/** {@inheritDoc} */ @Override public final Map<UUID, GridNodeMetrics> metrics(Collection<UUID> nodeIds) throws GridSpiException { assert !F.isEmpty(nodeIds); long now = U.currentTimeMillis(); Collection<UUID> expired = new LinkedList<>(); for (UUID id : nodeIds) { GridNodeMetrics nodeMetrics = metricsMap.get(id); Long ts = tsMap.get(id); if (nodeMetrics == null || ts == null || ts < now - metricsExpireTime) expired.add(id); } if (!expired.isEmpty()) { Map<UUID, GridNodeMetrics> refreshed = metrics0(expired); for (UUID id : refreshed.keySet()) tsMap.put(id, now); metricsMap.putAll(refreshed); } return F.view(metricsMap, F.contains(nodeIds)); }
/** * Flushes every internal buffer if buffer was flushed before passed in threshold. * * <p>Does not wait for result and does not fail on errors assuming that this method should be * called periodically. */ @Override public void tryFlush() throws GridInterruptedException { if (!busyLock.enterBusy()) return; try { for (Buffer buf : bufMappings.values()) buf.flush(); lastFlushTime = U.currentTimeMillis(); } finally { leaveBusy(); } }
/** {@inheritDoc} */ @Override public long getDelay(TimeUnit unit) { return unit.convert(nextFlushTime() - U.currentTimeMillis(), TimeUnit.MILLISECONDS); }
/** Data loader implementation. */ public class GridDataLoaderImpl<K, V> implements GridDataLoader<K, V>, Delayed { /** Cache updater. */ private GridDataLoadCacheUpdater<K, V> updater = GridDataLoadCacheUpdaters.individual(); /** */ private byte[] updaterBytes; /** Max remap count before issuing an error. */ private static final int MAX_REMAP_CNT = 32; /** Log reference. */ private static final AtomicReference<GridLogger> logRef = new AtomicReference<>(); /** Cache name ({@code null} for default cache). */ private final String cacheName; /** Per-node buffer size. */ @SuppressWarnings("FieldAccessedSynchronizedAndUnsynchronized") private int bufSize = DFLT_PER_NODE_BUFFER_SIZE; /** */ private int parallelOps = DFLT_MAX_PARALLEL_OPS; /** */ private long autoFlushFreq; /** Mapping. */ @GridToStringInclude private ConcurrentMap<UUID, Buffer> bufMappings = new ConcurrentHashMap8<>(); /** Logger. */ private GridLogger log; /** Discovery listener. */ private final GridLocalEventListener discoLsnr; /** Context. */ private final GridKernalContext ctx; /** Communication topic for responses. */ private final Object topic; /** */ private byte[] topicBytes; /** {@code True} if data loader has been cancelled. */ private volatile boolean cancelled; /** Active futures of this data loader. */ @GridToStringInclude private final Collection<GridFuture<?>> activeFuts = new GridConcurrentHashSet<>(); /** Closure to remove from active futures. */ @GridToStringExclude private final GridInClosure<GridFuture<?>> rmvActiveFut = new GridInClosure<GridFuture<?>>() { @Override public void apply(GridFuture<?> t) { boolean rmv = activeFuts.remove(t); assert rmv; } }; /** Job peer deploy aware. */ private volatile GridPeerDeployAware jobPda; /** Deployment class. */ private Class<?> depCls; /** Future to track loading finish. */ private final GridFutureAdapter<?