@Test public void testZipAsync() { int NUM = (int) (RxRingBuffer.SIZE * 2.1); AtomicInteger c1 = new AtomicInteger(); AtomicInteger c2 = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<Integer>(); Observable<Integer> zipped = Observable.zip( incrementingIntegers(c1).subscribeOn(Schedulers.computation()), incrementingIntegers(c2).subscribeOn(Schedulers.computation()), new Func2<Integer, Integer, Integer>() { @Override public Integer call(Integer t1, Integer t2) { return t1 + t2; } }); zipped.take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testZipAsync => Received: " + ts.getOnNextEvents().size() + " Emitted: " + c1.get() + " / " + c2.get()); assertEquals(NUM, ts.getOnNextEvents().size()); assertTrue(c1.get() < RxRingBuffer.SIZE * 3); assertTrue(c2.get() < RxRingBuffer.SIZE * 3); }
@Test public void testMergeAsyncThenObserveOn() { int NUM = (int) (RxRingBuffer.SIZE * 4.1); AtomicInteger c1 = new AtomicInteger(); AtomicInteger c2 = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<Integer>(); Observable<Integer> merged = Observable.merge( incrementingIntegers(c1).subscribeOn(Schedulers.computation()), incrementingIntegers(c2).subscribeOn(Schedulers.computation())); merged.observeOn(Schedulers.newThread()).take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testMergeAsyncThenObserveOn => Received: " + ts.getOnNextEvents().size() + " Emitted: " + c1.get() + " / " + c2.get()); assertEquals(NUM, ts.getOnNextEvents().size()); // either one can starve the other, but neither should be capable of doing more than 5 batches // (taking 4.1) // TODO is it possible to make this deterministic rather than one possibly starving the other? // benjchristensen => In general I'd say it's not worth trying to make it so, as "fair" // algoritms generally take a performance hit // akarnokd => run this in a loop over 10k times and never saw values get as high as 7*SIZE, but // since observeOn delays the unsubscription non-deterministically, the test will remain // unreliable assertTrue(c1.get() < RxRingBuffer.SIZE * 7); assertTrue(c2.get() < RxRingBuffer.SIZE * 7); }
@Test public void testMergeSync() { int NUM = (int) (RxRingBuffer.SIZE * 4.1); AtomicInteger c1 = new AtomicInteger(); AtomicInteger c2 = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<Integer>(); Observable<Integer> merged = Observable.merge(incrementingIntegers(c1), incrementingIntegers(c2)); merged.take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println("Expected: " + NUM + " got: " + ts.getOnNextEvents().size()); System.out.println( "testMergeSync => Received: " + ts.getOnNextEvents().size() + " Emitted: " + c1.get() + " / " + c2.get()); assertEquals(NUM, ts.getOnNextEvents().size()); // either one can starve the other, but neither should be capable of doing more than 5 batches // (taking 4.1) // TODO is it possible to make this deterministic rather than one possibly starving the other? // benjchristensen => In general I'd say it's not worth trying to make it so, as "fair" // algoritms generally take a performance hit assertTrue(c1.get() < RxRingBuffer.SIZE * 5); assertTrue(c2.get() < RxRingBuffer.SIZE * 5); }
@Test public void testObserveOnWithSlowConsumer() { int NUM = (int) (Observable.bufferSize() * 0.2); AtomicInteger c = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<>(); incrementingIntegers(c) .observeOn(Schedulers.computation()) .map( i -> { try { Thread.sleep(1); } catch (InterruptedException e) { e.printStackTrace(); } return i; }) .take(NUM) .subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testObserveOnWithSlowConsumer => Received: " + ts.valueCount() + " Emitted: " + c.get()); assertEquals(NUM, ts.valueCount()); assertTrue(c.get() < Observable.bufferSize() * 2); }
