@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 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 testObserveOnWithSlowConsumer() {
int NUM = (int) (RxRingBuffer.SIZE * 0.2);
AtomicInteger c = new AtomicInteger();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
incrementingIntegers(c)
.observeOn(Schedulers.computation())
.map(
new Func1<Integer, Integer>() {
@Override
public Integer call(Integer 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.getOnNextEvents().size()
+ " Emitted: "
+ c.get());
assertEquals(NUM, ts.getOnNextEvents().size());
assertTrue(c.get() < RxRingBuffer.SIZE * 2);
}
@Test
public void testFlatMapSync() {
int NUM = (int) (RxRingBuffer.SIZE * 2.1);
AtomicInteger c = new AtomicInteger();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
incrementingIntegers(c)
.flatMap(
new Func1<Integer, Observable<Integer>>() {
@Override
public Observable<Integer> call(Integer i) {
return incrementingIntegers(new AtomicInteger()).take(10);
}
})
.take(NUM)
.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
System.out.println(
"testFlatMapSync => Received: " + ts.getOnNextEvents().size() + " Emitted: " + c.get());
assertEquals(NUM, ts.getOnNextEvents().size());
// expect less than 1 buffer since the flatMap is emitting 10 each time, so it is NUM/10 that
// will be taken.
assertTrue(c.get() < RxRingBuffer.SIZE);
}
@Test(timeout = 2000)
public void testOnBackpressureBuffer() {
int NUM = (int) (RxRingBuffer.SIZE * 1.1); // > 1 so that take doesn't prevent buffer overflow
AtomicInteger c = new AtomicInteger();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
firehose(c)
.takeWhile(
new Func1<Integer, Boolean>() {
@Override
public Boolean call(Integer t1) {
return t1 < 100000;
}
})
.onBackpressureBuffer()
.observeOn(Schedulers.computation())
.map(SLOW_PASS_THRU)
.take(NUM)
.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
System.out.println(
"testOnBackpressureBuffer => Received: "
+ ts.getOnNextEvents().size()
+ " Emitted: "
+ c.get());
assertEquals(NUM, ts.getOnNextEvents().size());
// it buffers, so we should get the right value sequentially
assertEquals(NUM - 1, ts.getOnNextEvents().get(NUM - 1).intValue());
}
@Test(timeout = 10000)
public void testOnBackpressureDropSynchronous() {
for (int i = 0; i < 100; i++) {
int NUM = (int) (RxRingBuffer.SIZE * 1.1); // > 1 so that take doesn't prevent buffer overflow
AtomicInteger c = new AtomicInteger();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
firehose(c).onBackpressureDrop().map(SLOW_PASS_THRU).take(NUM).subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
List<Integer> onNextEvents = ts.getOnNextEvents();
assertEquals(NUM, onNextEvents.size());
Integer lastEvent = onNextEvents.get(NUM - 1);
System.out.println(
"testOnBackpressureDrop => Received: "
+ onNextEvents.size()
+ " Emitted: "
+ c.get()
+ " Last value: "
+ lastEvent);
// it drop, so we should get some number far higher than what would have sequentially
// incremented
assertTrue(NUM - 1 <= lastEvent.intValue());
}
}
@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(groups = "standalone")
public void testObserveMultiple() {
final TestSubscriber<Response> tester = new TestSubscriber<>();
try (AsyncHttpClient client = asyncHttpClient()) {
Observable<Response> o1 =
AsyncHttpObservable.observe(() -> client.prepareGet("http://gatling.io"));
Observable<Response> o2 =
AsyncHttpObservable.observe(
() -> client.prepareGet("http://www.wisc.edu").setFollowRedirect(true));
Observable<Response> o3 =
AsyncHttpObservable.observe(
() -> client.prepareGet("http://www.umn.edu").setFollowRedirect(true));
Observable<Response> all = Observable.merge(o1, o2, o3);
all.subscribe(tester);
tester.awaitTerminalEvent();
tester.assertTerminalEvent();
tester.assertCompleted();
tester.assertNoErrors();
List<Response> responses = tester.getOnNextEvents();
assertNotNull(responses);
assertEquals(responses.size(), 3);
for (Response response : responses) {
assertEquals(response.getStatusCode(), 200);
}
} catch (Exception e) {
Thread.currentThread().interrupt();
}
}
@Test
public void testFlatMapMaxConcurrent() {
final int m = 4;
final AtomicInteger subscriptionCount = new AtomicInteger();
Observable<Integer> source =
Observable.range(1, 10)
.flatMap(
new Func1<Integer, Observable<Integer>>() {
@Override
