconnect()
        .map { _ in Int.random(in: 1...100) }

randomNumberGenerator
    .sink { number in
        print(number)
    }
    .store(in: &cancellables)

randomNumberGenerator
    .sink { number in
        print(number)
    }
    .store(in: &cancellables)

It would arguably be a bit strange if both of our subscribers were given the exact same number every second, given that we’re expecting each number to be completely random (and therefore somewhat “unique”). So, from that perspective, the fact that Combine publishers produce separate output for each subscriber does arguably make a lot of sense.

But, going back to our ArticleLoader, how can we then modify that default behavior to prevent duplicate network calls from being performed?

Using the share operator

The good news is that all that we have to do is to use the share operator, which (like its name implies) modifies a given Combine pipeline so that the result of its work is automatically shared among all subscribers:

class ArticleLoader {
    ...

    func loadArticle(from url: URL) -> Publisher {
        if let publisher = publishers[url] {
            return publisher
        }

        let publisher = urlSession
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Article.self, decoder: decoder)
            .handleEvents(receiveCompletion: { [weak self] _ in
                self?.publishers[url] = nil
            })
            .share()
            .eraseToAnyPublisher()

        publishers[url] = publisher
        return publisher
    }
}

With just that tiny change in place, we’ve now completely solved our problem. Now, even if multiple loadArticle calls happen in quick succession, only a single network call will be performed, and its result will be reported to each of those call sites.

Well, perhaps “complete solved” isn’t entirely true, because our implementation still has one potential issue — it currently doesn’t account for the fact that our ArticleLoader is likely to be called on a different thread than what URLSession returns its data task output on. While it’s likely that this will never end up causing any actual problems, how about we do a quick bonus round and make our implementation completely thread-safe while we’re at it?

To do that, let’s make a few tweaks to our loadArticle implementation. First, we’ll base our Combine pipeline on our input URL, and we’ll then immediately jump over to an internal DispatchQueue, which we’ll also use when receiving a completion event from one of our publishers. That way, we can guarantee that our publishers dictionary will always be both read and written to on the exact same queue:

class ArticleLoader {
    ...
    private let queue = DispatchQueue(label: "ArticleLoader")

    func loadArticle(from url: URL) -> Publisher {
        Just(url)
            .receive(on: queue)
            .flatMap { [weak self, urlSession, queue, decoder] url -> Publisher in
                if let publisher = self?.publishers[url] {
                    return publisher
                }

                let publisher = urlSession
                    .dataTaskPublisher(for: url)
                    .map(\.data)
                    .decode(type: Article.self, decoder: decoder)
                    .receive(on: queue)
                    .handleEvents(receiveCompletion: { [weak self] _ in
                        self?.publishers[url] = nil
                    })
                    .share()
                    .eraseToAnyPublisher()

                self?.publishers[url] = publisher
                return publisher
            }
            .eraseToAnyPublisher()
    }
}

With those tweaks in place, we now have a completely thread-safe implementation that successfully reuses publishers to avoid having to perform any duplicate work. A potential next step could be to add caching to the above implementation (we currently just rely on the default caching mechanism that URLSession provides out of the box), if that’s something that we think would be useful.

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Conclusion

So that’s how the share operator can be used to avoid duplicate work within a Combine pipeline. I hope you found this article useful and interesting, and if you did, feel free to share it with a friend or on social media. That always helps me out a lot! And, if you’ve got any questions, comments, or feedback, then feel free to reach out via email.

Thanks for reading!

One of the major advantages of Swift’s built-in Codable API is how the compiler is able to automatically synthesize many different encoding and decoding implementations when using it. In many cases, all that we have to do to enable a Swift type to be serialized into formats like JSON is to mark it as Codable, and the compiler takes care of the rest.

Let’s take a look at how that automatic synthesis works for enums specifically, and how that part of the system has been upgraded in Swift 5.5.

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Raw representable enums

Enums generally come in two variants — those that are backed by raw values (such as Int or String), and those that contain associated values. Ever since the introduction of Codable in Swift 4.0, enums that belong to the former category have always supported compiler synthesis.

So, for example, let’s say that we’re working on an app that includes the following String-backed enum, which conforms to Codable:

enum MediaType: String, Codable {
    case article
    case podcast
    case video
}

Since the compiler is able to automatically synthesize all of the code needed to encode and decode enums with raw values, we typically don’t have to write any more code than that ourselves — meaning that we’re now free to use the above enum within other Codable types, like this:

struct Item: Codable {
    var title: String
    var url: URL
    var mediaType: MediaType
}

If we now were to encode an instance of the above Item type into JSON, then we’d get the following kind of output (since MediaType values will automatically be encoded and decoded using the raw String values that back them):

{
    "title": "Swift by Sundell",
    "url": "https://swiftbysundell.com/podcast",
    "mediaType": "podcast"
}

So far so good. But what if we instead wanted to encode or decode an enum that supports associated values? Let’s take a look at that next.

