/** {@inheritDoc} */ @Nullable @Override public Map<? extends GridComputeJob, GridNode> map( List<GridNode> subgrid, @Nullable GridBiTuple<Set<UUID>, A> arg) throws GridException { assert arg != null; assert arg.get1() != null; start = U.currentTimeMillis(); boolean debug = debugState(g); if (debug) logStart(g.log(), getClass(), start); Set<UUID> nodeIds = arg.get1(); Map<GridComputeJob, GridNode> map = U.newHashMap(nodeIds.size()); try { taskArg = arg.get2(); for (GridNode node : subgrid) if (nodeIds.contains(node.id())) map.put(job(taskArg), node); return map; } finally { if (debug) logMapped(g.log(), getClass(), map.values()); } }
/** * Maps list by node ID. * * @param subgrid Subgrid. * @return Map. */ private Map<UUID, GridNode> mapSubgrid(Collection<GridNode> subgrid) { Map<UUID, GridNode> res = U.newHashMap(subgrid.size()); for (GridNode node : subgrid) res.put(node.id(), node); return res; }
/** * Creates node predicate that evaluates to {@code true} for all provided nodes. Implementation * will make a defensive copy. * * @param nodes Optional grid nodes. If none provided - predicate will always return {@code * false}. */ public GridNodePredicate(@Nullable GridNode... nodes) { if (F.isEmpty(nodes)) ids = Collections.emptySet(); else if (nodes.length == 1) ids = Collections.singleton(nodes[0].id()); else { ids = new HashSet<>(nodes.length); for (GridNode n : nodes) ids.add(n.id()); } }
public Serializable execute() throws GridException { GridNode gridNode = GridFactory.getGrid().getLocalNode(); Serializable attribute = gridNode.getAttribute(""); System.out.println(nameOfPersonToSalute + ":" + (null == context)); for (String beanName : context.getBeanDefinitionNames()) { System.out.println(beanName); } return null; }
/** {@inheritDoc} */ @Override public Map<? extends GridComputeJob, GridNode> map(List<GridNode> subgrid, String arg) throws GridException { assert locNodeId != null; if (log.isInfoEnabled()) { log.info("Mapping jobs [subgrid=" + subgrid + ", arg=" + arg + ']'); } GridNode remoteNode = null; for (GridNode node : subgrid) { if (!node.id().equals(locNodeId)) { remoteNode = node; } } return Collections.singletonMap( new GridComputeJobAdapter(locNodeId) { /** */ @GridLocalNodeIdResource private UUID nodeId; /** {@inheritDoc} */ @SuppressWarnings("NakedNotify") @Override public Serializable execute() throws GridException { assert nodeId != null; if (!nodeId.equals(argument(0))) { try { synchronized (mux) { mux.notifyAll(); } Thread.sleep(Integer.MAX_VALUE); } catch (InterruptedException e) { throw new GridComputeExecutionRejectedException( "Expected interruption during execution.", e); } } else { return "success"; } throw new GridComputeExecutionRejectedException( "Expected exception during execution."); } }, remoteNode); }
/** * @param cctx Context. * @param tx Transaction. * @param failedNodeId ID of failed node started transaction. */ @SuppressWarnings("ConstantConditions") public GridCachePessimisticCheckCommittedTxFuture( GridCacheContext<K, V> cctx, GridCacheTxEx<K, V> tx, UUID failedNodeId) { super(cctx.kernalContext(), new SingleReducer<K, V>()); this.cctx = cctx; this.tx = tx; this.failedNodeId = failedNodeId; log = U.logger(ctx, logRef, GridCacheOptimisticCheckPreparedTxFuture.class); nodes = new GridLeanMap<>(); for (GridNode node : CU.allNodes(cctx, tx.topologyVersion())) nodes.put(node.id(), node); }
/** @param e Node left exception. */ void onResult(GridTopologyException e) { if (isDone()) return; if (rcvRes.compareAndSet(false, true)) { if (log.isDebugEnabled()) log.debug( "Remote node left grid while sending or waiting for reply (will fail): " + this); if (tx != null) tx.removeMapping(node.id()); // Primary node left the grid, so fail the future. GridNearLockFuture.this.onDone(newTopologyException(e, node.id())); onDone(true); } }