public Observable<Integer> call(Integer t1) {
return compose(Observable.range(t1 * 10, 2), subscriptionCount, m)
.subscribeOn(Schedulers.computation());
}
},
m);
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
source.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
Set<Integer> expected =
new HashSet<Integer>(
Arrays.asList(
10, 11, 20, 21, 30, 31, 40, 41, 50, 51, 60, 61, 70, 71, 80, 81, 90, 91, 100, 101));
Assert.assertEquals(expected.size(), ts.getOnNextEvents().size());
Assert.assertTrue(expected.containsAll(ts.getOnNextEvents()));
}
@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 testAsyncChild() {
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
Observable.range(0, 100000)
.observeOn(Schedulers.newThread())
.observeOn(Schedulers.newThread())
.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
}
private static void waitForStoreToStart(final String storeId) {
TestSubscriber testSubscriber = new TestSubscriber();
sc.getDataService()
.storeStarted(storeId)
.timeout(3, TimeUnit.MINUTES)
.subscribe(testSubscriber);
testSubscriber.awaitTerminalEvent();
testSubscriber.assertNoErrors();
testSubscriber.assertCompleted();
}
@Test
public void shouldEmmitGroundOverlay() throws Exception {
TestSubscriber<GroundOverlay> testSubscriber = new TestSubscriber<>();
new GroundOverlayClickFunc().call(googleMap).subscribe(testSubscriber);
verify(googleMap).setOnGroundOverlayClickListener(argumentCaptor.capture());
argumentCaptor.getValue().onGroundOverlayClick(null);
testSubscriber.assertNoErrors();
testSubscriber.assertValueCount(1);
testSubscriber.assertValue(null);
}
@Test(timeout = 10000)
public void testOnBackpressureDropWithAction() {
for (int i = 0; i < 100; i++) {
final AtomicInteger emitCount = new AtomicInteger();
final AtomicInteger dropCount = new AtomicInteger();
final AtomicInteger passCount = new AtomicInteger();
final int NUM = RxRingBuffer.SIZE * 3; // > 1 so that take doesn't prevent buffer overflow
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
firehose(emitCount)
.onBackpressureDrop(
new Action1<Integer>() {
@Override
public void call(Integer i) {
dropCount.incrementAndGet();
}
})
.doOnNext(
new Action1<Integer>() {
@Override
public void call(Integer integer) {
passCount.incrementAndGet();
}
})
.observeOn(Schedulers.computation())
.map(SLOW_PASS_THRU)
.take(NUM)
.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
List<Integer> onNextEvents = ts.getOnNextEvents();
Integer lastEvent = onNextEvents.get(NUM - 1);
System.out.println(
testName.getMethodName()
+ " => Received: "
+ onNextEvents.size()
+ " Passed: "
+ passCount.get()
+ " Dropped: "
+ dropCount.get()
+ " Emitted: "
+ emitCount.get()
+ " Last value: "
+ lastEvent);
assertEquals(NUM, onNextEvents.size());
// in reality, NUM < passCount
assertTrue(NUM <= passCount.get());
// it drop, so we should get some number far higher than what would have sequentially
// incremented
assertTrue(NUM - 1 <= lastEvent.intValue());
assertTrue(0 < dropCount.get());
assertEquals(emitCount.get(), passCount.get() + dropCount.get());
}
}
@Test
public void testGetArticles() throws Exception {
final int articleNumPerPage = 30;
TestSubscriber<Article> testSubscriber = new TestSubscriber<>();
webApi.getArticles(1, articleNumPerPage).subscribe(testSubscriber);
testSubscriber.assertNoErrors();
List<Article> articleList = testSubscriber.getOnNextEvents();
assertThat(articleList, hasSize(greaterThan(0)));
assertThat(articleList, hasSize(lessThan(articleNumPerPage + 1)));
}
@Test
public void testObserveOn() {
int NUM = (int) (RxRingBuffer.SIZE * 2.1);
AtomicInteger c = new AtomicInteger();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
incrementingIntegers(c).observeOn(Schedulers.computation()).take(NUM).subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
System.out.println(
"testObserveOn => Received: " + ts.getOnNextEvents().size() + " Emitted: " + c.get());
assertEquals(NUM, ts.getOnNextEvents().size());
assertTrue(c.get() < RxRingBuffer.SIZE * 4);
}
@Test
public void lightService_turnOff() {
LightModel light = mockLightModel();
mockClient();
TestSubscriber<LightModel> tester = new TestSubscriber<>();
lightService.turnOff(light).subscribe(tester);
verify(commonService).findClient(GATEWAY_UUID);
tester.assertValue(light);
tester.assertCompleted();
