/** @return Nodes to execute on. */
private Collection<ClusterNode> nodes() {
CacheMode cacheMode = cctx.config().getCacheMode();
switch (cacheMode) {
case LOCAL:
if (prj != null)
U.warn(
log,
"Ignoring query projection because it's executed over LOCAL cache "
+ "(only local node will be queried): "
+ this);
return Collections.singletonList(cctx.localNode());
case REPLICATED:
if (prj != null || partition() != null) return nodes(cctx, prj, partition());
return cctx.affinityNode()
? Collections.singletonList(cctx.localNode())
: Collections.singletonList(F.rand(nodes(cctx, null, partition())));
case PARTITIONED:
return nodes(cctx, prj, partition());
default:
throw new IllegalStateException("Unknown cache distribution mode: " + cacheMode);
}
}
/**
* @param cctx Cache context.
* @param prj Projection (optional).
* @return Collection of data nodes in provided projection (if any).
*/
private static Collection<ClusterNode> nodes(
final GridCacheContext<?, ?> cctx,
@Nullable final ClusterGroup prj,
@Nullable final Integer part) {
assert cctx != null;
final AffinityTopologyVersion topVer = cctx.affinity().affinityTopologyVersion();
Collection<ClusterNode> affNodes = CU.affinityNodes(cctx);
if (prj == null && part == null) return affNodes;
final Set<ClusterNode> owners =
part == null
? Collections.<ClusterNode>emptySet()
: new HashSet<>(cctx.topology().owners(part, topVer));
return F.view(
affNodes,
new P1<ClusterNode>() {
@Override
public boolean apply(ClusterNode n) {
return cctx.discovery().cacheAffinityNode(n, cctx.name())
&& (prj == null || prj.node(n.id()) != null)
&& (part == null || owners.contains(n));
}
});
}
/**
* @param cacheCtx Cache context.
* @throws IgniteCheckedException If failed.
*/
private void initTopology(GridCacheContext cacheCtx) throws IgniteCheckedException {
if (stopping(cacheCtx.cacheId())) return;
if (canCalculateAffinity(cacheCtx)) {
if (log.isDebugEnabled())
log.debug(
"Will recalculate affinity [locNodeId="
+ cctx.localNodeId()
+ ", exchId="
+ exchId
+ ']');
cacheCtx.affinity().calculateAffinity(exchId.topologyVersion(), discoEvt);
} else {
if (log.isDebugEnabled())
log.debug(
"Will request affinity from remote node [locNodeId="
+ cctx.localNodeId()
+ ", exchId="
+ exchId
+ ']');
// Fetch affinity assignment from remote node.
GridDhtAssignmentFetchFuture fetchFut =
new GridDhtAssignmentFetchFuture(
cacheCtx,
exchId.topologyVersion(),
CU.affinityNodes(cacheCtx, exchId.topologyVersion()));
fetchFut.init();
List<List<ClusterNode>> affAssignment = fetchFut.get();
if (log.isDebugEnabled())
log.debug(
"Fetched affinity from remote node, initializing affinity assignment [locNodeId="
+ cctx.localNodeId()
+ ", topVer="
+ exchId.topologyVersion()
+ ']');
if (affAssignment == null) {
affAssignment = new ArrayList<>(cacheCtx.affinity().partitions());
List<ClusterNode> empty = Collections.emptyList();
for (int i = 0; i < cacheCtx.affinity().partitions(); i++) affAssignment.add(empty);
}
cacheCtx.affinity().initializeAffinity(exchId.topologyVersion(), affAssignment);
}
}
/**
* @param p Partition.
* @param topVer Topology version ({@code -1} for all nodes).
* @param state Partition state.
* @param states Additional partition states.
* @return List of nodes for the partition.
*/
private List<ClusterNode> nodes(
int p,
AffinityTopologyVersion topVer,
GridDhtPartitionState state,
GridDhtPartitionState... states) {
Collection<UUID> allIds =
topVer.topologyVersion() > 0 ? F.nodeIds(CU.affinityNodes(cctx, topVer)) : null;
lock.readLock().lock();
try {
assert node2part != null && node2part.valid()
: "Invalid node-to-partitions map [topVer="
+ topVer
+ ", allIds="
+ allIds
+ ", node2part="
+ node2part
+ ", cache="
+ cctx.name()
+ ']';
Collection<UUID> nodeIds = part2node.get(p);
// Node IDs can be null if both, primary and backup, nodes disappear.
int size = nodeIds == null ? 0 : nodeIds.size();
if (size == 0) return Collections.emptyList();
List<ClusterNode> nodes = new ArrayList<>(size);
for (UUID id : nodeIds) {
if (topVer.topologyVersion() > 0 && !allIds.contains(id)) continue;
if (hasState(p, id, state, states)) {
ClusterNode n = cctx.discovery().node(id);
if (n != null && (topVer.topologyVersion() < 0 || n.order() <= topVer.topologyVersion()))
nodes.add(n);
}
}
return nodes;
} finally {
lock.readLock().unlock();
}
}
/** {@inheritDoc} */
@Override
public boolean onDone(AffinityTopologyVersion res, Throwable err) {
Map<Integer, Boolean> m = null;
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (cacheCtx.config().getTopologyValidator() != null && !CU.isSystemCache(cacheCtx.name())) {
if (m == null) m = new HashMap<>();
m.put(
cacheCtx.cacheId(),
cacheCtx.config().getTopologyValidator().validate(discoEvt.topologyNodes()));
}
}
cacheValidRes = m != null ? m : Collections.<Integer, Boolean>emptyMap();
cctx.cache().onExchangeDone(exchId.topologyVersion(), reqs, err);
cctx.exchange().onExchangeDone(this, err);
if (super.onDone(res, err) && !dummy && !forcePreload) {
if (log.isDebugEnabled())
log.debug(
"Completed partition exchange [localNode="
+ cctx.localNodeId()
+ ", exchange= "
+ this
+ ']');
initFut.onDone(err == null);
GridTimeoutObject timeoutObj = this.timeoutObj;
// Deschedule timeout object.
