By default, encoding or decoding an array using Swift’s built-in Codable API is an all-or-nothing type of deal. Either all elements will be successfully handled, or an error will be thrown, which is arguably a good default, since it ensures a high level of data consistency.

However, sometimes we might want to tweak that behavior so that invalid elements will be ignored, rather than resulting in our entire coding process failing. For example, let’s say that we’re working with a JSON-based web API that returns collections of items that we’re currently modeling in Swift like this:

struct Item: Codable {
    var name: String
    var value: Int
}

extension Item {
    struct Collection: Codable {
        var items: [Item]
    }
}

Now let’s say that the web API that we’re working with occasionally returns responses such as the following, which includes a null value where our Swift code is excepting an Int:

{
    "items": [
        {
            "name": "One",
            "value": 1
        },
        {
            "name": "Two",
            "value": 2
        },
        {
            "name": "Three",
            "value": null
        }
    ]
}

If we try to decode the above response into an instance of our Item.Collection model, then the entire decoding process will fail, even if the majority of our items did contain perfectly valid data.

The above might seem like a somewhat contrived example, but it’s incredibly common to encounter malformed or inconsistent JSON formats in the wild, and we might not always be able to adjust those formats to neatly fit Swift’s very static nature.

Of course, one potential solution would be to simply make our value property optional (Int?), but doing so could introduce all sorts of complexities across our code base, since we’d now have to unwrap those values every time that we wish to use them as concrete, non-optional Int values.

Another way to solve our problem could be to define default values for the properties that we’re expecting to potentially be null, missing, or invalid — which would be a fine solution in situations when we still want to keep any elements that contained invalid data, but let’s say that this is not one of those situations.

So, instead, let’s take a look at how we could ignore all invalid elements when decoding any Decodable array, without having to make any major modifications to how our data is structured within our Swift types.

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Building a lossy codable list type

What we’re essentially looking to do is to change our decoding process from being very strict to instead becoming “lossy”. To get started, let’s introduce a generic LossyCodableList type which will act as a thin wrapper around an array of Element values:

struct LossyCodableList<Element> {
    var elements: [Element]
}

Note how we didn’t immediately make our new type conform to Codable, and that’s because we’d like it to conditionally support either Decodable, Encodable, or both, depending on what Element type that it’s being used with. After all, not all types will be codable both ways, and by declaring our Codable conformances separately we’ll make our new LossyCodableList type as flexible as possible.

Let’s start with Decodable, which we’ll conform to by using an intermediate ElementWrapper type to decode each element in an optional manner. We’ll then use compactMap to discard all nil elements, which will give us our final array — like this:

extension LossyCodableList: Decodable where Element: Decodable {
    private struct ElementWrapper: Decodable {
        var element: Element?

        init(from decoder: Decoder) throws {
            let container = try decoder.singleValueContainer()
            element = try? container.decode(Element.self)
        }
    }

    init(from decoder: Decoder) throws {
        let container = try decoder.singleValueContainer()
        let wrappers = try container.decode([ElementWrapper].self)
        elements = wrappers.compactMap(\.element)
    }
}

To learn more about the above way of conforming to protocols, check out “Conditional conformances in Swift”.

Next, Encodable, which might not be something that every project needs, but it could still come in handy in case we also want to give our encoding process the same lossy behavior:

extension LossyCodableList: Encodable where Element: Encodable {
    func encode(to encoder: Encoder) throws {
        var container = encoder.unkeyedContainer()

        for element in elements {
            try? container.encode(element)
        }
    }
}

With the above in place, we’ll now be able to automatically discard all invalid Item values simply by making our nested Collection type use our new LossyCodableList — like this:

extension Item {
    struct Collection: Codable {
        var items: LossyCodableList<Item>
    }
}

Making our list type transparent

One quite major downside with the above approach, however, is that we now always have to use items.elements to access our actual item values, which isn’t ideal. It would arguably be much better if we could turn our usage of LossyCodableList into a completely transparent implementation detail, so that we could keep accessing our items property as a simple array of values.

