I've got an otherwise fairly standard SPA built on Angular 4 interfacing with a REST API.
Whenever the app performs a write operation to the API (put/post/delete), I want to abort all read operations (get).
I know I can achieve this via the takeUntil operator.
const write$ = new Subject<Date>();
public get(): Observable<Response> {
return http.get().takeUntil(write$);
}
public update(): Observable<Response> {
write$.next(new Date());
return http.post();
}
What I want to do (and I'm struggling with) is expanding on this so that:
- Aborted read operations are re-executed once there are no active write operations.
- Read operations submitted while a write operation is in progress are buffered (caused to wait) until there are no active write operations.
The use case I think is pretty common. Whenever the user modifies an entity, I update that entity's state immediately (as opposed to waiting for the write operation to complete). This makes the UI feel more responsive. Read operations that are in-flight prior to the write, or that start after the write but complete before the write completes, result in the UI flipping the entity back to it's old state.
It is important that the mechanism for aborting/buffering/waiting on read operations be lossless.
***** UPDATE *****
I've come up with something that appears to be working, but it feels more complicated than I would like. In addition to alternative solutions to the originally proposed problem, I would be interested in feedback on the following:
class ApiService {
private asyncDelay = 25;
private wait$ = new BehaviorSubject<Observable<Date>>(new BehaviorSubject<Date>(new Date()));
private read$ = new Subject<Observable<Response>>();
private buffer$ = new ReplaySubject<Observable<Response>>(1);
constructor() {
const flush$ = new Subject<any>();
this.read$.bufferToggle(this.wait$, () => flush$)
.do(x => console.warn('FLUSH: ' + x.length))
.switchMap(items => Observable.from(items))
.subscribe(this.buffer$);
this.wait$.switchMap(resume$ => {
console.warn('WAIT')
return resume$.switchMap(() => {
console.warn('RESUMED')
flush$.next(new Date());
return Observable.merge(this.buffer$, this.read$)
.mergeAll();
});
})
.subscribe();
}
protected get(url: string, options?: RequestOptionsArgs): Observable<Response> {
const abort$ = this.wait$
.skip(1)
.take(1)
.publishReplay(1)
.do(() => console.warn('ABORT'));
const source$ = this.http.get(url, options)
.takeUntil(abort$)
.publishReplay(1);
const retry$ = abort$.switchMap(() => Observable.timer(this.asyncDelay)
.switchMap(() => this.get(url, options)))
.takeUntil(source$)
.publishReplay(1);
this.read$.next(new Observable((observer: Observer<Response>) => {
source$.catch(err => Observable.of(err))
.subscribe(observer);
source$.connect();
}));
return Observable.race(source$, retry$)
.take(1);
}
protected put(url: string, body: any, options?: RequestOptionsArgs): Observable<Response> {
const resume$ = new ReplaySubject<Date>(1);
this.wait$.next(resume$.delay(this.asyncDelay).take(1));
return this.http.put(url, body, options)
.finally(() => resume$.next(new Date()));
}
}
The idea is that read operations [get()
] are returned in a published/disconnected state until it is confirmed they are eligible to execute (there is no pending write operation).
The subscriptions in the constructor run for the life of the application.
Any write operation [put()
] results in an emission by the wait$ stream. The emission is a resume$ stream that will emit exactly once when the write operation that originated the wait$ emission completes.
Anytime the wait$ stream emits, the innermost subscription responsible for connecting read$ operations is halted - additionally the bufferToggled read$ subscription is opened.
switchMap from the wait$ stream to it's resume$ emission insures that the innermost subscription responsible for connecting read$ operations is not re-started until the write operation that halted the previous subscription is completed.
if a subsequent write operation occurs prior to the completion of the previous, the wait$ stream simply re-starts, ultimately waiting for the new resume$ signal. As I type this I realize that one assumption being made is that write operations will behave in a somewhat LILO fashion when it comes to completion timings. I think this is OK in my particular use case.
Once the last emitted resume$ stream emits, the buffer$ is flushed, closed and merged with a real-time stream of new read$ operations.
The source$ stream returned by a call to get()
is wired up to terminate in the event a write operation begins during it's execution. Additionally, I construct a retry$ stream that ultimately begins with an emission from the wait$ stream. I race() the source$ and retry$ stream... they are mutually exclusive in this case - it's only possible for one of them to emit. If the source$ is terminated, the same signal responsible for terminating it starts the retry$ sequence which recurses back into get()
and ultimately results in the retry response being buffered until all write operations complete.
... and the cycle repeats.
I don't know much about the underpinnings of RXJS, or the overhead involved in gorilla taping all of these operators and streams together as a means to an end. My biggest concern at this point is leaking memory somewhere, and obviously readability for poor soul who needs to modify it 12+ months from now.
waitUntil
operator