> fut; /** Busy lock. */ private final GridSpinBusyLock busyLock = new GridSpinBusyLock(); /** Closed flag. */ private final AtomicBoolean closed = new AtomicBoolean(); /** */ private volatile long lastFlushTime = U.currentTimeMillis(); /** */ private final DelayQueue<GridDataLoaderImpl<K, V>> flushQ; /** * @param ctx Grid kernal context. * @param cacheName Cache name. * @param flushQ Flush queue. */ public GridDataLoaderImpl( final GridKernalContext ctx, @Nullable final String cacheName, DelayQueue<GridDataLoaderImpl<K, V>> flushQ) { assert ctx != null; this.ctx = ctx; this.cacheName = cacheName; this.flushQ = flushQ; log = U.logger(ctx, logRef, GridDataLoaderImpl.class); discoLsnr = new GridLocalEventListener() { @Override public void onEvent(GridEvent evt) { assert evt.type() == EVT_NODE_FAILED || evt.type() == EVT_NODE_LEFT; GridDiscoveryEvent discoEvt = (GridDiscoveryEvent) evt; UUID id = discoEvt.eventNodeId(); // Remap regular mappings. final Buffer buf = bufMappings.remove(id); if (buf != null) { // Only async notification is possible since // discovery thread may be trapped otherwise. ctx.closure() .callLocalSafe( new Callable<Object>() { @Override public Object call() throws Exception { buf.onNodeLeft(); return null; } }, true /* system pool */); } } }; ctx.event().addLocalEventListener(discoLsnr, EVT_NODE_FAILED, EVT_NODE_LEFT); // Generate unique topic for this loader. topic = TOPIC_DATALOAD.topic(GridUuid.fromUuid(ctx.localNodeId())); ctx.io() .addMessageListener( topic, new GridMessageListener() { @Override public void onMessage(UUID nodeId, Object msg) { assert msg instanceof GridDataLoadResponse; GridDataLoadResponse res = (GridDataLoadResponse) msg; if (log.isDebugEnabled()) log.debug("Received data load response: " + res); Buffer buf = bufMappings.get(nodeId); if (buf != null) buf.onResponse(res); else if (log.isDebugEnabled()) log.debug("Ignoring response since node has left [nodeId=" + nodeId + ", "); } }); if (log.isDebugEnabled()) log.debug("Added response listener within topic: " + topic); fut = new GridDataLoaderFuture(ctx, this); } /** Enters busy lock. */ private void enterBusy() { if (!busyLock.enterBusy()) throw new IllegalStateException("Data loader has been closed."); } /** Leaves busy lock. */ private void leaveBusy() { busyLock.leaveBusy(); } /** {@inheritDoc} */ @Override public GridFuture<?> future() { return fut; } /** {@inheritDoc} */ @Override public void deployClass(Class<?> depCls) { this.depCls = depCls; } /** {@inheritDoc} */ @Override public void updater(GridDataLoadCacheUpdater<K, V> updater) { A.notNull(updater, "updater"); this.updater = updater; } /** {@inheritDoc} */ @Override public boolean isolated() { return updater != GridDataLoadCacheUpdaters.individual(); } /** {@inheritDoc} */ @Override public void isolated(boolean isolated) throws GridException { if (isolated()) return; GridNode node = F.first(ctx.grid().forCache(cacheName).nodes()); if (node == null) throw new GridException("Failed to get node for cache: " + cacheName); GridCacheAttributes a = U.cacheAttributes(node, cacheName); assert a != null; updater = a.atomicityMode() == GridCacheAtomicityMode.ATOMIC ? GridDataLoadCacheUpdaters.<K, V>batched() : GridDataLoadCacheUpdaters.<K, V>groupLocked(); } /** {@inheritDoc} */ @Override @Nullable public String cacheName() { return cacheName; } /** {@inheritDoc} */ @Override public int perNodeBufferSize() { return bufSize; } /** {@inheritDoc} */ @Override public void perNodeBufferSize(int bufSize) { A.ensure(bufSize > 0, "bufSize > 0"); this.bufSize = bufSize; } /** {@inheritDoc} */ @Override public int perNodeParallelLoadOperations() { return parallelOps; } /** {@inheritDoc} */ @Override public void perNodeParallelLoadOperations(int parallelOps) { this.parallelOps = parallelOps; } /** {@inheritDoc} */ @Override public long autoFlushFrequency() { return autoFlushFreq; } /** {@inheritDoc} */ @Override public void autoFlushFrequency(long autoFlushFreq) { A.ensure(autoFlushFreq >= 0, "autoFlushFreq >= 0"); long old = this.autoFlushFreq; if (autoFlushFreq != old) { this.autoFlushFreq = autoFlushFreq; if (autoFlushFreq != 0 && old == 0) flushQ.add(this); else if (autoFlushFreq == 0) flushQ.remove(this); } } /** {@inheritDoc} */ @Override public GridFuture<?