One way to make that happen would be to store our item collection’s LossyCodableList as a private property, and to then use a CodingKeys type to point to that property when encoding or decoding. We could then implement items as a computed property, for example like this:

extension Item {
    struct Collection: Codable {
        enum CodingKeys: String, CodingKey {
            case _items = "items"
        }

        var items: [Item] {
            get { _items.elements }
            set { _items.elements = newValue } 
        }
        
        private var _items: LossyCodableList<Item>
    }
}

Another option would be to give our Collection type a completely custom Decodable implementation, which would involve decoding each JSON array using LossyCodableList before assigning the resulting elements to our items property:

extension Item {
    struct Collection: Codable {
        enum CodingKeys: String, CodingKey {
            case items
        }

        var items: [Item]

        init(from decoder: Decoder) throws {
            let container = try decoder.container(keyedBy: CodingKeys.self)
            let collection = try container.decode(
                LossyCodableList<Item>.self,
                forKey: .items
            )
            
            items = collection.elements
        }
    }
}

Both of the above approaches are perfectly fine solutions, but let’s see if we could make things even nicer by using Swift’s property wrappers feature.

Both a type and a property wrapper

One really neat thing about the way that property wrappers are implemented in Swift is that they’re all just standard Swift types, which means that we can retrofit our LossyCodableList to also be able to act as a property wrapper.

All that we have to do to make that happen is to mark it with the @propertyWrapper attribute, and to implement the required wrappedValue property (which once again could be done as a computed property):

@propertyWrapper
struct LossyCodableList<Element> {
    var elements: [Element]

    var wrappedValue: [Element] {
    get { elements }
    set { elements = newValue }
}
}

With the above in place, we’ll now be able to mark any Array-based property with the @LossyCodableList attribute, and it’ll be lossily encoded and decoded — comparably transparently:

extension Item {
    struct Collection: Codable {
        @LossyCodableList var items: [Item]
    }
}

Of course, we’ll still be able to keep using LossyCodableList as a stand-alone type, just like we did before. All that we’ve done by turning it into a property wrapper is to also enable it to be used that way, which once again gives us a lot of added flexibility without any real cost.

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Conclusion

At first glance, Codable might seem like an incredibly strict and somewhat limited API that either succeeds or fails, without any room for nuance or customization. However, once we get past the surface level, Codable is actually incredibly powerful, and can be customized in lots of different ways.

Silently ignoring invalid elements is definitely not always the right approach — very often we do want our coding processes to fail whenever any invalid data was encountered — but when that’s not the case, then either of the techniques used in this article can provide a great way to make our coding code more flexible and lossy without introducing a ton of additional complexity.

If you’ve got any questions, comments, or feedback, then feel free to reach out via either Twitter or email. If you want to, you can also support my work by either checking out the above sponsor, or by sharing this article to help more people discover it.

Thanks for reading!

Testing asynchronous code is often particularly tricky, and code written using Apple’s Combine framework is no exception. Since each XCTest-based unit test executes in a purely synchronous fashion, we have to find ways to tell the test runner to await the output of the various asynchronous calls that we’re looking to test — otherwise their output won’t be available until after our tests have already finished executing.

So, in this article, let’s take a look at how to do just that when it comes to code that’s based on Combine publishers, and also how we can augment Combine’s built-in API with a few utilities that’ll heavily improve its testing ergonomics.

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Awaiting expectations

As an example, let’s say that we’ve been working on a Tokenizer that can be used to identify various tokens within a string (such as usernames, URLs, hashtags, and so on). Since we’re looking to tokenize strings of varying length and complexity, we’ve opted to make our Tokenizer perform its work on a background thread, and to then use Combine to asynchronously report what tokens that it found within a given String:

struct Tokenizer {
    func tokenize(_ string: String) -> AnyPublisher<[Token], Error> {
        ...
    }
}

Now let’s say that we wanted to write a series of tests to verify that our tokenization logic works as indented, and since the above API is asynchronous, we’re going to have to do a little bit of work to ensure that those tests will execute predictably.

