29 Sep 2023
Parameter packs are new in Swift 5.9 and they are pretty cool.
Here’s a few example uses from an initial exploration.
valuesAt
I often want to pluck out specific values from a type but don’t necessarily want to do it over multiple lines e.g. plucking details out of a Github pull request might look like this
let number = pullRequest.number
let user = pullRequest.user.login
let head = pullRequest.head.sha
The above could go on further with many more parameters but the main take away is it creates some repetitive noise and sometimes I just want a one liner.
With parameter packs we can write a valuesAt function to achieve this result
let (number, user, head) = valuesAt(pullRequest, keyPaths: \.number, \.user.login, \.head.sha)
The end result is the same in that I have 3 strongly typed let bindings but I can get it onto one line.
The implementation of valuesAt looks like this:
func valuesAt<T, each U>(
_ subject: T,
keyPaths keyPath: repeat KeyPath<T, each U>
) -> (repeat each U) {
(repeat (subject[keyPath: each keyPath]))
}
decorateAround
With higher order functions in Swift it’s easy to write a function that decorates another.
The issue is handling varying arity and differing return types means we previously had to write loads of function overloads.
With parameter packs we can write a generic function that allows us to write wrappers inline.
Imagine I need to log the arguments and return value for a function but I don’t have access to the source so I can’t just modify the function directly.
What I can do is decorate the function and then use the newly generated function in the original functions place.
let decoratedAddition: (Int, Int) -> Int = decorateAround(+) { add, a, b in
let result = add(a, b)
print("\(a) + \(b) = \(result)")
return result
}
print(decoratedAddition(1, 2))
//=> 1 + 2 = 3
//=> 3
With the above the core underlying function is unchanged but I’ve added additional observability.
With this particular set up the decorateAround actually gives the caller lots of flexibility as they can also optionally inspect/modify the arguments to the wrapped function and then modify the result.
The code to achieve this triggers my semantic satiation for the words repeat and each but here it is in all its glory
func decorateAround<each Argument, Return>(
_ function: @escaping (repeat each Argument) -> Return,
around: @escaping ((repeat each Argument) -> Return, repeat each Argument) -> Return
) -> (repeat each Argument) -> Return {
{ (argument: repeat each Argument) in
around(function, repeat each argument)
}
}
We could go further and create helpers that make it simple to decoratePre and decoratePost and only use the decorateAround variant when we need full flexibility.
memoize
With the general pattern of decoration there are other things we can expand on.
One such function would be to memoize expensive computations so if we call a decorated function with the same inputs multiple times we expect the computation to be performed only once.
One example might be loading a resource from disk and keeping it in a local cache to avoid the disk IO when the same file is requested
let memoizedLoadImage = memoize(loadImage)
memoizedLoadImage(URL(filePath: "some-url"))
memoizedLoadImage(URL(filePath: "some-url"))
memoizedLoadImage(URL(filePath: "other-url"))
In the above example the image at some-url will only have the work performed to load it the first time, on the subsequent call the in memory cached result will be returned.
The final call to other-url will not have any result in the cache and so would trigger a disk load.
In order to build this one we have to get a little more inventive with things as the cache is a Dictionary so we need to build a key somehow but tuples are not Hashable.
I ended up building an array for the key that has all the arguments type erased to AnyHashable.
The code looks like this:
func memoize<each Argument: Hashable, Return>(
_ function: @escaping (repeat each Argument) -> Return
) -> (repeat each Argument) -> Return {
var storage = [AnyHashable: Return]()
return { (argument: repeat each Argument) in
var key = [AnyHashable]()
repeat key.append(AnyHashable(each argument))
if let result = storage[key] {
return result
} else {
let result = function(repeat each argument)
storage[key] = result
return result
}
}
}
Conclusion
Parameter packs are an interesting feature - I’m not sure the above code snippets are particularly good or even sensible to use but I hope it helps people get their toe in the door on using the feature and potentially coming up with stronger use cases than I’ve imagined.
23 Mar 2023
The XCTest framework added the super helpful function XCTUnwrap back in Xcode 11.
At the time I added a similar helper to my various projects to help smooth over the many cases where casting is required.
The idea is to have a similar call site to XCTUnwrap but for use in situations where you want to verify you have the right type or fail.
This commonly happens when we are testing functions that have a return type where some of the type information is erased e.g. when a function returns a protocol or generic super class but we need to assert on a specific implementation.
Another common case is if we are using mocks/doubles via subclassing, in our test we’ll often want to cast to our test type to get more information.
One such example in practice might be to check that a class implements UICollectionViewDataSource in the correct way for your application.
The method that you would want to validate would be UICollectionViewDataSource.collectionView(_:cellForItemAt:) -> UICollectionViewCell.
