The easiest Future and Promises framework in Swift. No magic. No boilerplate.
While starting from the Objective-C implementation of JustPromises and keeping the code minimalistic, this library adds the following:
- conversion to Swift 4
- usage of generics to allow great type inference that wasn't possible in Objective-C
- overall refactoring for fresh and modern code
- remove the unnecessary and misleading concept of Progress causing bad patterns to emerge
You can read about the theory behind Future and Promises on Wikipedia, here are the main things you should know to get started.
- Promises represent the promise that a task will be fulfilled in the future while the future holds the state of such resolution.
- Futures, when created are in the unresolved state and can be resolved with one of 3 states: with a result, an error, or being cancelled.
- Futures can be chained, allowing to avoid the pyramid of doom problem, clean up asynchronous code paths and simplify error handling.
Promis brags about being/having:
- Fully unit-tested and documented π―
- Thread-safe π¦
- Clean interface πΌ
- Support for chaining β
- Support for cancellation π ββοΈ
- Queue-based block execution if needed π
- Result type provided via generics π
- Keeping the magic to the minimum, leaving the code in a readable state without going off of a tangent with fancy and unnecessary design decisions ΰ² _ΰ²
Other open-source solutions exist such as:
Promis takes inspiration from the Objective-C version of JustPromises developed by the iOS Team of Just Eat which is really concise and minimalistic, while other libraries are more weighty.
The following example should outline the main benefits of using futures via chaining.
let request = URLRequest(url: URL(string: "http://example.com")!)
// starts by hitting an API to download data
getData(request: request).thenWithResult { data in
// continue by parsing the retrieved data
parse(data: data)
}.thenWithResult { parsedData in
// continue by mapping the parsed data
map(data: parsedData)
}.onError { error in
// executed only in case an error occurred in the chain
print("error: " + String(describing: error))
}.finally(queue: .main) { future in
// always executed, no matter the state of the previous future or how the chain did perform
switch future.state {
case .result(let value):
print(String(describing: value))
case .error(let err):
print(String(describing: err))
case .cancelled:
print("future is in a cancelled state")
case .unresolved:
print("this really cannot be if any chaining block is executed")
}
}
The functions used in the example have the following signatures:
func getData(request: URLRequest) -> Future<Data>
func parse(data: Data) -> Future<[Dictionary<String,AnyObject>]>
func map(data: [Dictionary<String,AnyObject>]) -> Future<[FooBar]>
Promises and Futures are parametrized leveraging the power of the generics, meaning that Swift can infer the type of the result compile type. This was a considerable limitation in the Objective-C world and we can now prevent lots of issues at build time thanks to the static typing nature of the language. The state of the future is an enum defined as follows:
enum FutureState<ResultType> {
case unresolved
case result(ResultType)
case error(Error)
case cancelled
}
Promises are created and resolved like so:
let promise = Promise<ResultType>()
promise.setResult(value)
// or
promise.setError(error)
// or
promise.cancel()
Continuation methods used for chaining are the following:
func then<NextResultType>(queue: DispatchQueue? = nil, task: @escaping (Future) -> Future<NextResultType>) -> Future<NextResultType>
func thenWithResult<NextResultType>(queue: DispatchQueue? = nil, continuation: @escaping (ResultType) -> Future<NextResultType>) -> Future<NextResultType> {
func onError(queue: DispatchQueue? = nil, continuation: @escaping (Error) -> Void) -> Future {
func finally(queue: DispatchQueue? = nil, block: @escaping (Future<ResultType>) -> Void)
All the functions can accept an optional DispatchQueue
used to perform the continuation blocks.
Functions wrapping async tasks should follow the below pattern:
func wrappedAsyncTask() -> Future<ResultType> {
let promise = Promise<Data>()
someAsyncOperation() { data, error in
// resolve the promise according to how the async operations did go
switch (data, error) {
case (let data?, _):
promise.setResult(data)
case (nil, let error?):
promise.setError(error)
// etc.
}
}
return promise.future
}
You could chain an onError
continuation before returning the future to allow in-line error handling, which I find to be a very handy pattern.
// ...
return promise.future.onError {error in
// handle/log error
}
When using then
or thenWithResult
, the following should be taken in consideration.
...}.thenWithResult { data -> Future<NextResultType> in
/**
If a block is not trivial, Swift cannot infer the type of the closure and gives the error
'Unable to infer complex closure return type; add explicit type to disambiguate'
so you'll have to add `-> Future<NextResultType> to the block signature
You can make the closure complex just by adding any extra statement (like a print).
All the more reason to structure your code as done in the first given example :)
*/
print("complex closure")
return parse(data: data)
}
Please check the GettingStarted playground in the demo app to see the complete implementation of the above examples.
Add Promis
to your Podfile
use_frameworks!
target 'MyTarget' do
pod 'Promis', '~> x.y.z'
end
$ pod install
github "albertodebortoli/Promis" ~> "x.y.z"
Then on your application target Build Phases settings tab, add a "New Run Script Phase". Create a Run Script with the following content:
/usr/local/bin/carthage copy-frameworks
and add the following paths under "Input Files":
$(SRCROOT)/Carthage/Build/iOS/Promis.framework
Alberto De Bortoli [email protected] Twitter: @albertodebo GitHub: albertodebortoli website: albertodebortoli.com
Promis is available under the Apache 2 license in respect of JustPromises which this library takes inspiration from. See the LICENSE file for more info.