Like we took a look at in “Unit testing asynchronous Swift code”, XCTest’s expectations system enables us to tell the test runner to await the result of an asynchronous call by creating, awaiting and fulfilling an XCTestExpectation instance. So let’s use that system, along with Combine’s sink operator, to write our first test like this:

class TokenizerTests: XCTestCase {
    private var cancellables: Set<AnyCancellable>!

    override func setUp() {
        super.setUp()
        cancellables = []
    }

    func testIdentifyingUsernames() {
        let tokenizer = Tokenizer()
    
        // Declaring local variables that we'll be able to write
        // our output to, as well as an expectation that we'll
        // use to await our asynchronous result:
        var tokens = [Token]()
        var error: Error?
        let expectation = self.expectation(description: "Tokenization")

        // Setting up our Combine pipeline:
        tokenizer
            .tokenize("Hello @john")
            .sink(receiveCompletion: { completion in
                switch completion {
                case .finished:
                    break
                case .failure(let encounteredError):
                    error = encounteredError
                }

                // Fullfilling our expectation to unblock
                // our test execution:
                expectation.fulfill()
            }, receiveValue: { value in
                tokens = value
            })
            .store(in: &cancellables)

        // Awaiting fulfilment of our expecation before
        // performing our asserts:
        waitForExpectations(timeout: 10)

        // Asserting that our Combine pipeline yielded the
        // correct output:
        XCTAssertNil(error)
        XCTAssertEqual(tokens, [.text("Hello "), .username("john")])
    }
}

While the above test works perfectly fine, it’s arguably not that pleasant to read, and it involves a lot of boilerplate code that we’ll likely have to repeat within every single Tokenizer test that we’ll write.

A dedicated method for awaiting the output of a publisher

So let’s address those issues by introducing a variant of the await method from “Async/await in Swift unit tests”, which essentially moves all of the setup code required to observe and await the result of a publisher into a dedicated XCTestCase method:

extension XCTestCase {
    func await<T: Publisher>(
        _ publisher: T,
        timeout: TimeInterval = 10,
        file: StaticString = #file,
        line: UInt = #line
    ) throws -> T.Output {
        // This time, we use Swift's Result type to keep track
        // of the result of our Combine pipeline:
        var result: Result<T.Output, Error>?
        let expectation = self.expectation(description: "Awaiting publisher")

        let cancellable = publisher.sink(
            receiveCompletion: { completion in
                switch completion {
                case .failure(let error):
                    result = .failure(error)
                case .finished:
                    break
                }

                expectation.fulfill()
            },
            receiveValue: { value in
                result = .success(value)
            }
        )

        // Just like before, we await the expectation that we
        // created at the top of our test, and once done, we
        // also cancel our cancellable to avoid getting any
        // unused variable warnings:
        waitForExpectations(timeout: timeout)
        cancellable.cancel()

        // Here we pass the original file and line number that
        // our utility was called at, to tell XCTest to report
        // any encountered errors at that original call site:
        let unwrappedResult = try XCTUnwrap(
            result,
            "Awaited publisher did not produce any output",
            file: file,
            line: line
        )

        return try unwrappedResult.get()
    }
}

To learn more about the XCTUnwrap function used above, check out “Avoiding force unwrapping in Swift unit tests”.

With the above in place, we’ll now be able to drastically simplify our original test, which can now be implemented using just a few lines of code:

class TokenizerTests: XCTestCase {
    func testIdentifyingUsernames() throws {
        let tokenizer = Tokenizer()
        let tokens = try await(tokenizer.tokenize("Hello @john"))
        XCTAssertEqual(tokens, [.text("Hello "), .username("john")])
    }
}

Much better! However, one thing that we have to keep in mind is that our new await method assumes that each publisher passed into it will eventually complete, and it also only captures the latest value that the publisher emitted. So while it’s incredibly useful for publishers that adhere to the classic request/response model, we might need a slightly different set of tools to test publishers that continuously emit new values.