> addData(Map<K, V> entries) throws IllegalStateException { A.notNull(entries, "entries"); return addData(entries.entrySet()); } /** {@inheritDoc} */ @Override public GridFuture<?> addData(Collection<? extends Map.Entry<K, V>> entries) { A.notEmpty(entries, "entries"); enterBusy(); try { GridFutureAdapter<Object> resFut = new GridFutureAdapter<>(ctx); activeFuts.add(resFut); resFut.listenAsync(rmvActiveFut); Collection<K> keys = new GridConcurrentHashSet<>(entries.size(), 1.0f, 16); for (Map.Entry<K, V> entry : entries) keys.add(entry.getKey()); load0(entries, resFut, keys, 0); return resFut; } finally { leaveBusy(); } } /** {@inheritDoc} */ @Override public GridFuture<?> addData(Map.Entry<K, V> entry) throws GridException, IllegalStateException { A.notNull(entry, "entry"); return addData(F.asList(entry)); } /** {@inheritDoc} */ @Override public GridFuture<?> addData(K key, V val) throws GridException, IllegalStateException { A.notNull(key, "key"); return addData(new Entry0<>(key, val)); } /** {@inheritDoc} */ @Override public GridFuture<?> removeData(K key) throws GridException, IllegalStateException { return addData(key, null); } /** * @param entries Entries. * @param resFut Result future. * @param activeKeys Active keys. * @param remaps Remaps count. */ private void load0( Collection<? extends Map.Entry<K, V>> entries, final GridFutureAdapter<Object> resFut, final Collection<K> activeKeys, final int remaps) { assert entries != null; if (remaps >= MAX_REMAP_CNT) { resFut.onDone(new GridException("Failed to finish operation (too many remaps): " + remaps)); return; } Map<GridNode, Collection<Map.Entry<K, V>>> mappings = new HashMap<>(); boolean initPda = ctx.deploy().enabled() && jobPda == null; for (Map.Entry<K, V> entry : entries) { GridNode node; try { K key = entry.getKey(); assert key != null; if (initPda) { jobPda = new DataLoaderPda(key, entry.getValue(), updater); initPda = false; } node = ctx.affinity().mapKeyToNode(cacheName, key); } catch (GridException e) { resFut.onDone(e); return; } if (node == null) { resFut.onDone( new GridTopologyException( "Failed to map key to node " + "(no nodes with cache found in topology) [infos=" + entries.size() + ", cacheName=" + cacheName + ']')); return; } Collection<Map.Entry<K, V>> col = mappings.get(node); if (col == null) mappings.put(node, col = new ArrayList<>()); col.add(entry); } for (final Map.Entry<GridNode, Collection<Map.Entry<K, V>>> e : mappings.entrySet()) { final UUID nodeId = e.getKey().id(); Buffer buf = bufMappings.get(nodeId); if (buf == null) { Buffer old = bufMappings.putIfAbsent(nodeId, buf = new Buffer(e.getKey())); if (old != null) buf = old; } final Collection<Map.Entry<K, V>> entriesForNode = e.getValue(); GridInClosure<GridFuture<?>> lsnr = new GridInClosure<GridFuture<?>>() { @Override public void apply(GridFuture<?> t) { try { t.get(); for (Map.Entry<K, V> e : entriesForNode) activeKeys.remove(e.getKey()); if (activeKeys.isEmpty()) resFut.onDone(); } catch (GridException e1) { if (log.isDebugEnabled()) log.debug("Future finished with error [nodeId=" + nodeId + ", err=" + e1 + ']'); if (cancelled) { resFut.onDone( new GridException( "Data loader has been cancelled: " + GridDataLoaderImpl.this, e1)); } else load0(entriesForNode, resFut, activeKeys, remaps + 1); } } }; GridFutureAdapter<?