/** {@inheritDoc} */ @Override public Map<? extends GridComputeJob, GridNode> map(List<GridNode> subgrid, Integer arg) throws GridException { assert taskSes != null; assert arg != null; assert arg > 0; Map<GridSessionLoadTestJob, GridNode> map = new HashMap<>(subgrid.size()); Iterator<GridNode> iter = subgrid.iterator(); Random rnd = new Random(); params = new HashMap<>(arg); Collection<UUID> assigned = new ArrayList<>(subgrid.size()); for (int i = 0; i < arg; i++) { // Recycle iterator. if (!iter.hasNext()) iter = subgrid.iterator(); String paramName = UUID.randomUUID().toString(); int paramVal = rnd.nextInt(); taskSes.setAttribute(paramName, paramVal); GridNode node = iter.next(); assigned.add(node.id()); map.put(new GridSessionLoadTestJob(paramName), node); params.put(paramName, paramVal); if (log.isDebugEnabled()) log.debug("Set session attribute [name=" + paramName + ", value=" + paramVal + ']'); } taskSes.setAttribute("nodes", assigned); return map; }
/** * @param mapping Mappings. * @param key Key to map. * @param topVer Topology version. * @return Near lock mapping. * @throws GridException If mapping for key failed. */ private GridNearLockMapping<K, V> map( K key, @Nullable GridNearLockMapping<K, V> mapping, long topVer) throws GridException { assert mapping == null || mapping.node() != null; GridNode primary = cctx.affinity().primary(key, topVer); if (cctx.discovery().node(primary.id()) == null) // If primary node left the grid before lock acquisition, fail the whole future. throw newTopologyException(null, primary.id()); if (inTx() && tx.groupLock() && !primary.isLocal()) throw new GridException( "Failed to start group lock transaction (local node is not primary for " + " key) [key=" + key + ", primaryNodeId=" + primary.id() + ']'); if (mapping == null || !primary.id().equals(mapping.node().id())) mapping = new GridNearLockMapping<>(primary, key); else mapping.addKey(key); return mapping; }
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); }
/** @throws Exception If failed. */ public void testKeyMappingOnComputeNode() throws Exception { try { cache = true; for (int i = 0; i < 4; i++) { nearOnly = i == 0; startGrid(i); } cache = false; Grid compute = startGrid(4); for (int i = 0; i < 100; i++) { GridNode node = compute.mapKeyToNode(null, i); assertFalse("For key: " + i, node.id().equals(compute.localNode().id())); assertFalse("For key: " + i, node.id().equals(grid(0).localNode().id())); } } finally { stopAllGrids(); } }
/** @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); }
/** * Creates node shadow adapter. * * @param node Node. */ GridDiscoveryNodeShadowAdapter(GridNode node) { assert node != null; created = U.currentTimeMillis(); id = node.id(); attrs = Collections.unmodifiableMap(node.attributes()); addrs = Collections.unmodifiableCollection(node.addresses()); hostNames = Collections.unmodifiableCollection(node.hostNames()); order = node.order(); lastMetrics = node.metrics(); daemon = "true".equalsIgnoreCase(this.<String>attribute(ATTR_DAEMON)); }
/** Initializes future. */ public void prepare() { if (log.isDebugEnabled()) log.debug("Checking if transaction was committed on remote nodes: " + tx); // Check local node first (local node can be a backup node for some part of this transaction). long originatingThreadId = tx.threadId(); if (tx instanceof GridCacheTxRemoteEx) originatingThreadId = ((GridCacheTxRemoteEx) tx).remoteThreadId(); GridCacheCommittedTxInfo<K, V> txInfo = cctx.tm().txCommitted(tx.nearXidVersion(), tx.eventNodeId(), originatingThreadId); if (txInfo != null) { onDone(txInfo); markInitialized(); return; } Collection<GridNode> checkNodes = CU.remoteNodes(cctx, tx.topologyVersion()); if (tx instanceof GridDhtTxRemote) { // If we got primary node failure and near node has not failed. if (tx.nodeId().equals(failedNodeId) && !tx.eventNodeId().equals(failedNodeId)) { nearCheck = true; GridNode nearNode = cctx.discovery().node(tx.eventNodeId()); if (nearNode == null) { // Near node failed, separate check prepared future will take care of