Testing published properties

A very common example of publishers that never complete and that keep emitting new values are published properties. For example, let’s say that we’ve now wrapped our Tokenizer into an ObservableObject that can be used within our UI code, which might look something like this:

class EditorViewModel: ObservableObject {
    @Published private(set) var tokens = [Token]()
    @Published var string = ""

    private let tokenizer = Tokenizer()

    init() {
        // Every time that a new string is assigned, we pass
        // that new value to our tokenizer, and we then assign
        // the result of that operation to our 'tokens' property:
        $string
            .flatMap(tokenizer.tokenize)
            .replaceError(with: [])
            .assign(to: &$tokens)
    }
}

Note how we currently replace all errors with an empty array of tokens, in order to be able to assign our publisher directly to our tokens property. Alternatively, we could’ve used an operator like catch to perform more custom error handling, or to propagate any encountered error to the UI.

Now let’s say that we’d like to write a test that ensures that our new EditorViewModel keeps publishing new [Token] values as its string property is modified, which means that we’re no longer just interested in a single output value, but rather multiple ones.

An initial idea on how to handle that, while still being able to use our await method from before, might be to use Combine’s collect operator to emit a single array containing all of the values that our view model’s tokens property will publish, and to then perform a series of verifications on that array — like this:

class EditorViewModelTests: XCTestCase {
    func testTokenizingMultipleStrings() throws {
        let viewModel = EditorViewModel()
        
        // Here we collect the first two [Token] values that
        // our published property emitted:
        let tokenPublisher = viewModel.$tokens
            .collect(2)
            .first()
    
        // Triggering our underlying Combine pipeline by assigning
        // new strings to our view model:
        viewModel.string = "Hello @john"
        viewModel.string = "Check out #swift"

        // Once again we wait for our publisher to complete before
        // performing assertions on its output:
        let tokenArrays = try await(tokenPublisher)
        XCTAssertEqual(tokenArrays.count, 2)
        XCTAssertEqual(tokenArrays.first, [.text("Hello "), .username("john")])
        XCTAssertEqual(tokenArrays.last, [.text("Check out "), .hashtag("swift")])
    }
}

However, the above test currently fails, since the first element within our tokenArrays output value will be an empty array. That’s because all @Published-marked properties always emit their current value when a subscriber is attached to them, meaning that the above tokenPublisher will always receive our tokens property’s initial value (an empty array) as its first input value.

Thankfully, that problem is quite easily fixed, since Combine ships with a dedicated operator that lets us ignore the first output element that a given publisher will produce — dropFirst. So if we simply insert that operator as the first step within our local publisher’s pipeline, then our test will now successfully pass:

class EditorViewModelTests: XCTestCase {
    func testTokenizingMultipleStrings() throws {
        let viewModel = EditorViewModel()
        let tokenPublisher = viewModel.$tokens
            .dropFirst()
            .collect(2)
            .first()

        viewModel.string = "Hello @john"
        viewModel.string = "Check out #swift"

        let tokenArrays = try await(tokenPublisher)
        XCTAssertEqual(tokenArrays.count, 2)
        XCTAssertEqual(tokenArrays.first, [.text("Hello "), .username("john")])
        XCTAssertEqual(tokenArrays.last, [.text("Check out "), .hashtag("swift")])
    }
}

However, we’re once again at a point where it would be quite tedious (and error prone) to have to write the above set of operators for each published property that we’re looking to write tests against — so let’s write another utility that’ll do that work for us. This time, we’ll extend the Published type’s nested Publisher directly, since we’re only looking to perform this particular operation when testing published properties:

extension Published.Publisher {
    func collectNext(_ count: Int) -> AnyPublisher<[Output], Never> {
        self.dropFirst()
            .collect(count)
            .first()
            .eraseToAnyPublisher()
    }
}