tester.assertNoErrors();
}
@Test
public void lightService_update() {
LightModel lightModel = new LightModel();
when(lightRepository.update(lightModel)).thenReturn(Observable.just(null));
TestSubscriber<Void> tester = new TestSubscriber<>();
lightService.update(lightModel).subscribe(tester);
verify(lightRepository).update(lightModel);
tester.assertCompleted();
tester.assertNoErrors();
}
@Test
public void lightService_delete() {
String LIGHT_UUID = "myUuid";
when(lightRepository.delete(LIGHT_UUID)).thenReturn(Observable.just(null));
TestSubscriber<Void> tester = new TestSubscriber<>();
lightService.delete(LIGHT_UUID).subscribe(tester);
verify(lightRepository).delete(LIGHT_UUID);
tester.assertCompleted();
tester.assertNoErrors();
}
@Test
public void test() {
TestSubscriber<Long> tester = new TestSubscriber<>();
TestScheduler scheduler = Schedulers.test();
Observable.switchOnNext(
Observable.interval(100, TimeUnit.MILLISECONDS, scheduler)
.map(i -> Observable.interval(30, TimeUnit.MILLISECONDS, scheduler).map(i2 -> i)))
.distinctUntilChanged()
.subscribe(tester);
scheduler.advanceTimeBy(500, TimeUnit.MILLISECONDS);
tester.assertReceivedOnNext(Arrays.asList(0L, 1L, 2L, 3L));
tester.assertNoErrors();
assertEquals(tester.getOnCompletedEvents().size(), 0);
}
@Test
public void lightService_add() {
String LIGHT_UUID = "myUuid";
LightModel lightModel = new LightModel();
when(lightRepository.add(lightModel)).thenReturn(Observable.just(LIGHT_UUID));
TestSubscriber<String> tester = new TestSubscriber<>();
lightService.add(lightModel).subscribe(tester);
verify(lightRepository).add(lightModel);
tester.assertValue(LIGHT_UUID);
tester.assertCompleted();
tester.assertNoErrors();
}
@Test
public void testSimpleObject() {
TestSubscriber<Person> subscriber = new TestSubscriber<>();
observable.lift(new GsonConverter<Person>()).subscribe(subscriber);
subscriber.assertNoErrors();
subscriber.assertTerminalEvent();
List<Person> persons = subscriber.getOnNextEvents();
assertEquals(1, persons.size());
Person person = persons.get(0);
assertEquals("John", person.name);
assertEquals(25, person.age);
assertTrue(person.isDev);
}
@Test(timeout = 30000)
public void flatMapRangeMixedAsyncLoop() {
for (int i = 0; i < 2000; i++) {
if (i % 10 == 0) {
System.out.println("flatMapRangeAsyncLoop > " + i);
}
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
Observable.range(0, 1000)
.flatMap(
new Func1<Integer, Observable<Integer>>() {
final Random rnd = new Random();
@Override
public Observable<Integer> call(Integer t) {
Observable<Integer> r = Observable.just(t);
if (rnd.nextBoolean()) {
r = r.asObservable();
}
return r;
}
})
.observeOn(Schedulers.computation())
.subscribe(ts);
ts.awaitTerminalEvent(2500, TimeUnit.MILLISECONDS);
if (ts.getOnCompletedEvents().isEmpty()) {
System.out.println(ts.getOnNextEvents().size());
}
ts.assertTerminalEvent();
ts.assertNoErrors();
List<Integer> list = ts.getOnNextEvents();
if (list.size() < 1000) {
Set<Integer> set = new HashSet<Integer>(list);
for (int j = 0; j < 1000; j++) {
if (!set.contains(j)) {
System.out.println(j + " missing");
}
}
}
assertEquals(1000, list.size());
}
}
@Test(groups = "standalone")
public void testObserveError() {
final TestSubscriber<Response> tester = new TestSubscriber<>();
try (AsyncHttpClient client = asyncHttpClient()) {
Observable<Response> o1 =
AsyncHttpObservable.observe(() -> client.prepareGet("http://gatling.io/ttfn"));
o1.subscribe(tester);
tester.awaitTerminalEvent();
tester.assertTerminalEvent();
tester.assertCompleted();
tester.assertNoErrors();
List<Response> responses = tester.getOnNextEvents();
assertNotNull(responses);
assertEquals(responses.size(), 1);
assertEquals(responses.get(0).getStatusCode(), 404);
} catch (Exception e) {
Thread.currentThread().interrupt();
}
}
@Test
public void testSubscribeOnScheduling() {
// in a loop for repeating the concurrency in this to increase chance of failure
for (int i = 0; i < 100; i++) {
int NUM = (int) (RxRingBuffer.SIZE * 2.1);
AtomicInteger c = new AtomicInteger();
ConcurrentLinkedQueue<Thread> threads = new ConcurrentLinkedQueue<Thread>();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
// observeOn is there to make it async and need backpressure
incrementingIntegers(c, threads)
.subscribeOn(Schedulers.computation())
.observeOn(Schedulers.computation())