@Test public void testTakeFilterSkipChainAsync() { int NUM = (int) (Observable.bufferSize() * 2.1); AtomicInteger c = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<>(); incrementingIntegers(c) .observeOn(Schedulers.computation()) .skip(10000) .filter(i -> i > 11000) .take(NUM) .subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); // emit 10000 that are skipped // emit next 1000 that are filtered out // take NUM // so emitted is at least 10000+1000+NUM + extra for buffer size/threshold int expected = 10000 + 1000 + Observable.bufferSize() * 3 + Observable.bufferSize() / 2; System.out.println( "testTakeFilterSkipChain => Received: " + ts.valueCount() + " Emitted: " + c.get() + " Expected: " + expected); assertEquals(NUM, ts.valueCount()); assertTrue(c.get() < expected); }
@Test public void testZipAsync() { int NUM = (int) (Observable.bufferSize() * 2.1); AtomicInteger c1 = new AtomicInteger(); AtomicInteger c2 = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<>(); Observable<Integer> zipped = Observable.zip( incrementingIntegers(c1).subscribeOn(Schedulers.computation()), incrementingIntegers(c2).subscribeOn(Schedulers.computation()), (t1, t2) -> t1 + t2); zipped.take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testZipAsync => Received: " + ts.valueCount() + " Emitted: " + c1.get() + " / " + c2.get()); assertEquals(NUM, ts.valueCount()); int max = Observable.bufferSize() * 5; assertTrue("" + c1.get() + " >= " + max, c1.get() < max); assertTrue("" + c2.get() + " >= " + max, c2.get() < max); }
@Test @Ignore // the test is non-deterministic and can't be made deterministic public void testFlatMapAsync() { int NUM = (int) (Observable.bufferSize() * 2.1); AtomicInteger c = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<>(); incrementingIntegers(c) .subscribeOn(Schedulers.computation()) .flatMap( i -> incrementingIntegers(new AtomicInteger()) .take(10) .subscribeOn(Schedulers.computation())) .take(NUM) .subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testFlatMapAsync => Received: " + ts.valueCount() + " Emitted: " + c.get() + " Size: " + Observable.bufferSize()); assertEquals(NUM, ts.valueCount()); // even though we only need 10, it will request at least Observable.bufferSize(), and then as it // drains keep requesting more // and then it will be non-deterministic when the take() causes the unsubscribe as it is // scheduled on 10 different schedulers (threads) // normally this number is ~250 but can get up to ~1200 when Observable.bufferSize() == 1024 assertTrue(c.get() <= Observable.bufferSize() * 2); }
@Test public void fromArityArgs1() { Observable<String> items = Observable.just("one"); assertEquals((Long) 1L, items.count().toBlocking().single()); assertEquals("one", items.takeLast(1).toBlocking().single()); }
@Test public void testMergeAsyncThenObserveOnLoop() { for (int i = 0; i < 500; i++) { if (i % 10 == 0) { System.out.println("testMergeAsyncThenObserveOnLoop >> " + i); } // Verify there is no MissingBackpressureException int NUM = (int) (RxRingBuffer.SIZE * 4.1); AtomicInteger c1 = new AtomicInteger(); AtomicInteger c2 = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<Integer>(); Observable<Integer> merged = Observable.merge( incrementingIntegers(c1).subscribeOn(Schedulers.computation()), incrementingIntegers(c2).subscribeOn(Schedulers.computation())); merged.observeOn(Schedulers.io()).take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testMergeAsyncThenObserveOn => Received: " + ts.getOnNextEvents().size() + " Emitted: " + c1.get() + " / " + c2.get()); assertEquals(NUM, ts.getOnNextEvents().size()); } }
@Test public void testMergeCovariance4() { Observable<Movie> o1 = Observable.create( new OnSubscribeFunc<Movie>() { @Override public Subscription onSubscribe(Observer<? super Movie> o) { o.onNext(new HorrorMovie()); o.onNext(new Movie()); // o.onNext(new Media()); // correctly doesn't compile o.onCompleted(); return Subscriptions.empty(); } }); Observable<Media> o2 = Observable.from(new Media(), new HorrorMovie()); List<Media> values = Observable.merge(o1, o2).toList().toBlockingObservable().single(); assertTrue(values.get(0) instanceof HorrorMovie); assertTrue(values.get(1) instanceof Movie); assertTrue(values.get(2) instanceof Media); assertTrue(values.get(3) instanceof HorrorMovie); }