Associated values

Before Swift 5.5, if we wanted to make an enum that contains associated values conform to Codable, then we’d have to write all of that code manually. However, that’s no longer the case, as the compiler has received an upgrade that now makes it capable of auto-synthesizing serialization code for such enums as well.

For example, the following Video enum can now be made Codable without requiring any custom code on our part:

enum Video: Codable {
    case youTube(id: String)
    case vimeo(id: String)
    case hosted(url: URL)
}

To see what the above type looks like when encoded, let’s create an instance of a VideoCollection that stores an array of Video values:

struct VideoCollection: Codable {
    var name: String
    var videos: [Video]
}

let collection = VideoCollection(
    name: "Conference talks",
    videos: [
    .youTube(id: "ujOc3a7Hav0"),
    .vimeo(id: "234961067")
]
)

If we then encode the above collection value into JSON, then we’ll get the following result:

{
    "name": "Conference talks",
    "videos": [
        {
            "youTube": {
    "id": "ujOc3a7Hav0"
}
        },
        {
            "vimeo": {
    "id": "234961067"
}
        }
    ]
}

So, by default, when we let the compiler automatically synthesize the Codable conformance for an enum with associated values, then the names of our cases and the labels for the associated values within them will be used when calculating that type’s serialization format.

For unlabelled associated values, underscored numeric keys (like _0, _1, and so on) will be used by default.

Key customization

Just like when working with structs and classes, we’re able to customize what keys that will be used when encoding or decoding an enum’s cases and associated values, and we can even use that capability to omit certain cases entirely.

For example, let’s say that we wanted to extend our Video enum to add support for local videos, but that there’s no reasonable way for us to serialize the data for those videos.

While we could always create a completely separate type for representing such videos, we could also use a nested CodingKeys enum to tell the compiler to ignore the local case when generating our Video type’s Codable implementation.

Here we’ve done just that, and we’ve also customized the hosted case so that it’s referred to as custom when serialized:

enum Video: Codable {
    case youTube(id: String)
    case vimeo(id: String)
    case hosted(url: URL)
    case local(LocalVideo)
}

extension Video {
    enum CodingKeys: String, CodingKey {
        case youTube
        case vimeo
        case hosted = "custom"
    }
}

If needed, we could even customize what keys that are used for the associated values within a specific case. For example, here’s how we could declare that we’d like the youTube case’s id value to be serialized as youTubeID:

extension Video {
    enum YouTubeCodingKeys: String, CodingKey {
        case id = "youTubeID"
    }
}

The above YouTubeCodingKeys enum is matched to our youTube case by name, so if we also wanted to customize the vimeo case, then we could add a VimeoCodingKeys enum for that.

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Conclusion

Although Codable’s automatic synthesis does have its limits (particularly when working with serialized formats that are vastly different from how we’d like to organize the data within our Swift types), it’s incredibly convenient — and is often particularly useful when working with locally stored values, such as when caching values on disk, or when reading bundled configuration files.

Regardless, the fact that enums with associated values can now join the auto-synthesis party is definitely a good thing in terms of consistency, and should prove to be quite useful within many different code bases — including my own.

Got questions, comments, or feedback? You’re more than welcome to reach out via email.

Thanks for reading!

New in Swift 5.5: It’s now possible to conditionally compile postfix member expressions using Swift’s #if compiler directive. Let’s take a look at what kinds of situations that this new feature could be really useful in.

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Working around platform differences

Although many of the built-in APIs and frameworks work exactly the same way across Apple’s platforms, there are certain differences that we might need to work around. For example, when using SwiftUI to build an app that runs on both iOS and the Mac, we might find ourselves in the following type of situation — in which we’re getting an error when attempting to apply the iOS-specific InsetGroupedListStyle to a List:

struct ItemList: View {
    var items: [Item]

    var body: some View {
        List {
            ...
        }
        // Error: 'InsetGroupedListStyle' is unavailable in macOS
        .listStyle(InsetGroupedListStyle())
    }
}

In general, these kinds of issues can be worked around using a compile-time platform check — but before Swift 5.5, we’d have to first break our List out into a separate expression, and then apply different listStyle modifiers separately using an #if-based operating system condition:

struct ItemList: View {
    var items: [Item]

    var body: some View {
        let list = List {
            ...
        }

        #if os(iOS)
        list.listStyle(InsetGroupedListStyle())
        #else
        list.listStyle(InsetListStyle())
        #endif
    }
}

In isolation, the above code doesn’t look that bad, but if our ItemList view were to gain additional subviews (or if we’d need to perform additional compile-time checks within it), then its body could quickly become quite hard to read.