> f; try { f = buf.update(entriesForNode, lsnr); } catch (GridInterruptedException e1) { resFut.onDone(e1); return; } if (ctx.discovery().node(nodeId) == null) { if (bufMappings.remove(nodeId, buf)) buf.onNodeLeft(); if (f != null) f.onDone( new GridTopologyException( "Failed to wait for request completion " + "(node has left): " + nodeId)); } } } /** * Performs flush. * * @throws GridException If failed. */ private void doFlush() throws GridException { lastFlushTime = U.currentTimeMillis(); List<GridFuture> activeFuts0 = null; int doneCnt = 0; for (GridFuture<?> f : activeFuts) { if (!f.isDone()) { if (activeFuts0 == null) activeFuts0 = new ArrayList<>((int) (activeFuts.size() * 1.2)); activeFuts0.add(f); } else { f.get(); doneCnt++; } } if (activeFuts0 == null || activeFuts0.isEmpty()) return; while (true) { Queue<GridFuture<?>> q = null; for (Buffer buf : bufMappings.values()) { GridFuture<?> flushFut = buf.flush(); if (flushFut != null) { if (q == null) q = new ArrayDeque<>(bufMappings.size() * 2); q.add(flushFut); } } if (q != null) { assert !q.isEmpty(); boolean err = false; for (GridFuture fut = q.poll(); fut != null; fut = q.poll()) { try { fut.get(); } catch (GridException e) { if (log.isDebugEnabled()) log.debug("Failed to flush buffer: " + e); err = true; } } if (err) // Remaps needed - flush buffers. continue; } doneCnt = 0; for (int i = 0; i < activeFuts0.size(); i++) { GridFuture f = activeFuts0.get(i); if (f == null) doneCnt++; else if (f.isDone()) { f.get(); doneCnt++; activeFuts0.set(i, null); } else break; } if (doneCnt == activeFuts0.size()) return; } } /** {@inheritDoc} */ @SuppressWarnings("ForLoopReplaceableByForEach") @Override public void flush() throws GridException { enterBusy(); try { doFlush(); } finally { leaveBusy(); } } /** * Flushes every internal buffer if buffer was flushed before passed in threshold. * * <p>Does not wait for result and does not fail on errors assuming that this method should be * called periodically. */ @Override public void tryFlush() throws GridInterruptedException { if (!busyLock.enterBusy()) return; try { for (Buffer buf : bufMappings.values()) buf.flush(); lastFlushTime = U.currentTimeMillis(); } finally { leaveBusy(); } } /** * @param cancel {@code True} to close with cancellation. * @throws GridException If failed. */ @Override public void close(boolean cancel) throws GridException { if (!closed.compareAndSet(false, true)) return; busyLock.block(); if (log.isDebugEnabled()) log.debug("Closing data loader [ldr=" + this + ", cancel=" + cancel + ']'); GridException e = null; try { // Assuming that no methods are called on this loader after this method is called. if (cancel) { cancelled = true; for (Buffer buf : bufMappings.values()) buf.cancelAll(); } else doFlush(); ctx.event().removeLocalEventListener(discoLsnr); ctx.io().removeMessageListener(topic); } catch (GridException e0) { e = e0; } fut.onDone(null, e); if (e != null) throw e; } /** @return {@code true} If the loader is closed. */ boolean isClosed() { return fut.isDone(); } /** {@inheritDoc} */ @Override public void close() throws GridException { close(false); } /** {@inheritDoc} */ @Override public String toString() { return S.toString(GridDataLoaderImpl.class, this); } /** {@inheritDoc} */ @Override public long getDelay(TimeUnit unit) { return unit.convert(nextFlushTime() - U.currentTimeMillis(), TimeUnit.MILLISECONDS); } /** @return Next flush time. */ private long nextFlushTime() { return lastFlushTime + autoFlushFreq; } /** {@inheritDoc} */ @Override public int compareTo(Delayed o) { return nextFlushTime() > ((GridDataLoaderImpl) o).nextFlushTime() ? 