.take(NUM)
.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
System.out.println(
"testSubscribeOnScheduling => Received: "
+ ts.getOnNextEvents().size()
+ " Emitted: "
+ c.get());
assertEquals(NUM, ts.getOnNextEvents().size());
assertTrue(c.get() < RxRingBuffer.SIZE * 4);
Thread first = null;
for (Thread t : threads) {
System.out.println("testSubscribeOnScheduling => thread: " + t);
if (first == null) {
first = t;
} else {
if (!first.equals(t)) {
fail("Expected to see the same thread");
}
}
}
System.out.println(
"testSubscribeOnScheduling => Number of batch requests seen: " + threads.size());
assertTrue(threads.size() > 1);
System.out.println(
"-------------------------------------------------------------------------------------------");
}
}
@Test
public void flatMapTwoNestedSync() {
for (final int n : new int[] {1, 1000, 1000000}) {
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
Observable.just(1, 2)
.flatMap(
new Func1<Integer, Observable<Integer>>() {
@Override
public Observable<Integer> call(Integer t) {
return Observable.range(1, n);
}
})
.subscribe(ts);
System.out.println("flatMapTwoNestedSync >> @ " + n);
ts.assertNoErrors();
ts.assertCompleted();
ts.assertValueCount(n * 2);
}
}
public void testDelete() throws Exception {
// arrange
E entity = getFakeEntity();
insertFakeToRealm();
RealmQuery<V> query = realm.where(getRealmObjClass());
assertThat(query.findFirst(), is(notNullValue()));
TestSubscriber<Boolean> subscriber = new TestSubscriber<>();
// act
Observable<Boolean> result = realmCache.delete(entity);
result.subscribe(subscriber);
// assert
subscriber.assertCompleted();
subscriber.assertNoErrors();
subscriber.assertValue(true);
query = realm.where(getRealmObjClass());
assertThat(query.findFirst(), is(nullValue()));
}
@Test
public void flatMapIntPassthruAsync() {
for (int i = 0; i < 1000; i++) {
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
Observable.range(1, 1000)
.flatMap(
new Func1<Integer, Observable<Integer>>() {
@Override
public Observable<Integer> call(Integer t) {
return Observable.just(1).subscribeOn(Schedulers.computation());
}
})
.subscribe(ts);
ts.awaitTerminalEvent(5, TimeUnit.SECONDS);
ts.assertNoErrors();
ts.assertCompleted();
ts.assertValueCount(1000);
}
}
@Ignore // don't care for any reordering
@Test(timeout = 10000)
public void flatMapRangeAsyncLoop() {
for (int i = 0; i < 2000; i++) {
if (i % 10 == 0) {
System.out.println("flatMapRangeAsyncLoop > " + i);
}
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
Observable.range(0, 1000)
.flatMap(
new Func1<Integer, Observable<Integer>>() {
@Override
public Observable<Integer> call(Integer t) {
return Observable.just(t);
}
})
.observeOn(Schedulers.computation())
.subscribe(ts);
ts.awaitTerminalEvent(2500, TimeUnit.MILLISECONDS);
if (ts.getOnCompletedEvents().isEmpty()) {
System.out.println(ts.getOnNextEvents().size());
}
ts.assertTerminalEvent();
ts.assertNoErrors();
List<Integer> list = ts.getOnNextEvents();
assertEquals(1000, list.size());
boolean f = false;
for (int j = 0; j < list.size(); j++) {
if (list.get(j) != j) {
System.out.println(j + " " + list.get(j));
f = true;
}
}
if (f) {
Assert.fail("Results are out of order!");
}
}
}
@Test(timeout = 10000)
public void testOnBackpressureDrop() {
long t = System.currentTimeMillis();
for (int i = 0; i < 100; i++) {
// stop the test if we are getting close to the timeout because slow machines
// may not get through 100 iterations
if (System.currentTimeMillis() - t > TimeUnit.SECONDS.toMillis(9)) {
break;
}
int NUM = (int) (RxRingBuffer.SIZE * 1.1); // > 1 so that take doesn't prevent buffer overflow
AtomicInteger c = new AtomicInteger();
TestSubscriber<Integer> ts = new TestSubscriber<Integer>();
firehose(c)
.onBackpressureDrop()
.observeOn(Schedulers.computation())
.map(SLOW_PASS_THRU)
.take(NUM)
.subscribe(ts);
ts.awaitTerminalEvent();
ts.assertNoErrors();
List<Integer> onNextEvents = ts.getOnNextEvents();
assertEquals(NUM, onNextEvents.size());
Integer lastEvent = onNextEvents.get(NUM - 1);
System.out.println(
"testOnBackpressureDrop => Received: "
+ onNextEvents.size()
+ " Emitted: "
+ c.get()
+ " Last value: "
+ lastEvent);
// it drop, so we should get some number far higher than what would have sequentially
// incremented
assertTrue(NUM - 1 <= lastEvent.intValue());
}
}