So perhaps a more robust solution to this problem would be to instead extract the above platform check into a dedicated modifier method — for example like this:

extension View {
    func defaultListStyle() -> some View {
        #if os(iOS)
        listStyle(InsetGroupedListStyle())
        #else
        listStyle(InsetListStyle())
        #endif
    }
}

With the above in place, we can simply apply our new defaultListStyle modifier within our ItemList view, and we no longer have to deal with any platform differences when constructing our actual UI:

struct ItemList: View {
    var items: [Item]

    var body: some View {
        List {
            ...
        }
        .defaultListStyle()
    }
}

However, while the above is certainly a neat technique when working with modifiers and styles that we’re looking to reuse multiple times across a project, always having to define a dedicated method each time we encounter a platform difference can become quite tedious.

This is where Swift 5.5’s new support for #if conditions within postfix member expressions comes in.

Inline checks within expressions

When using Swift 5.5, we now have the option to inline #if directives right within our expressions. So, going back to our ItemList, we can now conditionally apply each of our listStyle modifiers completely inline — without first having to break our expression up into multiple parts:

struct ItemList: View {
    var items: [Item]

    var body: some View {
        List {
            ...
        }
        #if os(iOS)
        .listStyle(.insetGrouped)
        #else
        .listStyle(.inset)
        #endif
    }
}

Above we’re also making use of another new language feature that enables us to refer to SwiftUI list styles (and other kinds of protocol-based types) using dot syntax. Check out “Using static protocol APIs to create conforming instances” to learn more about that.

Nice! Of course, this new capability also works for other kinds of #if-based compile-time checks — including using the standard DEBUG flag to check if our app is being compiled using its debug build configuration, and any custom compiler flags that we might’ve defined.

As an example, here’s how we could use a custom flag to conditionally visualize the final rendering size of one of our views:

struct DynamicIcon: View {
    var name: String

    var body: some View {
        Image(systemName: name)
            .resizable()
            .aspectRatio(contentMode: .fit)
            #if SHOW_ICON_SIZES
            .overlay(GeometryReader { geo in
                Text("\(Int(geo.size.width)) x \(Int(geo.size.height))")
                    .font(.footnote)
                    .background(Color.blue)
                    .foregroundColor(.white)
            })
            #endif
    }
}

To learn more about how to define and use custom compiler flags, check out “Using compiler directives in Swift”.

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Conclusion

So, how should we pick between these new inline #if conditions versus creating dedicated modifiers for working around platform differences and for performing other kinds of compile-time checks? While every developer will certainly have their own preferences — for me, it all depends on whether a given pattern will be repeated within a code base, or whether it’s something that we’re only performing once.

For repeated compile-time checks, I still prefer to create dedicated functions, since that lets me wrap those checks up into a much simpler API, but when working around minor platform differences (like we did above), I prefer the new inline style. It’s already proving to be quite useful when working on cross-platform SwiftUI-based projects.

If you have any questions, comments, or feedback, then feel free to reach out via email.

Thanks for reading!

When iterating over any Swift collection using a standard for loop, there are two key components that decide what elements that will be passed into our iteration code — a sequence, and an iterator. For example, Swift’s standard Array type is a sequence, and uses IndexingIterator as its iterator type.

While we very often interact directly with sequences when writing our Swift code, we rarely have to deal with iterators ourselves, as the language will automatically manage those instances for us whenever we’re using a for loop.

The fact that iterations are explicitly controlled by dedicated types is really powerful, though, since that enables us to write our own, completely custom sequences that can be iterated over the exact same way as when looping through built-in types like Array, Dictionary, and Set.

In this article, let’s take a look at how this system works, and how it extends into the world of Swift concurrency — enabling us to create completely asynchronous sequences and streams that deliver their values over time.

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Sequences and iterators

Let’s say that we wanted to build a custom sequence that lets us download data from a series of URLs. To make that happen, we’ll first need to implement a custom type that conforms to the Sequence protocol, which in turn creates an iterator using the required makeIterator method — like this:

struct RemoteDataSequence: Sequence {
    var urls: [URL]

    func makeIterator() -> RemoteDataIterator {
        RemoteDataIterator(urls: urls)
    }
}

Next, let’s implement the above RemoteDataIterator type, which performs its iterations by incrementing an index property every time that a new element was requested by the system:

struct RemoteDataIterator: IteratorProtocol {
    var urls: [URL]
    fileprivate var index = 0

    mutating func next() -> Data? {
        guard index < urls.count else {
            return nil
        }

        let url = urls[index]
        index += 1

        // If a download fails, we simply move on to
        // the next URL in this case:
        guard let data = try? Data(contentsOf: url) else {
            return next()
        }

        return data
    }
}

We don’t need to worry about managing multiple, concurrent iterations, since the system will automatically create a fresh new iterator (using our sequence’s makeIterator method) every time a new for loop is started.