1 : -1; } /** */ private class Buffer { /** Node. */ private final GridNode node; /** Active futures. */ private final Collection<GridFuture<Object>> locFuts; /** Buffered entries. */ private List<Map.Entry<K, V>> entries; /** */ @GridToStringExclude private GridFutureAdapter<Object> curFut; /** Local node flag. */ private final boolean isLocNode; /** ID generator. */ private final AtomicLong idGen = new AtomicLong(); /** Active futures. */ private final ConcurrentMap<Long, GridFutureAdapter<Object>> reqs; /** */ private final Semaphore sem; /** Closure to signal on task finish. */ @GridToStringExclude private final GridInClosure<GridFuture<Object>> signalC = new GridInClosure<GridFuture<Object>>() { @Override public void apply(GridFuture<Object> t) { signalTaskFinished(t); } }; /** @param node Node. */ Buffer(GridNode node) { assert node != null; this.node = node; locFuts = new GridConcurrentHashSet<>(); reqs = new ConcurrentHashMap8<>(); // Cache local node flag. isLocNode = node.equals(ctx.discovery().localNode()); entries = newEntries(); curFut = new GridFutureAdapter<>(ctx); curFut.listenAsync(signalC); sem = new Semaphore(parallelOps); } /** * @param newEntries Infos. * @param lsnr Listener for the operation future. * @throws GridInterruptedException If failed. * @return Future for operation. */ @Nullable GridFutureAdapter<?> update( Iterable<Map.Entry<K, V>> newEntries, GridInClosure<GridFuture<?>> lsnr) throws GridInterruptedException { List<Map.Entry<K, V>> entries0 = null; GridFutureAdapter<Object> curFut0; synchronized (this) { curFut0 = curFut; curFut0.listenAsync(lsnr); for (Map.Entry<K, V> entry : newEntries) entries.add(entry); if (entries.size() >= bufSize) { entries0 = entries; entries = newEntries(); curFut = new GridFutureAdapter<>(ctx); curFut.listenAsync(signalC); } } if (entries0 != null) { submit(entries0, curFut0); if (cancelled) curFut0.onDone( new GridException("Data loader has been cancelled: " + GridDataLoaderImpl.this)); } return curFut0; } /** @return Fresh collection with some space for outgrowth. */ private List<Map.Entry<K, V>> newEntries() { return new ArrayList<>((int) (bufSize * 1.2)); } /** * @return Future if any submitted. * @throws GridInterruptedException If thread has been interrupted. */ @Nullable GridFuture<?> flush() throws GridInterruptedException { List<Map.Entry<K, V>> entries0 = null; GridFutureAdapter<Object> curFut0 = null; synchronized (this) { if (!entries.isEmpty()) { entries0 = entries; curFut0 = curFut; entries = newEntries(); curFut = new GridFutureAdapter<>(ctx); curFut.listenAsync(signalC); } } if (entries0 != null) submit(entries0, curFut0); // Create compound future for this flush. GridCompoundFuture<Object, Object> res = null; for (GridFuture<Object> f : locFuts) { if (res == null) res = new GridCompoundFuture<>(ctx); res.add(f); } for (GridFuture<Object> f : reqs.values()) { if (res == null) res = new GridCompoundFuture<>(ctx); res.add(f); } if (res != null) res.markInitialized(); return res; } /** * Increments active tasks count. * * @throws GridInterruptedException If thread has been interrupted. */ private void incrementActiveTasks() throws GridInterruptedException { U.acquire(sem); } /** @param f Future that finished. */ private void signalTaskFinished(GridFuture<Object> f) { assert f != null; sem.release(); } /** * @param entries Entries to submit. * @param curFut Current future. * @throws GridInterruptedException If interrupted. */ private void submit(final List<Map.Entry<K, V>> entries, final GridFutureAdapter<Object> curFut) throws GridInterruptedException { assert entries != null; assert !entries.isEmpty(); assert curFut != null; incrementActiveTasks(); GridFuture<Object> fut; if (isLocNode) { fut = ctx.closure() .callLocalSafe( new GridDataLoadUpdateJob<>(ctx, log, cacheName, entries, false, updater), false); locFuts.add(fut); fut.listenAsync( new GridInClosure<GridFuture<Object>>() { @Override