With the above in place, we’ll now be able to easily collect the N number of next values that a given published property will emit within any of our unit tests:

class EditorViewModelTests: XCTestCase {
    func testTokenizingMultipleStrings() throws {
        let viewModel = EditorViewModel()
        let tokenPublisher = viewModel.$tokens.collectNext(2)
        ...
    }
}

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Conclusion

Even though Combine’s stream-driven design might differ quite a bit from other kinds of asynchronous code that we might be used to (such as using completion handler closures, or something like Futures and Promises), we can still use XCTest’s asynchronous testing tools when verifying our Combine-based logic as well. Hopefully this article has given you a few ideas on how to do just that, and how we can make writing such tests much simpler by introducing a few lightweight utilities.

If you’ve got questions, comments, or feedback, then feel free to reach out via either Twitter or email. Thanks for reading, and happy testing!

Memory management is often especially tricky when dealing with asynchronous operations, as those tend to require us to keep certain objects in memory beyond the scope in which they were defined, while still making sure that those objects eventually get deallocated in a predictable way.

Although Apple’s Combine framework can make it somewhat simpler to manage such long-living references — as it encourages us to model our asynchronous code as pipelines, rather than a series of nested closures — there are still a number of potential memory management pitfalls that we have to constantly look out for.

In this article, let’s take a look at how some of those pitfalls can be avoided, specifically when it comes to self and Cancellable references.

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A cancellable manages the lifetime of a subscription

Combine’s Cancellable protocol (which we typically interact with through its type-erased AnyCancellable wrapper) lets us control how long a given subscription should stay alive and active. Like its name implies, as soon as a cancellable is deallocated (or manually cancelled), the subscription that it’s tied to is automatically invalidated — which is why almost all of Combine’s subscription APIs (like sink) return an AnyCancellable when called.

For example, the following Clock type holds a strong reference to the AnyCancellable instance that it gets back from calling sink on a Timer publisher, which keeps that subscription active for as long as its Clock instance remains in memory — unless the cancellable is manually removed by setting its property to nil:

class Clock: ObservableObject {
    @Published private(set) var time = Date().timeIntervalSince1970
    private var cancellable: AnyCancellable?

    func start() {
        cancellable = Timer.publish(
            every: 1,
            on: .main,
            in: .default
        )
        .autoconnect()
        .sink { date in
            self.time = date.timeIntervalSince1970
        }
    }

    func stop() {
        cancellable = nil
    }
}

However, while the above implementation perfectly manages its AnyCancellable instance and the Timer subscription that it represents, it does have quite a major flaw in terms of memory management. Since we’re capturing self strongly within our sink closure, and since our cancellable (which is, in turn, owned by self) will keep that subscription alive for as long as it remains in memory, we’ll end up with a retain cycle — or in other words, a memory leak.

Avoiding self-related memory leaks

An initial idea on how to fix that problem might be to instead use Combine’s assign operator (along with a quick Data-to-TimeInterval transformation using map) to be able to assign the result of our pipeline directly to our clock’s time property — like this:

class Clock: ObservableObject {
    ...

    func start() {
        cancellable = Timer.publish(
            every: 1,
            on: .main,
            in: .default
        )
        .autoconnect()
        .map(\.timeIntervalSince1970)
.assign(to: \.time, on: self)
    }

    ...
}

However, the above approach will still cause self to be retained, as the assign operator keeps a strong reference to each object that’s passed to it. Instead, with our current setup, we’ll have to resort to a good old fashioned “weak self dance” in order to capture a weak reference to our enclosing Clock instance, which will break our retain cycle:

class Clock: ObservableObject {
    ...

    func start() {
        cancellable = Timer.publish(
            every: 1,
            on: .main,
            in: .default
        )
        .autoconnect()
        .map(\.timeIntervalSince1970)
        .sink { [weak self] time in
    self?.time = time
}
    }

    ...
}

With the above in place, each Clock instance can now be deallocated once it’s no longer referenced by any other object, which in turn will cause our AnyCancellable to be deallocated as well, and our Combine pipeline will be properly dissolved. Great!