@Test public void fromArray() { String[] items = new String[] {"one", "two", "three"}; assertEquals((Long) 3L, Observable.fromArray(items).count().toBlocking().single()); assertEquals("two", Observable.fromArray(items).skip(1).take(1).toBlocking().single()); assertEquals("three", Observable.fromArray(items).takeLast(1).toBlocking().single()); }
@Test public void testMergeAsync() { int NUM = (int) (Observable.bufferSize() * 4.1); AtomicInteger c1 = new AtomicInteger(); AtomicInteger c2 = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<>(); Observable<Integer> merged = Observable.merge( incrementingIntegers(c1).subscribeOn(Schedulers.computation()), incrementingIntegers(c2).subscribeOn(Schedulers.computation())); merged.take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println( "testMergeAsync => Received: " + ts.valueCount() + " Emitted: " + c1.get() + " / " + c2.get()); assertEquals(NUM, ts.valueCount()); // either one can starve the other, but neither should be capable of doing more than 5 batches // (taking 4.1) // TODO is it possible to make this deterministic rather than one possibly starving the other? // benjchristensen => In general I'd say it's not worth trying to make it so, as "fair" // algoritms generally take a performance hit int max = Observable.bufferSize() * 7; assertTrue("" + c1.get() + " >= " + max, c1.get() < max); assertTrue("" + c2.get() + " >= " + max, c2.get() < max); }
/** * The error from the user provided Observable is handled by the subscribe try/catch because this * is synchronous * * <p>Result: Passes */ @Test public void testCustomObservableWithErrorInObservableSynchronous() { final AtomicInteger count = new AtomicInteger(); final AtomicReference<Throwable> error = new AtomicReference<>(); // FIXME custom built??? Observable.just("1", "2") .concatWith(Observable.error(() -> new NumberFormatException())) .subscribe( new Observer<String>() { @Override public void onComplete() { System.out.println("completed"); } @Override public void onError(Throwable e) { error.set(e); System.out.println("error"); e.printStackTrace(); } @Override public void onNext(String v) { System.out.println(v); count.incrementAndGet(); } }); assertEquals(2, count.get()); assertNotNull(error.get()); if (!(error.get() instanceof NumberFormatException)) { fail("It should be a NumberFormatException"); } }
/** * A reduce on an empty Observable and a seed should just pass the seed through. * * <p>This is confirmed at https://github.com/ReactiveX/RxJava/issues/423#issuecomment-27642456 */ @Test public void testReduceWithEmptyObservableAndSeed() { Observable<Integer> observable = Observable.range(1, 0); int value = observable.reduce(1, (t1, t2) -> t1 + t2).toBlocking().last(); assertEquals(1, value); }
public void testTakeFirstWithPredicateOfSome() { Observable<Integer> observable = Observable.just(1, 3, 5, 4, 6, 3); observable.takeFirst(IS_EVEN).subscribe(w); verify(w, times(1)).onNext(anyInt()); verify(w).onNext(4); verify(w, times(1)).onComplete(); verify(w, never()).onError(any(Throwable.class)); }
@Test public void testFirstWithPredicateOfNoneMatchingThePredicate() { Observable<Integer> observable = Observable.just(1, 3, 5, 7, 9, 7, 5, 3, 1); observable.filter(IS_EVEN).first().subscribe(w); verify(w, never()).onNext(anyInt()); verify(w, never()).onComplete(); verify(w, times(1)).onError(isA(NoSuchElementException.class)); }
@Test public void testFirstOfNone() { Observable<Integer> observable = Observable.empty(); observable.first().subscribe(w); verify(w, never()).onNext(anyInt()); verify(w, never()).onComplete(); verify(w, times(1)).onError(isA(NoSuchElementException.class)); }
@Test public void testTakeFirstOfNone() { Observable<Integer> observable = Observable.empty(); observable.take(1).subscribe(w); verify(w, never()).onNext(anyInt()); verify(w, times(1)).onComplete(); verify(w, never()).onError(any(Throwable.class)); }
@Test public void testTakeFirstWithPredicateOfNoneMatchingThePredicate() { Observable<Integer> observable = Observable.just(1, 3, 5, 7, 9, 7, 5, 3, 1); observable.takeFirst(IS_EVEN).subscribe(w); verify(w, never()).onNext(anyInt()); verify(w, times(1)).onComplete(); verify(w, never()).onError(any(Throwable.class)); }