public void apply(GridFuture<Object> t) { try { boolean rmv = locFuts.remove(t); assert rmv; curFut.onDone(t.get()); } catch (GridException e) { curFut.onDone(e); } } }); } else { byte[] entriesBytes; try { entriesBytes = ctx.config().getMarshaller().marshal(entries); if (updaterBytes == null) { assert updater != null; updaterBytes = ctx.config().getMarshaller().marshal(updater); } if (topicBytes == null) topicBytes = ctx.config().getMarshaller().marshal(topic); } catch (GridException e) { U.error(log, "Failed to marshal (request will not be sent).", e); return; } GridDeployment dep = null; GridPeerDeployAware jobPda0 = null; if (ctx.deploy().enabled()) { try { jobPda0 = jobPda; assert jobPda0 != null; dep = ctx.deploy().deploy(jobPda0.deployClass(), jobPda0.classLoader()); } catch (GridException e) { U.error( log, "Failed to deploy class (request will not be sent): " + jobPda0.deployClass(), e); return; } if (dep == null) U.warn(log, "Failed to deploy class (request will be sent): " + jobPda0.deployClass()); } long reqId = idGen.incrementAndGet(); fut = curFut; reqs.put(reqId, (GridFutureAdapter<Object>) fut); GridDataLoadRequest<Object, Object> req = new GridDataLoadRequest<>( reqId, topicBytes, cacheName, updaterBytes, entriesBytes, true, dep != null ? dep.deployMode() : null, dep != null ? jobPda0.deployClass().getName() : null, dep != null ? dep.userVersion() : null, dep != null ? dep.participants() : null, dep != null ? dep.classLoaderId() : null, dep == null); try { ctx.io().send(node, TOPIC_DATALOAD, req, PUBLIC_POOL); if (log.isDebugEnabled()) log.debug("Sent request to node [nodeId=" + node.id() + ", req=" + req + ']'); } catch (GridException e) { if (ctx.discovery().alive(node) && ctx.discovery().pingNode(node.id())) ((GridFutureAdapter<Object>) fut).onDone(e); else ((GridFutureAdapter<Object>) fut) .onDone( new GridTopologyException( "Failed to send " + "request (node has left): " + node.id())); } } } /** */ void onNodeLeft() { assert !isLocNode; assert bufMappings.get(node.id()) != this; if (log.isDebugEnabled()) log.debug("Forcibly completing futures (node has left): " + node.id()); Exception e = new GridTopologyException( "Failed to wait for request completion " + "(node has left): " + node.id()); for (GridFutureAdapter<Object> f : reqs.values()) f.onDone(e); // Make sure to complete current future. GridFutureAdapter<Object> curFut0; synchronized (this) { curFut0 = curFut; } curFut0.onDone(e); } /** @param res Response. */ void onResponse(GridDataLoadResponse res) { if (log.isDebugEnabled()) log.debug("Received data load response: " + res); GridFutureAdapter<?> f = reqs.remove(res.requestId()); if (f == null) { if (log.isDebugEnabled()) log.debug("Future for request has not been found: " + res.requestId()); return; } Throwable err = null; byte[] errBytes = res.errorBytes(); if (errBytes != null) { try { GridPeerDeployAware jobPda0 = jobPda; err = ctx.config() .getMarshaller() .unmarshal( errBytes, jobPda0 != null ? jobPda0.classLoader() : U.gridClassLoader()); } catch (GridException e) { f.onDone(null, new GridException("Failed to unmarshal response.", e)); return; } } f.onDone(null, err); if (log.isDebugEnabled()) log.debug( "Finished future [fut=" + f + ", reqId=" + res.requestId() + ", err=" + err + ']'); } /** */ void cancelAll() { GridException err = new GridException("Data loader has been cancelled: " + GridDataLoaderImpl.this); for (GridFuture<?> f : locFuts) { try { f.cancel(); } catch (GridException e) { U.error(log, "Failed to cancel mini-future.", e); } } for (GridFutureAdapter<?