it. onDone( new GridTopologyException( "Failed to check near transaction state (near node left grid): " + tx.eventNodeId())); return; } checkNodes = Collections.singletonList(nearNode); } } for (GridNode rmtNode : checkNodes) { // Skip left nodes and local node. if (rmtNode.id().equals(failedNodeId)) continue; /* * Send message to all cache nodes in the topology. */ MiniFuture fut = new MiniFuture(rmtNode.id()); GridCachePessimisticCheckCommittedTxRequest<K, V> req = new GridCachePessimisticCheckCommittedTxRequest<>( tx, originatingThreadId, futureId(), fut.futureId()); add(fut); try { cctx.io().send(rmtNode.id(), req); } catch (GridTopologyException ignored) { fut.onNodeLeft(); } catch (GridException e) { fut.onError(e); break; } } markInitialized(); }
/** {@inheritDoc} */ @Override public boolean apply(GridNode n) { assert n != null; return ids.contains(n.id()); }
/** * Processes lock request. * * @param nodeId Sender node ID. * @param msg Lock request. */ @SuppressWarnings({"unchecked", "ThrowableInstanceNeverThrown"}) private void processLockRequest(UUID nodeId, GridDistributedLockRequest<K, V> msg) { assert !nodeId.equals(locNodeId); List<byte[]> keys = msg.keyBytes(); int cnt = keys.size(); GridReplicatedTxRemote<K, V> tx = null; GridDistributedLockResponse res; ClassLoader ldr = null; try { ldr = ctx.deploy().globalLoader(); if (ldr != null) { res = new GridDistributedLockResponse(msg.version(), msg.futureId(), cnt); for (int i = 0; i < keys.size(); i++) { byte[] bytes = keys.get(i); K key = msg.keys().get(i); Collection<GridCacheMvccCandidate<K>> cands = msg.candidatesByIndex(i); if (bytes == null) continue; if (log.isDebugEnabled()) log.debug("Unmarshalled key: " + key); GridDistributedCacheEntry<K, V> entry = null; while (true) { try { entry = entryexx(key); // Handle implicit locks for pessimistic transactions. if (msg.inTx()) { tx = ctx.tm().tx(msg.version()); if (tx != null) { if (msg.txRead()) tx.addRead(key, bytes); else tx.addWrite(key, bytes); } else { tx = new GridReplicatedTxRemote<K, V>( nodeId, msg.threadId(), msg.version(), null, PESSIMISTIC, msg.isolation(), msg.isInvalidate(), msg.timeout(), key, bytes, msg.txRead(), ctx); tx = ctx.tm().onCreated(tx); if (tx == null || !ctx.tm().onStarted(tx)) throw new GridCacheTxRollbackException( "Failed to acquire lock " + "(transaction has been completed): " + msg.version()); } } // Add remote candidate before reordering. entry.addRemote( msg.nodeId(), null, msg.threadId(), msg.version(), msg.timeout(), tx != null && tx.ec(), tx != null, tx != null && tx.implicitSingle()); // Remote candidates for ordered lock queuing. entry.addRemoteCandidates( cands, msg.version(), msg.committedVersions(), msg.rolledbackVersions()); // Double-check in case if sender node left the grid. if (ctx.discovery().node(msg.nodeId()) == null) { if (log.isDebugEnabled()) log.debug( "Node requesting lock left grid (lock request will be ignored): " + msg); if (tx != null) tx.rollback(); return; } res.setCandidates( i, entry.localCandidates(), ctx.tm().committedVersions(msg.version()), ctx.tm().rolledbackVersions(msg.version())); res.addValueBytes( entry.rawGet(), msg.returnValue(i) ? entry.valueBytes(null) : null, ctx); // Entry is legit. break; } catch (GridCacheEntryRemovedException ignored) { assert entry.obsoleteVersion() != null : "Obsolete flag not set on removed entry: " + entry; if (log.isDebugEnabled()) log.debug( "Received entry removed exception (will retry on renewed entry): " + entry); if (tx != null) { tx.clearEntry(entry.key()); if (log.isDebugEnabled()) log.debug( "Cleared removed entry from remote transaction (will retry) [entry=" + entry + ", tx=" + tx + ']'); } } } } } else { String err = "Failed to acquire deployment class for message: " + msg; U.warn(log, err); res = new GridDistributedLockResponse(msg.version(), msg.futureId(), new GridException(err)); } } catch (GridCacheTxRollbackException e) { if (log.isDebugEnabled()) log.debug("Received lock request for completed transaction (will ignore): " + e); res = new GridDistributedLockResponse(msg.version(), msg.futureId(), e); } catch (GridException e) { String err = "Failed to unmarshal at least one of the keys for lock request message: " + msg; log.error(err, e); res = new GridDistributedLockResponse(msg.version(), msg.futureId(), new GridException(err, e)); if (tx != null) tx.rollback(); } catch (GridDistributedLockCancelledException ignored) { // Received lock request for cancelled lock. if (log.isDebugEnabled()) log.debug("Received lock request for canceled lock (will ignore): " + msg); if (tx != null) tx.rollback(); // Don't send response back. return; } GridNode node = ctx.discovery().node(msg.nodeId()); boolean releaseAll = false; if (node != null) { try { // Reply back to sender. ctx.io().send(node, res); } catch (GridException e) { U.error(log, "Failed to send message to node (did the node leave grid?): " + node.id(), e); releaseAll = ldr != null; } } // If sender left grid, release all locks acquired so far. else releaseAll = ldr != null; // Release all locks because sender node left grid. if (releaseAll) { for (K key : msg.keys()) { while (true) { GridDistributedCacheEntry<K, V> entry = peekexx(key); try { if (entry != null) entry.removeExplicitNodeLocks(msg.nodeId()); break; } catch (GridCacheEntryRemovedException ignore) { if (log.isDebugEnabled()) log.debug( "Attempted to remove lock on removed entity during failure " + "of replicated lock request handling (will retry): " + entry); } } } U.warn( log, "Sender node left grid in the midst of lock acquisition (locks will be released)."); } }
/** * @param nodeId Sender node ID. * @param msg Prepare request. */ @SuppressWarnings({"InstanceofCatchParameter"}) private void processPrepareRequest(UUID nodeId, GridDistributedTxPrepareRequest<K, V> msg) { assert nodeId != null; assert msg != null; GridReplicatedTxRemote<K, V> tx = null; GridDistributedTxPrepareResponse<K, V> res; try { tx = new GridReplicatedTxRemote<K, V>( ctx.deploy().globalLoader(), nodeId, msg.threadId(), msg.version(), msg.commitVersion(), msg.concurrency(), msg.isolation(), msg.isInvalidate(), msg.timeout(), msg.reads(), msg.writes(), ctx); tx = ctx.tm().onCreated(tx); if (tx == null || !ctx.tm().onStarted(tx)) throw new GridCacheTxRollbackException("Attempt to start a completed transaction: " + tx); // Prepare prior to reordering, so the pending locks added // in prepare phase will get properly ordered as well. tx.prepare(); // Add remote candidates and reorder completed and uncompleted versions. tx.addRemoteCandidates( msg.candidatesByKey(), msg.committedVersions(), msg.rolledbackVersions()); if (msg.concurrency() == EVENTUALLY_CONSISTENT) { if (log.isDebugEnabled()) log.debug("Committing transaction during remote prepare: " + tx); tx.commit(); if (log.isDebugEnabled()) log.debug("Committed transaction during remote prepare: " + tx); // Don't send response. return; } res = new GridDistributedTxPrepareResponse<K, V>(msg.version()); Map<K, Collection<GridCacheMvccCandidate<K>>> cands = tx.localCandidates(); // Add local candidates (completed version must be set below). res.candidates(cands); } catch (GridException e) { if (e instanceof GridCacheTxRollbackException) { if (log.isDebugEnabled()) log.debug("Transaction was rolled back before prepare completed: " + tx); } else if (e instanceof GridCacheTxOptimisticException) { if (log.isDebugEnabled()) log.debug("Optimistic failure for remote transaction (will rollback): " + tx); } else { U.error(log, "Failed to process prepare request: " + msg, e); } if (tx != null) // Automatically rollback remote transactions. tx.rollback(); // Don't send response. if (msg.concurrency() == EVENTUALLY_CONSISTENT) return; res = new GridDistributedTxPrepareResponse<K, V>(msg.version()); res.error(e); } // Add completed versions. res.completedVersions( ctx.tm().committedVersions(msg.version()), ctx.tm().rolledbackVersions(msg.version())); assert msg.concurrency() != EVENTUALLY_CONSISTENT; GridNode node = ctx.discovery().node(nodeId); if (node != null) { try { // Reply back to sender. ctx.io().send(node, res); } catch (GridException e) { U.error( log, "Failed to send tx response to node (did the node leave grid?) [node=" + node.id() + ", msg=" + res + ']', e); if (tx != null) tx.rollback(); } } }