Assigning output values directly to a Published property

Another option that can be great to keep in mind is that (as of iOS 14 and macOS Big Sur) we can also connect a Combine pipeline directly to a published property. However, while doing so can be incredibly convenient in a number of different situations, that approach doesn’t give us an AnyCancellable back — meaning that we won’t have any means to cancel such a subscription.

In the case of our Clock type, we might still be able to use that approach — if we’re fine with removing our start and stop methods, and instead automatically start each clock upon initialization, since otherwise we might end up with duplicate subscriptions. If those are tradeoffs that we’re willing to accept, then we could change our implementation into this:

class Clock: ObservableObject {
    @Published private(set) var time = Date().timeIntervalSince1970

    init() {
        Timer.publish(
            every: 1,
            on: .main,
            in: .default
        )
        .autoconnect()
        .map(\.timeIntervalSince1970)
        .assign(to: &$time)
    }
}

When calling the above flavor of assign, we’re passing a direct reference to our Published property’s projected value, prefixed with an ampersand to make that value mutable (since assign uses the inout keyword). To learn more about that pattern, check out the Basics article about value and reference types.

The beauty of the above approach is that Combine will now automatically manage our subscription based on the lifetime of our time property — meaning that we’re still avoiding any reference cycles while also significantly reducing the amount of bookkeeping code that we have to write ourselves. So for pipelines that are only configured once, and are directly tied to a Published property, using the above overload of the assign operator can often be a great choice.

Weak property assignments

Next, let’s take a look at a slightly more complex example, in which we’ve implemented a ModelLoader that lets us load and decode a Decodable model from a given URL. By using a single cancellable property, our loader can automatically cancel any previous data loading pipeline when a new one is triggered — as any previously assigned AnyCancellable instance will be deallocated when that property’s value is replaced.

Here’s what that ModelLoader type currently looks like:

class ModelLoader<Model: Decodable>: ObservableObject {
    enum State {
        case idle
        case loading
        case loaded(Model)
        case failed(Error)
    }

    @Published private(set) var state = State.idle

    private let url: URL
    private let session: URLSession
    private let decoder: JSONDecoder
    private var cancellable: AnyCancellable?

    ...

    func load() {
        state = .loading

        cancellable = session
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Model.self, decoder: decoder)
            .map(State.loaded)
            .catch { error in
                Just(.failed(error))
            }
            .receive(on: DispatchQueue.main)
            .sink { [weak self] state in
    self?.state = state
}
    }
}

While that automatic cancellation of old requests prevents us from simply connecting the output of our data loading pipeline to our Published property, if we wanted to avoid having to manually capture a weak reference to self every time that we use the above pattern (that is, loading a value and assigning it to a property), we could introduce the following Publisher extension — which adds a weak-capturing version of the standard assign operator that we took a look at earlier:

extension Publisher where Failure == Never {
    func weakAssign<T: AnyObject>(
        to keyPath: ReferenceWritableKeyPath<T, Output>,
        on object: T
    ) -> AnyCancellable {
        sink { [weak object] value in
            object?[keyPath: keyPath] = value
        }
    }
}

With the above in place, we can now simply call weakAssign whenever we want to assign the output of a given publisher to a property of an object that’s captured using a weak reference — like this:

class ModelLoader<Model: Decodable>: ObservableObject {
    ...

    func load() {
        state = .loading

        cancellable = session
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Model.self, decoder: decoder)
            .map(State.loaded)
            .catch { error in
                Just(.failed(error))
            }
            .receive(on: DispatchQueue.main)
            .weakAssign(to: \.state, on: self)
    }
}

Is that new weakAssign method purely syntactic sugar? Yes. But is it nicer than what we were using before? Also yes 🙂

Capturing stored objects, rather than self

Another type of situation that’s quite commonly encountered when working with Combine is when we need to access a specific property within one of our operators, for example in order to perform a nested asynchronous call.