> f : reqs.values()) f.onDone(err); } /** {@inheritDoc} */ @Override public String toString() { int size; synchronized (this) { size = entries.size(); } return S.toString( Buffer.class, this, "entriesCnt", size, "locFutsSize", locFuts.size(), "reqsSize", reqs.size()); } } /** Data loader peer-deploy aware. */ private class DataLoaderPda implements GridPeerDeployAware { /** Deploy class. */ private Class<?> cls; /** Class loader. */ private ClassLoader ldr; /** Collection of objects to detect deploy class and class loader. */ private Collection<Object> objs; /** * Constructs data loader peer-deploy aware. * * @param objs Collection of objects to detect deploy class and class loader. */ private DataLoaderPda(Object... objs) { this.objs = Arrays.asList(objs); } /** {@inheritDoc} */ @Override public Class<?> deployClass() { if (cls == null) { Class<?> cls0 = null; if (depCls != null) cls0 = depCls; else { for (Iterator<Object> it = objs.iterator(); (cls0 == null || U.isJdk(cls0)) && it.hasNext(); ) { Object o = it.next(); if (o != null) cls0 = U.detectClass(o); } if (cls0 == null || U.isJdk(cls0)) cls0 = GridDataLoaderImpl.class; } assert cls0 != null : "Failed to detect deploy class [objs=" + objs + ']'; cls = cls0; } return cls; } /** {@inheritDoc} */ @Override public ClassLoader classLoader() { if (ldr == null) { ClassLoader ldr0 = deployClass().getClassLoader(); // Safety. if (ldr0 == null) ldr0 = U.gridClassLoader(); assert ldr0 != null : "Failed to detect classloader [objs=" + objs + ']'; ldr = ldr0; } return ldr; } } /** Entry. */ private static class Entry0<K, V> implements Map.Entry<K, V>, Externalizable { /** */ private K key; /** */ private V val; /** * @param key Key. * @param val Value. */ private Entry0(K key, @Nullable V val) { assert key != null; this.key = key; this.val = val; } /** For {@link Externalizable}. */ @SuppressWarnings("UnusedDeclaration") public Entry0() { // No-op. } /** {@inheritDoc} */ @Override public K getKey() { return key; } /** {@inheritDoc} */ @Override public V getValue() { return val; } /** {@inheritDoc} */ @Override public V setValue(V val) { throw new UnsupportedOperationException(); } /** {@inheritDoc} */ @Override public void writeExternal(ObjectOutput out) throws IOException { out.writeObject(key); out.writeObject(val); } /** {@inheritDoc} */ @Override public void readExternal(ObjectInput in) throws IOException, ClassNotFoundException { key = (K) in.readObject(); val = (V) in.readObject(); } } }
/** * Performs flush. * * @throws GridException If failed. */ private void doFlush() throws GridException { lastFlushTime = U.currentTimeMillis(); List<GridFuture> activeFuts0 = null; int doneCnt = 0; for (GridFuture<?> f : activeFuts) { if (!f.isDone()) { if (activeFuts0 == null) activeFuts0 = new ArrayList<>((int) (activeFuts.size() * 1.2)); activeFuts0.add(f); } else { f.get(); doneCnt++; } } if (activeFuts0 == null || activeFuts0.isEmpty()) return; while (true) { Queue<GridFuture<?>> q = null; for (Buffer buf : bufMappings.values()) { GridFuture<?> flushFut = buf.flush(); if (flushFut != null) { if (q == null) q = new ArrayDeque<>(bufMappings.size() * 2); q.add(flushFut); } } if (q != null) { assert !q.isEmpty(); boolean err = false; for (GridFuture fut = q.poll(); fut != null; fut = q.poll()) { try { fut.get(); } catch (GridException e) { if (log.isDebugEnabled()) log.debug("Failed to flush buffer: " + e); err = true; } } if (err) // Remaps needed - flush buffers. continue; } doneCnt = 0; for (int i = 0; i < activeFuts0.size(); i++) { GridFuture f = activeFuts0.get(i); if (f == null) doneCnt++; else if (f.isDone()) { f.get(); doneCnt++; activeFuts0.set(i, null); } else break; } if (doneCnt == activeFuts0.size()) return; } }