With the above in place, we’ll now be able to iterate over all of our downloaded data using the exact same syntax as we’d use when iterating over an array:

for data in RemoteDataSequence(urls: urls) {
    ...
}

Really cool! However, downloading data synchronously like that probably isn’t a very good idea (except when writing things like scripts or command line tools), as doing so will completely block the current thread until all downloads have completed. So let’s explore how we could turn the above into an asynchronous sequence instead.

Asynchronous iterations

Swift 5.5’s new concurrency system introduces the concept of asynchronous sequences and iterators, which are defined in almost the exact same way as their synchronous counterparts. So, to make our RemoteDataSequence asynchronous, all that we have to do is to make it conform to the AsyncSequence protocol and implement the makeAsyncIterator method — like this:

struct RemoteDataSequence: AsyncSequence {
    typealias Element = Data

    var urls: [URL]

    func makeAsyncIterator() -> RemoteDataIterator {
        RemoteDataIterator(urls: urls)
    }
}

Note that the above typealias shouldn’t really be needed, since the compiler should be able to infer our sequence’s Element type, but that doesn’t seem to be the case as of Xcode 13.0.

Next, let’s give our RemoteDataIterator an async makeover as well — which involves adding the async and throws keywords to its next method (since we want our iteration to be able to yield errors when a data download failed) — and we can then use the built-in URLSession networking API to download our data completely asynchronously:

struct RemoteDataIterator: AsyncIteratorProtocol {
    var urls: [URL]
    fileprivate var urlSession = URLSession.shared
    fileprivate var index = 0

    mutating func next() async throws -> Data? {
        guard index < urls.count else {
            return nil
        }

        let url = urls[index]
        index += 1

        let (data, _) = try await urlSession.data(from: url)
        return data
    }
}

To learn more about the new, async/await-powered URLSession APIs, check out this article over on WWDC by Sundell & Friends.

With the above changes in place, our RemoteDataSequence has now been turned into a fully asynchronous sequence, which requires us to use await (and, in this case, try) when iterating over its elements — since our data will now be downloaded in the background, and will be delivered into our for loop when ready:

for try await data in RemoteDataSequence(urls: urls) {
    ...
}

The fact that async iterators can throw errors is really powerful, as that lets us automatically exit out of a for loop if an error was encountered, rather than requiring us to keep track of such errors manually. Of course, that doesn’t mean that all async sequences need to be capable of throwing. If we simply omit the throws keyword when declaring our iterator’s next method, then our sequence will be considered non-throwing (and we no longer need to use try when iterating over its elements).

Asynchronous streams

While being able to define completely custom, asynchronous sequences is incredibly powerful, the standard library also ships with two stand-alone types that enable us to create such sequences without having to define any types of our own. Those types are AsyncStream and AsyncThrowingStream, with the former letting us create non-throwing async sequences, while the latter gives us the option to throw errors.

Going back to the example of downloading data from a series of URLs, let’s take a look at how we could implement that same functionality using an AsyncThrowingStream, rather than declaring custom types. Doing so would involve kicking off an async Task, within which we yield all of the data that was downloaded, and we then finish by reporting any error that was encountered — like this:

func remoteDataStream(
    forURLs urls: [URL],
    urlSession: URLSession = .shared
) -> AsyncThrowingStream<Data, Error> {
    AsyncThrowingStream { continuation in
        Task {
            do {
                for url in urls {
                    let (data, _) = try await urlSession.data(from: url)
                    continuation.yield(data)
                }

                continuation.finish(throwing: nil)
            } catch {
                continuation.finish(throwing: error)
            }
        }
    }
}

While the above is a perfectly fine implementation, it can actually be simplified quite a bit using another AsyncThrowingStream initializer — which gives us a closure that’s already marked as async, within which we can focus on returning the next element in our stream:

func remoteDataStream(
    forURLs urls: [URL],
    urlSession: URLSession = .shared
) -> AsyncThrowingStream<Data, Error> {
    var index = 0

    return AsyncThrowingStream {
        guard index < urls.count else {
            return nil
        }

        let url = urls[index]
        index += 1

        let (data, _) = try await urlSession.data(from: url)
        return data
    }
}

Above we’re capturing the local index variable within our stream’s closure, enabling us to use it to keep track of the state of our iteration. To learn more about that technique, check out “Swift’s closure capturing mechanics”.