The issue we have is that the return type is UICollectionViewCell which you’ll often subclass.
A safe test method might look like this:
func testFirstCellHasListing1() throws {
let cell = controller.collectionView(collectionView, cellForItemAt: .init(item: 0, section: 0))
guard let cell = cell as? MyCell else {
XCTFail("Expected cell of type `MyCell` but got \(cell)")
return
}
XCTAssertEqual("Item 1", cell.title)
}
In the above the middle 3 lines are just noise to handle type casting, in isolation it might not seem too bad but across a whole test suite it adds up.
The above code snippet is quite wordy and it’s not uncommon to see repeated tasks performed differently overtime. Someone might come to the code base and opt for a more concise assertion that handles the casting
XCTAssertEqual("Item 1", (cell as! MyCell).title)
This is bad because if the test fails it will crash and unfortunately XCTest doesn’t handle crashes gracefully, instead of treating them as test failures it instead brings the whole test suite to a halt.
It might then be wise to assume making this safer could be a case of updating to one of the following:
XCTAssertEqual("Item 1", (cell as? MyCell)?.title)
XCTAssertEqual("Item 1", try XCTUnwrap(cell as? MyCell).title)
The above lines would certainly resolve the crashing issue but the actual failures don’t really pinpoint the issue.
The errors for the lines above would be something like
... -[Sample.Tests testFirstCellHasListing1] :
XCTAssertEqual failed: ("Optional("Item 1")") is not equal to ("nil")
... -[Sample.Tests testFirstCellHasListing1] :
XCTUnwrap failed: expected non-nil value of type "MyCell"
The first error is comparing an expected value to nil which doesn’t really hint why there is a nil without examining the code.
The second error mentions the type expectation but it’s still not the main focus of the error so we’d need to inspect the code to see where the nil was introduced.
Adding our own helper
If we follow the rough design of XCTUnwrap we could end up with something like this:
extension XCTestCase {
/// Asserts that an input can be cast to the target type and returns the cast result.
/// - Parameters:
/// - input: The value to attempt to cast.
/// - targetType: The desired type to cast to.
/// - message: An optional description of the failure.
/// - file: The file in which failure occurred. Defaults to the file name of the test case in which this function was called.
/// - line: The line number on which failure occurred. Defaults to the line number on which this function was called.
/// - Returns: A value of type `Target`, the result of casting the given `input`.
/// Throws: An error when the `input` cannot be cast to the type of `Target`.
public func XCTCast<Input, Target>(
_ input: Input,
as targetType: Target.Type = Target.self,
_ message: @autoclosure () -> String = "",
file: StaticString = #file,
line: UInt = #line
) throws -> Target {
guard let result = input as? Target else {
let description = "XCTCast failed: expected value of type \"\(targetType)\" but got \"\(type(of: input))\"" + message()
record(
.init(
type: .assertionFailure,
compactDescription: description,
sourceCodeContext: .init(
location: .init(
filePath: file,
lineNumber: line
)
)
)
)
throw CastingError(description: description)
}
return result
}
}
struct CastingError: Error {
let description: String
}
With the above (fairly wordy) helper tucked away in our project our call site becomes:
func testFirstCellHasListing1() throws {
let cell = controller.collectionView(collectionView, cellForItemAt: .init(item: 0, section: 0))
XCTAssertEqual("Item 1", try XCTCast(cell, as: MyCell.self).title)
}
This ends up being fairly concise and similar to our version above that was “safe” but gave a less helpful error
- XCTAssertEqual("Item 1", try XCTUnwrap(cell as? MyCell).title)
+ XCTAssertEqual("Item 1", try XCTCast(cell, as: MyCell.self).title)
The benefits to the new helper are that it better shows our intent when reading the test and the error message gets straight to the heart of the issue
... -[Sample.Tests testFirstCellHasListing1] :
XCTCast failed: expected value of type "MyCell" but got "UICollectionViewCell"
Conclusion
When XCTUnwrap landed it was a real reminder that I’d once again been dealing with daily paper cuts rather than looking at making my tooling better.
The XCTCast in this post was a direct reaction to that and recognising other pain points that could be easily smoothed over.
Even if XCTCast isn’t useful for someone else hopefully this is a good reminder to step back and look at your current pain points and take the time to improve things for future you.
18 Mar 2023
We can use functions in Swift to bundle up behaviour and pass it around our application really easily.
With functions we can sometimes hit specific usability examples, which can be resolved by wrapping our function in a struct.
This post is 100% not a recommendation to wrap every function in a struct, but instead an examination of some cases where it might make sense.
Here’s an example of me wanting to hide a fairly complex interaction and make it more testable.
In this case I want to check if the device has authorised push notifications, to keep things simple I’m not bothered about the specifics of what settings are enabled but rather just whether the system is authorised or not.