@Test public void testReduceWithInitialValue() { Observable<Integer> observable = Observable.just(1, 2, 3, 4); observable.reduce(50, (t1, t2) -> t1 + t2).subscribe(w); // we should be called only once verify(w, times(1)).onNext(anyInt()); verify(w).onNext(60); }
@Test public void testMergeCovariance2() { Observable<Media> o1 = Observable.from(new HorrorMovie(), new Movie(), new Media()); Observable<Media> o2 = Observable.from(new Media(), new HorrorMovie()); Observable<Observable<Media>> os = Observable.from(o1, o2); List<Media> values = Observable.merge(os).toList().toBlockingObservable().single(); }
@Test public void testCountError() { Observable<String> o = Observable.error(() -> new RuntimeException()); o.count().subscribe(w); verify(w, never()).onNext(anyInt()); verify(w, never()).onComplete(); verify(w, times(1)).onError(any(RuntimeException.class)); }
@Test public void testAssert() { Observable<Integer> oi = Observable.from(Arrays.asList(1, 2)); TestSubscriber<Integer> o = new TestSubscriber<Integer>(); oi.subscribe(o); o.assertReceivedOnNext(Arrays.asList(1, 2)); assertEquals(2, o.getOnNextEvents().size()); o.assertTerminalEvent(); }
@Test public void testCountZeroItems() { Observable<String> observable = Observable.empty(); observable.count().subscribe(w); // we should be called only once verify(w, times(1)).onNext(anyLong()); verify(w).onNext(0L); verify(w, never()).onError(any(Throwable.class)); verify(w, times(1)).onComplete(); }
@Test public void fromIterable() { ArrayList<String> items = new ArrayList<>(); items.add("one"); items.add("two"); items.add("three"); assertEquals((Long) 3L, Observable.fromIterable(items).count().toBlocking().single()); assertEquals("two", Observable.fromIterable(items).skip(1).take(1).toBlocking().single()); assertEquals("three", Observable.fromIterable(items).takeLast(1).toBlocking().single()); }
@Test public void testMergeCovariance3() { Observable<Movie> o1 = Observable.from(new HorrorMovie(), new Movie()); Observable<Media> o2 = Observable.from(new Media(), new HorrorMovie()); List<Media> values = Observable.merge(o1, o2).toList().toBlockingObservable().single(); assertTrue(values.get(0) instanceof HorrorMovie); assertTrue(values.get(1) instanceof Movie); assertTrue(values.get(2) instanceof Media); assertTrue(values.get(3) instanceof HorrorMovie); }
@Test public void testObserveOn() { int NUM = (int) (Observable.bufferSize() * 2.1); AtomicInteger c = new AtomicInteger(); TestSubscriber<Integer> ts = new TestSubscriber<>(); incrementingIntegers(c).observeOn(Schedulers.computation()).take(NUM).subscribe(ts); ts.awaitTerminalEvent(); ts.assertNoErrors(); System.out.println("testObserveOn => Received: " + ts.valueCount() + " Emitted: " + c.get()); assertEquals(NUM, ts.valueCount()); assertTrue(c.get() < Observable.bufferSize() * 4); }
@Test public void testCountAFewItems() { Observable<String> observable = Observable.just("a", "b", "c", "d"); observable.count().subscribe(w); // we should be called only once verify(w, times(1)).onNext(anyLong()); verify(w).onNext(4L); verify(w, never()).onError(any(Throwable.class)); verify(w, times(1)).onComplete(); }
@Test public void testIgnoreElements() { Observable<Integer> observable = Observable.just(1, 2, 3).ignoreElements(); Subscriber<Object> observer = TestHelper.mockSubscriber(); observable.subscribe(observer); verify(observer, never()).onNext(any(Integer.class)); verify(observer, never()).onError(any(Throwable.class)); verify(observer, times(1)).onComplete(); }
@Test public void testContainsWithEmptyObservable() { Observable<Boolean> observable = Observable.<String>empty().contains("a"); Subscriber<Object> observer = TestHelper.mockSubscriber(); observable.subscribe(observer); verify(observer, times(1)).onNext(false); verify(observer, never()).onNext(true); verify(observer, never()).onError(org.mockito.Matchers.any(Throwable.class)); verify(observer, times(1)).onComplete(); }