With either of the above two implementations in place, we can now iterate over our new async stream just like how we previously looped over our custom AsyncSequence:

for try await data in remoteDataStream(forURLs: urls) {
    ...
}

So AsyncStream and AsyncThrowingStream can be seen as concrete implementations of the AsyncSequence protocol, just like how Array is a concrete implementation of the synchronous Sequence protocol. In most situations, using a stream will probably be the most straightforward implementation, but if we want to gain complete control over a given iteration, then building a custom AsyncSequence will probably be the way to go.

How does all of this relate to Combine?

Now, if you’ve worked with Apple’s Combine framework, then you might be asking yourself how this new suite of async sequence APIs relates to that framework, given that they both enable us to emit and observe values over time.

While I already discussed this to some extent in my WWDC article “What Swift’s new concurrency features might mean for the future of Combine”, the way I look at it is that Combine is a fully-featured reactive programming framework, while this new async sequence system offers more low-level APIs for constructing any kind of async sequence — either with or without embracing a reactive programming style.

The good news, though, is that Combine has now been made fully AsyncSequence compatible, which enables us to turn any Publisher into such an async sequence of values. For example, here’s a Combine-powered version of our data downloading functionality from before:

func remoteDataPublisher(
    forURLs urls: [URL],
    urlSession: URLSession = .shared
) -> AnyPublisher<Data, URLError> {
    urls.publisher
        .setFailureType(to: URLError.self)
        .flatMap(maxPublishers: .max(1)) {
            urlSession.dataTaskPublisher(for: $0)
        }
        .map(\.data)
        .eraseToAnyPublisher()
}

To then convert the AnyPublisher that the above function returns into an AsyncSequence, all that we have to do is to access its values property — and the system will take care of the rest:

let publisher = remoteDataPublisher(forURLs: urls)

for try await data in publisher.values {
    ...
}

Very neat! The above API should prove to be incredibly useful within code bases that have existing Combine code, since it lets us keep using that code (without modifications!) even when adopting Swift’s new concurrency system.

To be able to go the other way around, and use async-marked APIs within Combine-based code, check out “Calling async functions within a Combine pipeline”.

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Conclusion

I hope that this article has given you a few new insights into how Swift’s new AsyncSequence and AsyncStream APIs work, how they can be used to implement various kinds of asynchronous sequences, and how those new APIs relate to Combine.

If you have any questions, comments, or feedback, then feel free to reach out via email.

Thanks for reading!

New in Swift 5.5: It’s now possible to define protocol APIs that let us use Swift’s very convenient “dot syntax” to create conforming instances, which in turn can make certain protocols act more like enums, while still retaining all of the flexibility that protocols give us.

For example, when applying a style to a SwiftUI List, we currently (in Swift 5.4) have to spell out the whole name of that style’s type — like this:

struct ItemList: View {
    var items: [Item]

    var body: some View {
        List(items) { item in
            ...
        }
        .listStyle(InsetGroupedListStyle())
    }
}

But now, we’re instead able to refer to the above style simply by typing .insetGrouped, which should feel a lot more intuitive to many Swift developers, as that’s the same type of syntax that we commonly use with other kinds of configuration APIs:

struct ItemList: View {
    var items: [Item]

    var body: some View {
        List(items) { item in
            ...
        }
        .listStyle(.insetGrouped)
    }
}

The good news is that the above new API style is even fully backward compatible with earlier versions of Apple’s operating systems (as long as we’re using Xcode 13 to build our app).

So how can we make use of this new feature within our own code as well? As an example, let’s say that an app that we’re working on contains the following ImageLoader API, which is modeled as a protocol that then has separate implementations for loading either internal or external images:

protocol ImageLoader {
    func loadImage(from url: URL) async throws -> Image
}

class ExternalImageLoader: ImageLoader {
    ...

    func loadImage(from url: URL) async throws -> Image {
        // Load the image from an external server.
        ...
    }
}

class AuthenticatedImageLoader: ImageLoader {
    private let token: AccessToken
    ...

    func loadImage(from url: URL) async throws -> Image {
        // Load the image from our app's own server, using
        // the loader's access token.
        ...
    }
}

To make it possible to refer to the above two ImageLoader implementations using dot syntax, all that we have to do is to define a type-constrained extension for each one — which in turn contains a static API for creating an instance of that type:

extension ImageLoader where Self == ExternalImageLoader {
    static var external: Self { Self() }
}

extension ImageLoader where Self == AuthenticatedImageLoader {
    static func authenticated(with token: AccessToken) -> Self {
        Self(token: token)
    }
}

With the above in place, we can now easily refer to either .external or .authenticated, depending on what type of image loader that we’re looking to create:

let searchListVC = ItemListViewController(
    dataSource: makeSearchListDataSource(),
    imageLoader: .external
)

let friendsListVC = ItemListViewController(
    dataSource: makeFriendsListDataSource(),
    imageLoader: .authenticated(with: user.accessToken)
)

While the above technique does require a bit more code than when using an enum (or a struct with static APIs), it does let us retain the main benefits of using protocols — such as being able to implement separate functionality using separate types — while still making our call sites much simpler.