/** @param res Result callback. */ void onResult(GridNearLockResponse<K, V> res) { if (rcvRes.compareAndSet(false, true)) { if (res.error() != null) { if (log.isDebugEnabled()) log.debug( "Finishing mini future with an error due to error in response [miniFut=" + this + ", res=" + res + ']'); // Fail. if (res.error() instanceof GridCacheLockTimeoutException) onDone(false); else onDone(res.error()); return; } int i = 0; long topVer = topSnapshot.get().topologyVersion(); for (K k : keys) { while (true) { GridNearCacheEntry<K, V> entry = cctx.near().entryExx(k, topVer); try { if (res.dhtVersion(i) == null) { onDone( new GridException( "Failed to receive DHT version from remote node " + "(will fail the lock): " + res)); return; } GridTuple3<GridCacheVersion, V, byte[]> oldValTup = valMap.get(entry.key()); V oldVal = entry.rawGet(); boolean hasOldVal = false; V newVal = res.value(i); byte[] newBytes = res.valueBytes(i); boolean readRecordable = false; if (retval) { readRecordable = cctx.events().isRecordable(EVT_CACHE_OBJECT_READ); if (readRecordable) hasOldVal = entry.hasValue(); } GridCacheVersion dhtVer = res.dhtVersion(i); GridCacheVersion mappedVer = res.mappedVersion(i); if (newVal == null) { if (oldValTup != null) { if (oldValTup.get1().equals(dhtVer)) { newVal = oldValTup.get2(); newBytes = oldValTup.get3(); } oldVal = oldValTup.get2(); } } // Lock is held at this point, so we can set the // returned value if any. entry.resetFromPrimary(newVal, newBytes, lockVer, dhtVer, node.id()); if (inTx() && implicitTx() && tx.onePhaseCommit()) { boolean pass = res.filterResult(i); tx.entry(k).filters(pass ? CU.<K, V>empty() : CU.<K, V>alwaysFalse()); } entry.readyNearLock( lockVer, mappedVer, res.committedVersions(), res.rolledbackVersions(), res.pending()); if (retval) { if (readRecordable) cctx.events() .addEvent( entry.partition(), entry.key(), tx, null, EVT_CACHE_OBJECT_READ, newVal, newVal != null || newBytes != null, oldVal, hasOldVal, CU.subjectId(tx, cctx)); cctx.cache().metrics0().onRead(false); } if (log.isDebugEnabled()) log.debug("Processed response for entry [res=" + res + ", entry=" + entry + ']'); break; // Inner while loop. } catch (GridCacheEntryRemovedException ignored) { if (log.isDebugEnabled()) log.debug("Failed to add candidates because entry was removed (will renew)."); // Replace old entry with new one. entries.set(i, (GridDistributedCacheEntry<K, V>) cctx.cache().entryEx(entry.key())); } catch (GridException e) { onDone(e); return; } } i++; } try { proceedMapping(mappings); } catch (GridException e) { onDone(e); } onDone(true); } }
/** * @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())); } } }
/** {@inheritDoc} */ @Override public String toString() { return S.toString(MiniFuture.class, this, "node", node.id(), "super", super.toString()); }
/** * Maps keys to nodes. Note that we can not simply group keys by nodes and send lock request as * such approach does not preserve order of lock acquisition. Instead, keys are split in * continuous groups belonging to one primary node and locks for these groups are acquired * sequentially. * * @param keys Keys. */ private void map(Iterable<? extends K> keys) { try { GridDiscoveryTopologySnapshot snapshot = topSnapshot.get(); assert snapshot != null; long topVer = snapshot.topologyVersion(); assert topVer > 0; if (CU.affinityNodes(cctx, topVer).isEmpty()) { onDone( new GridTopologyException( "Failed to map keys for near-only cache (all " + "partition nodes left the