I can boil this down to just injecting in a function of () async -> Bool:
World.areNotificationsAuthorized = {
if case .authorized = await UNUserNotificationCenter.current().notificationSettings().authorizationStatus {
return true
} else {
return false
}
}
...
func performAuthorizationFlow(isAuthorized: () async -> Bool = World.areNotificationsAuthorized) {
if (await isAuthorized()) {
...
} else {
...
}
}
With this approach I can test this function by simply overriding the isAuthorized function e.g.
performAuthorizationFlow(isAuthorized: { true })
// or
performAuthorizationFlow(isAuthorized: { false })
Arguably I could try and start doing some deeply nested mocking of types that I don’t own to verify that the code calls current() followed by notificationSettings() and then change the returned UNAuthorizationStatus but that involves a whole other conversation about trade offs and what I care to test.
Problem 1
This example highlights the first problem with this approach.
The function performAuthorizationFlow takes in a function of () async -> Bool, which is pretty general.
There could be many functions in my system that have this shape, which means I could accidentally pass the wrong function.
This problem is not unique to function types and creating whole new types rather than type aliases is a common solution.
To get around this we can define a simple struct that holds onto the function like this:
struct NotificationAuthorizationStatus {
let run: () async -> Bool
}
With this in place we can update our code to
- World.areNotificationsAuthorized = {
+ World.areNotificationsAuthorized = NotificationAuthorizationStatus {
if case .authorized = await UNUserNotificationCenter.current().notificationSettings().authorizationStatus {
return true
} else {
return false
}
}
...
- func performAuthorizationFlow(isAuthorized: () async -> Bool = World.areNotificationsAuthorized) {
+ func performAuthorizationFlow(isAuthorized: NotificationAuthorizationStatus = World.areNotificationsAuthorized) {
- if (await isAuthorized()) {
+ if (await isAuthorized.run()) {
...
} else {
...
}
}
Now we have to pass a concrete type which removes the chance of accidentally passing the wrong function to our method.
Problem 2
With a bare function we don’t really have a nice namespace to work within.
In this example we have the default implementation of this authorization function that calls out to Apple’s framework.
At the moment this code is floating in the breeze being assigned to the World object.
We can take inspiration from Point-Free’s work on protocol witnesses and add some convenience functions on our new namespace
struct NotificationAuthorizationStatus {
let run: () async -> Bool
static let live = NotificationAuthorizationStatus {
if case .authorized = await UNUserNotificationCenter.current().notificationSettings().authorizationStatus {
return true
} else {
return false
}
}
}
With this change our original set up changes like this:
- World.areNotificationsAuthorized = NotificationAuthorizationStatus {
- if case .authorized = await UNUserNotificationCenter.current().notificationSettings().authorizationStatus {
- return true
- } else {
- return false
- }
- }
+ World.areNotificationsAuthorized = .live
In our test target we could even add some convenience functions like this
extension NotificationAuthorizationStatus {
static let alwaysTrue = NotificationAuthorizationStatus { true }
static let alwaysFalse = NotificationAuthorizationStatus { false }
}
Problem 3
For the 3rd problem I’ll need a slightly different example (yes I could have used one example but repetition often helps cement ideas).
This is an issue of usability for the code calling the closure.
Imagine we have the following block:
let completion: (String, String, String) -> Void
At the call site it would be pretty unclear what each of these arguments should be e.g. completion(?, ?, ?) and we’d have to trace back through our code to find out.
We can improve this situation slightly by adding some documentation to the defintion so that we only need to navigate back through the code so far:
let completion: (_ email: String, _ forename: String, _ surname: String) -> Void
If we convert this to be wrapped by a struct we can see some options to improve this
struct UserCompletion {
private let completion: (_ email: String, _ forename: String, _ surname: String) -> Void
init(completion: @escaping (_ email: String, _ forename: String, _ surname: String) -> Void) {
self.completion = completion
}
func invoke(email: String, forename: String, surname: String) {
completion(email, forename, surname)
}
}
With the above our call site changes from the confusing invocation with no argument labels to a normal function call with argument labels (I didn’t even think of this benefit until my friend Ellen pointed it out)
It’s not strongly typed and we can still pass the wrong values in each argument position but at least the labels give some guidance.
There’s another enhancement that we can take advantage of here as the extra .invoke is a bit annoying.
Instead if we change the name of our method invoke to callAsFunction then this makes our struct directly invokable:
Conclusion
Swift is really expressive and has a lot of features to help organise code and make things stricter.
In this post we was able to make it more difficult to pass the wrong function around, gave ourselves a namespace to place code in and made our call sites a little safer.
I won’t be going off on a code rewriting spree but it’s definitely useful to have another option in my bag of tricks.