Personally, I think that this new language feature will be especially useful when working with protocols that have a somewhat finite set of implementations — such as SwiftUI’s various styling protocols, and the above ImageLoader example.

If you have any questions, comments, or feedback, then feel free to reach out via email.

Thanks for reading!

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For the most part, it’s fair to say that modern iOS and Mac apps are expected to gracefully adapt to whether the user’s device is running in light or dark mode, which often requires us to use more dynamic colors within the UIs that we build.

While Apple does make it fairly straightforward to declare such dynamic colors using Xcode’s asset catalog system, sometimes we might want to define our colors inline within our Swift code instead. So let’s take a look at a few ways to do just that, using either SwiftUI or UIKit.

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Using system colors

Perhaps the simplest way to ensure that our colors adapt to various user preferences is to use the pre-defined colors that ship as part of both UIKit and SwiftUI as much as possible. All of SwiftUI’s built-in colors are adaptive by default, and the same thing is true for all UIColor APIs that are prefixed with system:

// SwiftUI
label.foregroundColor(.orange)

// UIKit
label.textColor = .systemOrange

Although the above labels will always have an orange text color, the exact shade of orange that’s used will vary both depending on whether the user’s device is using dark or light mode, and whether certain accessibility settings have been enabled (such as Increase Contrast).

Both SwiftUI and UIKit also offer a suite of colors that are a bit more abstract, which will then resolve to specific, context-appropriate colors at runtime. For example, when using SwiftUI, the primary and secondary colors are often particularly useful when working with text, as they’ll make our text colors match the ones used throughout the system:

Preview

struct ArticleListItem: View {
    var article: Article
    
    var body: some View {
        VStack(alignment: .leading, spacing: 10) {
            Text(article.title)
                .font(.headline)
                .foregroundColor(.primary)
            Text(article.description)
                .foregroundColor(.secondary)
        }
        .padding()
    }
}

💡 Tip: Use the PREVIEW button to see what the above code sample looks like when rendered using both light and dark mode.

UIKit contains an even more comprehensive set of contextual colors that are a bit more tied to the default colors used for certain system components. So the equivalent of SwiftUI’s primary and secondary colors are referred to as label and secondaryLabel when working with UIColor:

label.textColor = .label
detailLabel.textColor = .secondaryLabel
view.backgroundColor = .systemBackground

For a complete list of colors, check out Apple’s “UI Element Colors” documentation page.

Custom colors

While the system-provided colors are definitely a great starting point, we’ll likely also want to use a few completely custom colors within each project, and we might need to make such colors adapt to the user’s current color scheme as well.

One way to do that is to make our UI code observe whenever the color scheme was changed, and to then update any custom colors that need to be adapted whenever that happens. For example like this when using SwiftUI:

struct ArticleListItem: View {
    var article: Article
    @Environment(\.colorScheme) private var colorScheme
    
    var body: some View {
        VStack(alignment: .leading, spacing: 10) {
            Text(article.title)
                .font(.headline)
                .foregroundColor(titleColor)
            Text(article.description)
                .foregroundColor(.secondary)
        }
        .padding()
    }
    
    private var titleColor: Color {
        switch colorScheme {
case .light:
    return Color(white: 0.2)
case .dark:
    return Color(white: 0.8)
@unknown default:
    return Color(white: 0.2)
}
    }
}

When using UIKit, we can perform the same kind of observation by overriding the traitCollectionDidChange(_:) method within one of our views or view controllers. We can then switch on the passed trait collection’s userInterfaceStyle.

