/** * JUnit. * * @throws Exception If failed. */ @SuppressWarnings({"TooBroadScope"}) public void testRestarts() throws Exception { int duration = 60 * 1000; int qryThreadNum = 10; final long nodeLifeTime = 2 * 1000; final int logFreq = 20; final IgniteCache<Integer, Integer> cache = grid(0).cache(null); assert cache != null; for (int i = 0; i < KEY_CNT; i++) cache.put(i, i); assertEquals(KEY_CNT, cache.localSize()); final AtomicInteger qryCnt = new AtomicInteger(); final AtomicBoolean done = new AtomicBoolean(); IgniteInternalFuture<?> fut1 = multithreadedAsync( new CAX() { @Override public void applyx() throws IgniteCheckedException { while (!done.get()) { Collection<Cache.Entry<Integer, Integer>> res = cache.query(new SqlQuery(Integer.class, "_val >= 0")).getAll(); assertFalse(res.isEmpty()); int c = qryCnt.incrementAndGet(); if (c % logFreq == 0) info("Executed queries: " + c); } } }, qryThreadNum); final AtomicInteger restartCnt = new AtomicInteger(); CollectingEventListener lsnr = new CollectingEventListener(); for (int i = 0; i < GRID_CNT; i++) grid(i).events().localListen(lsnr, EventType.EVT_CACHE_REBALANCE_STOPPED); IgniteInternalFuture<?> fut2 = multithreadedAsync( new Callable<Object>() { @SuppressWarnings({"BusyWait"}) @Override public Object call() throws Exception { while (!done.get()) { int idx = GRID_CNT; startGrid(idx); Thread.sleep(nodeLifeTime); stopGrid(idx); int c = restartCnt.incrementAndGet(); if (c % logFreq == 0) info("Node restarts: " + c); } return true; } }, 1); Thread.sleep(duration); done.set(true); fut1.get(); fut2.get(); info("Awaiting rebalance events [restartCnt=" + restartCnt.get() + ']'); boolean success = lsnr.awaitEvents(GRID_CNT * 2 * restartCnt.get(), 15000); for (int i = 0; i < GRID_CNT; i++) grid(i).events().stopLocalListen(lsnr, EventType.EVT_CACHE_REBALANCE_STOPPED); assert success; }
/** * @param cacheMode Cache mode. * @param sameAff If {@code false} uses different number of partitions for caches. * @param concurrency Transaction concurrency. * @param isolation Transaction isolation. * @throws Exception If failed. */ private void crossCacheTxFailover( CacheMode cacheMode, boolean sameAff, final TransactionConcurrency concurrency, final TransactionIsolation isolation) throws Exception { IgniteKernal ignite0 = (IgniteKernal) ignite(0); final AtomicBoolean stop = new AtomicBoolean(); try { ignite0.createCache(cacheConfiguration(CACHE1, cacheMode, 256)); ignite0.createCache(cacheConfiguration(CACHE2, cacheMode, sameAff ? 256 : 128)); final AtomicInteger threadIdx = new AtomicInteger(); IgniteInternalFuture<?> fut = GridTestUtils.runMultiThreadedAsync( new Callable<Void>() { @Override public Void call() throws Exception { int idx = threadIdx.getAndIncrement(); Ignite ignite = ignite(idx % GRID_CNT); log.info( "Started update thread [node=" + ignite.name() + ", client=" + ignite.configuration().isClientMode() + ']'); IgniteCache<TestKey, TestValue> cache1 = ignite.cache(CACHE1); IgniteCache<TestKey, TestValue> cache2 = ignite.cache(CACHE2); assertNotSame(cache1, cache2); IgniteTransactions txs = ignite.transactions(); ThreadLocalRandom rnd = ThreadLocalRandom.current(); long iter = 0; while (!stop.get()) { boolean sameKey = rnd.nextBoolean(); try { try (Transaction tx = txs.txStart(concurrency, isolation)) { if (sameKey) { TestKey key = new TestKey(rnd.nextLong(KEY_RANGE)); cacheOperation(rnd, cache1, key); cacheOperation(rnd, cache2, key); } else { TestKey key1 = new TestKey(rnd.nextLong(KEY_RANGE)); TestKey key2 = new TestKey(key1.key() + 1); cacheOperation(rnd, cache1, key1); cacheOperation(rnd, cache2, key2); } tx.commit(); } } catch (CacheException | IgniteException e) { log.info("Update error: " + e); } if (iter++ % 500 == 0) log.info("Iteration: " + iter); } return null; } /** * @param rnd Random. * @param cache Cache. * @param key Key. */ private void cacheOperation( ThreadLocalRandom rnd, IgniteCache<TestKey, TestValue> cache, TestKey key) { switch (rnd.nextInt(4)) { case 0: cache.put(key, new TestValue(rnd.nextLong())); break; case 1: cache.remove(key); break; case 2: cache.invoke(key, new TestEntryProcessor(rnd.nextBoolean() ? 1L : null)); break; case 3: cache.get(key); break; default: assert false; } } }, 10, "tx-thread"); long stopTime = System.currentTimeMillis() + 3 * 60_000; long topVer = ignite0.cluster().topologyVersion(); boolean failed = false; while (System.currentTimeMillis() < stopTime) { log.info("Start node."); IgniteKernal ignite = (IgniteKernal) startGrid(GRID_CNT); assertFalse(ignite.configuration().isClientMode()); topVer++; IgniteInternalFuture<?> affFut = ignite .context() .cache() .context() .exchange() .affinityReadyFuture(new AffinityTopologyVersion(topVer)); try { if (affFut != null) affFut.get(30_000); } catch (IgniteFutureTimeoutCheckedException e) { log.error("Failed to wait for affinity future after start: " + topVer); failed = true; break; } Thread.sleep(500); log.info("Stop node."); stopGrid(GRID_CNT); topVer++; affFut = ignite0 .context() .cache() .context() .exchange() .affinityReadyFuture(new AffinityTopologyVersion(topVer)); try { if (affFut != null) affFut.get(30_000); } catch (IgniteFutureTimeoutCheckedException e) { log.error("Failed to wait for affinity future after stop: " + topVer); failed = true; break; } } stop.set(true); fut.get(); assertFalse("Test failed, see log for details.", failed); } finally { stop.set(true); ignite0.destroyCache(CACHE1); ignite0.destroyCache(CACHE2); awaitPartitionMapExchange(); } }