To illustrate, let’s say that we wanted to extend our ModelLoader by using a Database to automatically store each model that was loaded — an operation that also wraps those model instances using a generic Stored type (for example in order to add local metadata, such as an ID or model version). To be able to access that database instance within an operator like flatMap, we could once again capture a weak reference to self — like this:

class ModelLoader<Model: Decodable>: ObservableObject {
    enum State {
        case idle
        case loading
        case loaded(Stored<Model>)
        case failed(Error)
    }

    ...
    private let database: Database
    ...

    func load() {
        state = .loading

        cancellable = session
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Model.self, decoder: decoder)
            .flatMap {
    [weak self] model -> AnyPublisher<Stored<Model>, Error> in
    
    guard let database = self?.database else {
        return Empty(completeImmediately: true)
            .eraseToAnyPublisher()
    }
    
    return database.store(model)
}
            .map(State.loaded)
            .catch { error in
                Just(.failed(error))
            }
            .receive(on: DispatchQueue.main)
            .weakAssign(to: \.state, on: self)
    }
}

The reason we use the flatMap operator above is because our database is also asynchronous, and returns another publisher that represents the current saving operation.

However, like the above example shows, it can sometimes be tricky to come up with a reasonable default value to return from an unwrapping guard statement placed within an operator like map or flatMap. Above we use Empty, which works, but it does add a substantial amount of extra verbosity to our otherwise quite elegant pipeline.

Thankfully, that problem is quite easy to fix (at least in this case). All that we have to do is to capture our database property directly, rather than capturing self. That way, we don’t have to deal with any optionals, and can now simply call our database’s store method within our flatMap closure — like this:

class ModelLoader<Model: Decodable>: ObservableObject {
    ...

    func load() {
        state = .loading

        cancellable = session
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Model.self, decoder: decoder)
            .flatMap { [database] model in
    database.store(model)
}
            .map(State.loaded)
            .catch { error in
                Just(.failed(error))
            }
            .receive(on: DispatchQueue.main)
            .weakAssign(to: \.state, on: self)
    }
}

As an added bonus, we could even pass the Database method that we’re looking to call directly into flatMap in this case — since its signature perfectly matches the closure that flatMap expects within this context (and thanks to the fact that Swift supports first class functions):

class ModelLoader<Model: Decodable>: ObservableObject {
    ...

    func load() {
        state = .loading

        cancellable = session
            .dataTaskPublisher(for: url)
            .map(\.data)
            .decode(type: Model.self, decoder: decoder)
            .flatMap(database.store)
            .map(State.loaded)
            .catch { error in
                Just(.failed(error))
            }
            .receive(on: DispatchQueue.main)
            .weakAssign(to: \.state, on: self)
    }
}

So, when possible, it’s typically a good idea to avoid capturing self within our Combine operators, and to instead call other objects that can be stored and directly passed into our various operators as properties.

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Conclusion

While Combine offers many APIs and features that can help us make our asynchronous code easier to write and maintain, it still requires us to be careful when it comes to how we manage our references and their underlying memory. Capturing a strong reference to self in the wrong place can still often lead to a retain cycle, and if a Cancellable is not properly deallocated, then a subscription might stay active for longer than expected.

Hopefully this article has given you a few new tips and techniques that you can use to prevent memory-related issues when working with self and Cancellable references within your Combine-based projects, and if you have any questions, comments, or feedback, then feel free to reach out via either Twitter or email.

Thanks for reading!