However, while the above technique certainly works, things can quickly get quite messy and repetitive if we need to perform the same kind of observation within many different views. One way to address that when using SwiftUI would be to instead create a reusable view modifier that lets us specify separate foreground colors for light and dark mode, and to then make our modifier observe the current color scheme internally — like this:

struct AdaptiveForegroundColorModifier: ViewModifier {
    var lightModeColor: Color
    var darkModeColor: Color
    
    @Environment(\.colorScheme) private var colorScheme
    
    func body(content: Content) -> some View {
        content.foregroundColor(resolvedColor)
    }
    
    private var resolvedColor: Color {
        switch colorScheme {
        case .light:
            return lightModeColor
        case .dark:
            return darkModeColor
        @unknown default:
            return lightModeColor
        }
    }
}

extension View {
    func foregroundColor(
        light lightModeColor: Color,
        dark darkModeColor: Color
    ) -> some View {
        modifier(AdaptiveForegroundColorModifier(
            lightModeColor: lightModeColor, 
            darkModeColor: darkModeColor
        ))
    }
}

With the above modifier in place, we can now easily specify our adaptive foreground colors inline within our views, without requiring any observations or other complexities at each call site:

struct ArticleListItem: View {
    var article: Article
    
    var body: some View {
        VStack(alignment: .leading, spacing: 10) {
            Text(article.title)
                .font(.headline)
                .foregroundColor(
    light: Color(white: 0.2),
    dark: Color(white: 0.8)
)
            Text(article.description)
                .foregroundColor(.secondary)
        }
        .padding()
    }
}

While the above technique is very useful if we only want to work with colors in a limited set of ways, if we instead wanted to customize all sorts of colors — foreground, background, tinting, shape stroking and filling, and so on — then we might want to come up with a slightly more versatile solution.

For that, we could turn to UIColor instead, which offers a way to initialize a color with a dynamic closure that the system will call whenever the currently active UITraitCollection was changed. That in turn enables us to implement a custom initializer that — just like the pattern that we used above — lets us specify separate light and dark mode colors, which will then be resolved based on the current trait collection’s userInterfaceStyle:

extension UIColor {
    convenience init(
        light lightModeColor: @escaping @autoclosure () -> UIColor,
        dark darkModeColor: @escaping @autoclosure () -> UIColor
     ) {
        self.init { traitCollection in
            switch traitCollection.userInterfaceStyle {
            case .light:
                return lightModeColor()
            case .dark:
                return darkModeColor()
            @unknown default:
                return lightModeColor()
            }
        }
    }
}

A big benefit of the above solution is that it can easily be expanded to take other kinds of traits (such as various accessibility settings) into account, since the UITraitCollection instance that we’re passed contains much more information than just what color scheme that’s used.

What’s really great is that SwiftUI’s Color and UIColor can easily be bridged — meaning that we can also make the above solution fully SwiftUI-compatible with very little extra code:

extension Color {
    init(
        light lightModeColor: @escaping @autoclosure () -> Color,
        dark darkModeColor: @escaping @autoclosure () -> Color
    ) {
        self.init(UIColor(
            light: UIColor(lightModeColor()),
            dark: UIColor(darkModeColor())
        ))
    }
}

Note that, in the iOS 15 SDK, the above Color initializer has been deprecated in favor of a new version called init(uiColor:), which works the exact same way.

With the above in place, we can now create adaptive Color and UIColor instances wherever we’d like, simply by doing this:

struct ArticleListItem: View {
    var article: Article
    
    var body: some View {
        VStack(alignment: .leading, spacing: 10) {
            Text(article.title)
                .font(.headline)
                .foregroundColor(Color(
    light: Color(white: 0.2),
    dark: Color(white: 0.8)
))
            Text(article.description)
                .foregroundColor(.secondary)
        }
        .padding()
    }
}

If we then wanted to take things even further, we could even fully abstract our color definitions from our views by moving them into static properties that act the same way as primary, secondary, and the other dynamic colors that ship as part of the system:

extension Color {
    static var title: Self {
        Self(light: Color(white: 0.2),
             dark: Color(white: 0.8))
    }
}

The above is definitely the architecture that I prefer to use when building apps. By contextualizing each color into properties like title, background, appTint, and so on, I find that it’s much easier to keep an app’s colors consistent and well-organized over time.

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Conclusion

Defining custom colors might initially seem like a simple problem to solve, but as the execution environments that our apps are run in continue to become more and more dynamic, the way we have to make our colors adapt to those different environments will likely continue to increase in complexity.

Hopefully this article has given you some inspiration on how to create such dynamic, adaptive colors, and if you have any questions, comments, or feedback, then feel free to reach out.

Thanks for reading!

When switching on an enum, we are required to either explicitly handle all of its cases, or provide a default case that’ll act as a fallback for cases that weren’t matched by any previous case statement. For example like this:

struct Article {
    enum State {
        case draft
        case published
        case removed
    }

    var state: State
    ...
}

// Explicitly handling all possible cases:

func articleIconColor(forState state: Article.State) -> Color {
    switch state {
    case .draft:
        return .yellow
    case .published:
        return .green
    case .removed:
        return .red
    }
}

// Using a default case:

extension Article {
    var isDraft: Bool {
        switch state {
        case .draft:
            return true
        default:
            return false
        }
    }
}

Fun fact: Instead of a default case, we can also use case _ to match all possible patterns within a switch statement. The two are functionally identical, since _ acts as a “wild card” within Swift’s pattern matching system.