grid).")); return; } ConcurrentLinkedDeque8<GridNearLockMapping<K, V>> mappings = new ConcurrentLinkedDeque8<>(); // Assign keys to primary nodes. GridNearLockMapping<K, V> map = null; for (K key : keys) { GridNearLockMapping<K, V> updated = map(key, map, topVer); // If new mapping was created, add to collection. if (updated != map) mappings.add(updated); map = updated; } if (isDone()) { if (log.isDebugEnabled()) log.debug("Abandoning (re)map because future is done: " + this); return; } if (log.isDebugEnabled()) log.debug("Starting (re)map for mappings [mappings=" + mappings + ", fut=" + this + ']'); // Create mini futures. for (Iterator<GridNearLockMapping<K, V>> iter = mappings.iterator(); iter.hasNext(); ) { GridNearLockMapping<K, V> mapping = iter.next(); GridNode node = mapping.node(); Collection<K> mappedKeys = mapping.mappedKeys(); assert !mappedKeys.isEmpty(); GridNearLockRequest<K, V> req = null; Collection<K> distributedKeys = new ArrayList<>(mappedKeys.size()); boolean explicit = false; for (K key : mappedKeys) { while (true) { GridNearCacheEntry<K, V> entry = null; try { entry = cctx.near().entryExx(key, topVer); if (!cctx.isAll(entry.wrap(false), filter)) { if (log.isDebugEnabled()) log.debug("Entry being locked did not pass filter (will not lock): " + entry); onComplete(false, false); return; } // Removed exception may be thrown here. GridCacheMvccCandidate<K> cand = addEntry(topVer, entry, node.id()); if (isDone()) { if (log.isDebugEnabled()) log.debug( "Abandoning (re)map because future is done after addEntry attempt " + "[fut=" + this + ", entry=" + entry + ']'); return; } if (cand != null) { if (tx == null && !cand.reentry()) cctx.mvcc().addExplicitLock(threadId, cand, snapshot); GridTuple3<GridCacheVersion, V, byte[]> val = entry.versionedValue(); if (val == null) { GridDhtCacheEntry<K, V> dhtEntry = dht().peekExx(key); try { if (dhtEntry != null) val = dhtEntry.versionedValue(topVer); } catch (GridCacheEntryRemovedException ignored) { assert dhtEntry.obsolete() : " Got removed exception for non-obsolete entry: " + dhtEntry; if (log.isDebugEnabled()) log.debug( "Got removed exception for DHT entry in map (will ignore): " + dhtEntry); } } GridCacheVersion dhtVer = null; if (val != null) { dhtVer = val.get1(); valMap.put(key, val); } if (!cand.reentry()) { if (req == null) { req = new GridNearLockRequest<>( topVer, cctx.nodeId(), threadId, futId, lockVer, inTx(), implicitTx(), implicitSingleTx(), read, isolation(), isInvalidate(), timeout, syncCommit(), syncRollback(), mappedKeys.size(), inTx() ? tx.size() : mappedKeys.size(), inTx() ? tx.groupLockKey() : null, inTx() && tx.partitionLock(), inTx() ? tx.subjectId() : null); mapping.request(req); } distributedKeys.add(key); GridCacheTxEntry<K, V> writeEntry = tx != null ? tx.writeMap().get(key) : null; if (tx != null) tx.addKeyMapping(key, mapping.node()); req.addKeyBytes( key, node.isLocal() ? null : entry.getOrMarshalKeyBytes(), retval && dhtVer == null, dhtVer, // Include DHT version to match remote DHT entry. writeEntry, inTx() ? tx.entry(key).drVersion() : null, cctx); // Clear transfer required flag since we are sending message. if (writeEntry != null) writeEntry.transferRequired(false); } if (cand.reentry()) explicit = tx != null && !entry.hasLockCandidate(tx.xidVersion()); } else // Ignore reentries within transactions. explicit = tx != null && !entry.hasLockCandidate(tx.xidVersion()); if (explicit) tx.addKeyMapping(key, mapping.node()); break; } catch (GridCacheEntryRemovedException ignored) { assert entry.obsolete() : "Got removed exception on non-obsolete entry: " + entry; if (log.isDebugEnabled()) log.debug("Got removed entry in lockAsync(..) method (will retry): " + entry); } } // Mark mapping explicit lock flag. if (explicit) { boolean marked = tx != null && tx.markExplicit(node.id()); assert tx == null || marked; } } if (!distributedKeys.isEmpty()) mapping.distributedKeys(distributedKeys); else { assert mapping.request() == null; iter.remove(); } } cctx.mvcc().recheckPendingLocks(); proceedMapping(mappings); } catch (GridException ex) { onError(ex); } }