When possible, I always recommend writing exhaustive switch statements that handle each possible case explicitly, even if that involves a bit more code. The reason is that doing so will give us a compiler error if we ever add a new case in the future, which in turn “forces us” to make a proper decision on how to handle that new case across our code base. Default cases might be convenient, but they can quickly become a common source of bugs when an old piece of code ends up dealing with an enum case that it wasn’t designed to handle, simply because it was called from within a default statement.

So here’s how I’d personally implement the above isDraft property:

extension Article {
    var isDraft: Bool {
        switch state {
        case .draft:
            return true
        case .published, .removed:
    return false
}
    }
}

However, when working with certain system-provided enums, we sometimes need to use a default case, since those enums might be updated with new cases at any point. For example, if we tried to exhaustively switch on something like UIKit’s UIUserInterfaceStyle enum, then the compiler would give us a warning:

extension UITraitEnvironment {
    var isUsingDarkMode: Bool {
        // ⚠️ Warning: Switch covers known cases, but
        // 'UIUserInterfaceStyle' may have additional unknown
        // values, possibly added in future versions.
        switch traitCollection.userInterfaceStyle {
        case .dark:
            return true
        case .light, .unspecified:
            return false
        }
    }
}

One way to address the above warning would of course be to use a standard default statement (as that would catch any additional cases that might be added in the future), but then we’re back in that situation where our code might end up doing the wrong thing when handling those new cases.

Thankfully, Swift has a built-in solution to this problem, and that’s the @unknown attribute, which can be attached to either a default or case _ statement in order to handle any cases that are unknown at the time when we’re writing our code, while still producing warnings if we forget to handle an existing case. Here’s how we could apply that attribute to the above isUsingDarkMode implementation:

extension UITraitEnvironment {
    var isUsingDarkMode: Bool {
        switch traitCollection.userInterfaceStyle {
        case .dark:
            return true
        case .light, .unspecified:
            return false
        @unknown default:
    return false
}
    }
}

Note how we need to write our @unknown default case as a separate statement, rather than combining it with another case that results in the same outcome. One way to work around that limitation would be to use the fallthrough keyword, which will cause Swift to automatically move to the next case within our switch statement — like this:

extension UITraitEnvironment {
    var isUsingDarkMode: Bool {
        switch traitCollection.userInterfaceStyle {
        case .dark:
            return true
        case .light, .unspecified:
            fallthrough
        @unknown default:
            return false
        }
    }
}

The above is not really a pattern that I personally use, since I prefer to clearly separate my @unknown default fallback code from the code that deals with known cases, but I still thought that it was worth mentioning that technique.

So how come @unknown default statements are only required (or at least recommended) when switching on certain specific enums? This is where the concept of frozen enums come in. When an enum is marked as frozen, that tells the compiler that it’ll never (or at least should never) gain any new cases, which means that it’s safe for us to exhaustively switch on its cases without needing to handle any unknown ones.

For example, if we take a look at what Foundation’s ComparisonResult enum’s Swift interface looks like, then we can see that it’s marked with the @frozen attribute:

@frozen public enum ComparisonResult: Int {
    case orderedAscending = -1
    case orderedSame = 0
    case orderedDescending = 1
}

That means that we’re free to switch on ComparisonResult values (and others like it) without being warned that we should add an @unknown default case.

So does that mean that we should also add that same @frozen attribute to our own enums as well? Not really, since the compiler will automatically treat all user-defined Swift enums as frozen by default. However, if we’re working with enums that we’ve defined in Objective-C, then we’ll have to explicitly mark them as “closed for extensibility” if we want them to become frozen when imported into Swift:

typedef NS_ENUM(NSInteger, SXSArticleState) {
    SXSArticleStateDraft,
    SXSArticleStatePublished,
    SXSArticleStateRemoved
} __attribute__((enum_extensibility(closed))) NS_SWIFT_NAME(ArticleState);

Alternatively, we could replace NS_ENUM with NS_CLOSED_ENUM to have the above extensibility attribute be automatically applied.

With the above in place, our SXSArticleState type will now be imported into Swift as a frozen enum called ArticleState, and it’ll work exactly like our earlier, Swift-native Article.State enum did.

I hope that this article has given you a few insights into how @unknown default statements work and why they’re sometimes needed. If you have any questions, comments, or feedback, then feel free to reach out.

Thanks for reading!

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