/** * Gets next near lock mapping and either acquires dht locks locally or sends near lock request to * remote primary node. * * @param mappings Queue of mappings. * @throws GridException If mapping can not be completed. */ private void proceedMapping(final ConcurrentLinkedDeque8<GridNearLockMapping<K, V>> mappings) throws GridException { GridNearLockMapping<K, V> map = mappings.poll(); // If there are no more mappings to process, complete the future. if (map == null) return; final GridNearLockRequest<K, V> req = map.request(); final Collection<K> mappedKeys = map.distributedKeys(); final GridNode node = map.node(); if (filter != null && filter.length != 0) req.filter(filter, cctx); if (node.isLocal()) { req.miniId(GridUuid.randomUuid()); if (log.isDebugEnabled()) log.debug("Before locally locking near request: " + req); GridFuture<GridNearLockResponse<K, V>> fut; if (CU.DHT_ENABLED) fut = dht().lockAllAsync(cctx.localNode(), req, filter); else { // Create dummy values for testing. GridNearLockResponse<K, V> res = new GridNearLockResponse<>(lockVer, futId, null, false, 1, null); res.addValueBytes(null, null, true, lockVer, lockVer, cctx); fut = new GridFinishedFuture<>(ctx, res); } // Add new future. add( new GridEmbeddedFuture<>( cctx.kernalContext(), fut, new C2<GridNearLockResponse<K, V>, Exception, Boolean>() { @Override public Boolean apply(GridNearLockResponse<K, V> res, Exception e) { if (CU.isLockTimeoutOrCancelled(e) || (res != null && CU.isLockTimeoutOrCancelled(res.error()))) return false; if (e != null) { onError(e); return false; } if (res == null) { onError(new GridException("Lock response is null for future: " + this)); return false; } if (res.error() != null) { onError(res.error()); return false; } if (log.isDebugEnabled()) log.debug( "Acquired lock for local DHT mapping [locId=" + cctx.nodeId() + ", mappedKeys=" + mappedKeys + ", fut=" + GridNearLockFuture.this + ']'); try { int i = 0; for (K k : mappedKeys) { while (true) { GridNearCacheEntry<K, V> entry = cctx.near().entryExx(k, req.topologyVersion()); try { GridTuple3<GridCacheVersion, V, byte[]> oldValTup = valMap.get(entry.key()); boolean hasBytes = entry.hasValue(); V oldVal = entry.rawGet(); V newVal = res.value(i); byte[] newBytes = res.valueBytes(i); GridCacheVersion dhtVer = res.dhtVersion(i); GridCacheVersion mappedVer = res.mappedVersion(i); // On local node don't record twice if DHT cache already recorded. boolean record = retval && oldValTup != null && oldValTup.get1().equals(dhtVer); if (newVal == null) { if (oldValTup != null) { if (oldValTup.get1().equals(dhtVer)) { newVal = oldValTup.get2(); newBytes = oldValTup.get3(); } oldVal = oldValTup.get2(); } } // Lock is held at this point, so we can set the // returned value if any. entry.resetFromPrimary(newVal, newBytes, lockVer, dhtVer, node.id()); entry.readyNearLock( lockVer, mappedVer, res.committedVersions(), res.rolledbackVersions(), res.pending()); if (inTx() && implicitTx() && tx.onePhaseCommit()) { boolean pass = res.filterResult(i); tx.entry(k).filters(pass ? CU.<K, V>empty() : CU.<K, V>alwaysFalse()); } if (record) { if (cctx.events().isRecordable(EVT_CACHE_OBJECT_READ)) cctx.events() .addEvent( entry.partition(), entry.key(), tx, null, EVT_CACHE_OBJECT_READ, newVal, newVal != null, oldVal, hasBytes, CU.subjectId(tx, cctx)); cctx.cache().metrics0().onRead(oldVal != null); } if (log.isDebugEnabled()) log.debug( "Processed response for entry [res=" + res + ", entry=" + entry + ']'); break; // Inner while loop. } catch (GridCacheEntryRemovedException ignored) { if (log.isDebugEnabled()) log.debug( "Failed to add candidates because entry was " + "removed (will renew)."); // Replace old entry with new one. entries.set( i, (GridDistributedCacheEntry<K, V>) cctx.cache().entryEx(entry.key())); } } i++; // Increment outside of while loop. } // Proceed and add new future (if any) before completing embedded future. proceedMapping(mappings); } catch (GridException ex) { onError(ex); return false; } return true; } })); } else { final MiniFuture fut = new MiniFuture(node, mappedKeys, mappings); req.miniId(fut.futureId()); add(fut); // Append new future. GridFuture<?> txSync = null; if (inTx()) txSync = cctx.tm().awaitFinishAckAsync(node.id(), tx.threadId()); if (txSync == null || txSync.isDone()) { try { if (log.isDebugEnabled()) log.debug("Sending near lock request [node=" + node.id() + ", req=" + req + ']'); cctx.io().send(node, req); } catch (GridTopologyException ex) { assert fut != null; fut.onResult(ex); } } else { txSync.listenAsync( new CI1<GridFuture<?>>() { @Override public void apply(GridFuture<?> t) { try { if (log.isDebugEnabled()) log.debug( "Sending near lock request [node=" + node.id() + ", req=" + req + ']'); cctx.io().send(node, req); } catch (GridTopologyException ex) { assert fut != null; fut.onResult(ex); } catch (GridException e) { onError(e); } } }); } } }
/** {@inheritDoc} */ @Override public void execute(@Nullable GridProjection prj) throws GridException { if (cb == null) throw new IllegalStateException("Mandatory local callback is not set for the query: " + this); if (prj == null) prj = ctx.grid(); prj = prj.forCache(ctx.name()); if (prj.nodes().isEmpty()) throw new GridTopologyException("Failed to execute query (projection is empty): " + this); GridCacheMode mode = ctx.config().getCacheMode(); if (mode == LOCAL || mode == REPLICATED) { Collection<GridNode> nodes = prj.nodes(); GridNode node = nodes.contains(ctx.localNode()) ? ctx.localNode() : F.rand(nodes); assert node != null; if (nodes.size() > 1 && !ctx.cache().isDrSystemCache()) { if (node.id().equals(ctx.localNodeId())) U.warn( log, "Continuous query for " + mode + " cache can be run only on local node. " + "Will execute query locally: " + this); else U.warn( log, "Continuous query for " + mode + " cache can be run only on single node. " + "Will execute query on remote node [qry=" + this + ", node=" + node + ']'); } prj = prj.forNode(node); } closeLock.lock(); try { if (routineId != null) throw new IllegalStateException("Continuous query can't be executed twice."); guard.block(); GridContinuousHandler hnd = new GridCacheContinuousQueryHandler<>(ctx.name(), topic, cb, filter, prjPred); routineId = ctx.kernalContext() .continuous() .startRoutine(hnd, bufSize, timeInterval, autoUnsubscribe, prj.predicate()) .get(); } finally { closeLock.unlock(); } }
/** @param m Mapping. */ private void finish(GridDistributedTxMapping<K, V> m) { GridNode n = m.node(); assert !m.empty(); GridNearTxFinishRequest<K, V> req = new GridNearTxFinishRequest<>( futId, tx.xidVersion(), tx.threadId(), commit, tx.isInvalidate(), m.explicitLock(), tx.topologyVersion(), null, null, null, tx.size(), commit && tx.pessimistic() ? m.writes() : null, commit && tx.pessimistic() ? tx.writeEntries() : null, commit ? tx.syncCommit() : tx.syncRollback(), tx.subjectId(), tx.taskNameHash()); // If this is the primary node for the keys. if (n.isLocal()) { req.miniId(GridUuid.randomUuid()); if (CU.DHT_ENABLED) { GridFuture<GridCacheTx> fut = commit ? dht().commitTx(n.id(), req) : dht().rollbackTx(n.id(), req); // Add new future. add(fut); } else // Add done future for testing. add(new GridFinishedFuture<GridCacheTx>(ctx)); } else { MiniFuture fut = new MiniFuture(m); req.miniId(fut.futureId()); add(fut); // Append new future. if (tx.pessimistic()) cctx.tm().beforeFinishRemote(n.id(), tx.threadId()); try { cctx.io().send(n, req); // If we don't wait for result, then mark future as done. if (!isSync() && !m.explicitLock()) fut.onDone(); } catch (GridTopologyException e) { // Remove previous mapping. mappings.remove(m.node().id()); fut.onResult(e); } catch (GridException e) { // Fail the whole thing. fut.onResult(e); } } }