if (timeoutObj != null) cctx.kernalContext().timeout().removeTimeoutObject(timeoutObj);
if (exchId.isLeft()) {
for (GridCacheContext cacheCtx : cctx.cacheContexts())
cacheCtx.config().getAffinity().removeNode(exchId.nodeId());
}
return true;
}
return dummy;
}
/**
* @param fld Folder with files to match.
* @param ptrn Pattern to match against file name.
* @return Collection of matched files.
*/
public static List<VisorLogFile> matchedFiles(File fld, final String ptrn) {
List<VisorLogFile> files =
fileTree(
fld,
MAX_FOLDER_DEPTH,
new FileFilter() {
@Override
public boolean accept(File f) {
return !f.isHidden()
&& (f.isDirectory() || f.isFile() && f.getName().matches(ptrn));
}
});
Collections.sort(files, LAST_MODIFIED);
return files;
}
/**
* Finds all files in folder and in it's sub-tree of specified depth.
*
* @param file Starting folder
* @param maxDepth Depth of the tree. If 1 - just look in the folder, no sub-folders.
* @param filter file filter.
* @return List of found files.
*/
public static List<VisorLogFile> fileTree(File file, int maxDepth, @Nullable FileFilter filter) {
if (file.isDirectory()) {
File[] files = (filter == null) ? file.listFiles() : file.listFiles(filter);
if (files == null) return Collections.emptyList();
List<VisorLogFile> res = new ArrayList<>(files.length);
for (File f : files) {
if (f.isFile() && f.length() > 0) res.add(new VisorLogFile(f));
else if (maxDepth > 1) res.addAll(fileTree(f, maxDepth - 1, filter));
}
return res;
}
return F.asList(new VisorLogFile(file));
}
/** {@inheritDoc} */
@Override
protected IgniteConfiguration getConfiguration(String gridName) throws Exception {
IgniteConfiguration cfg = super.getConfiguration(gridName);
cfg.setPeerClassLoadingEnabled(false);
cfg.setDeploymentMode(depMode);
if (initGar) {
UriDeploymentSpi depSpi = new UriDeploymentSpi();
depSpi.setUriList(Collections.singletonList(garFile));
cfg.setDeploymentSpi(depSpi);
}
((TcpDiscoverySpi) cfg.getDiscoverySpi()).setHeartbeatFrequency(500);
return cfg;
}
private void init() {
ClusterNode node = nodes.poll();
GridCacheQueryFutureAdapter<?, ?, R> fut0 =
(GridCacheQueryFutureAdapter<?, ?, R>)
(node.isLocal()
? qryMgr.queryLocal(bean)
: qryMgr.queryDistributed(bean, Collections.singleton(node)));
fut0.listen(
new IgniteInClosure<IgniteInternalFuture<Collection<R>>>() {
@Override
public void apply(IgniteInternalFuture<Collection<R>> fut) {
try {
onDone(fut.get());
} catch (IgniteCheckedException e) {
if (F.isEmpty(nodes)) onDone(e);
else init();
}
}
});
fut = fut0;
}
/**
* Sets list of routers this client should connect to.
*
* @param routers List of routers.
*/
public void setRouters(Collection<String> routers) {
this.routers = routers != null ? routers : Collections.<String>emptySet();
}
/** @return Remaining node IDs. */
Collection<UUID> remaining() {
if (rmtIds == null) return Collections.emptyList();
return F.lose(rmtIds, true, rcvdIds);
}
/** @return Collection of keys that did not pass the filter. */
public Collection<IgniteTxKey> filterFailedKeys() {
return filterFailedKeys == null ? Collections.<IgniteTxKey>emptyList() : filterFailedKeys;
}
/** @return Owned values map. */
public Map<IgniteTxKey, CacheVersionedValue> ownedValues() {
return ownedVals == null
? Collections.<IgniteTxKey, CacheVersionedValue>emptyMap()
: Collections.unmodifiableMap(ownedVals);
}
/**
* Gets pending versions that are less than {@link #version()}.
*
* @return Pending versions.
*/
public Collection<GridCacheVersion> pending() {
return pending == null ? Collections.<GridCacheVersion>emptyList() : pending;
}
/**
* Grabs local events and detects if events was lost since last poll.
*
* @param ignite Target grid.
* @param evtOrderKey Unique key to take last order key from node local map.
* @param evtThrottleCntrKey Unique key to take throttle count from node local map.
* @param evtTypes Event types to collect.
* @param evtMapper Closure to map grid events to Visor data transfer objects.
* @return Collections of node events
*/
public static Collection<VisorGridEvent> collectEvents(
Ignite ignite,
String evtOrderKey,
String evtThrottleCntrKey,
final int[] evtTypes,
IgniteClosure<Event, VisorGridEvent> evtMapper) {
assert ignite != null;
assert evtTypes != null && evtTypes.length > 0;
ConcurrentMap<String, Long> nl = ignite.cluster().nodeLocalMap();
final long lastOrder = getOrElse(nl, evtOrderKey, -1L);
final long throttle = getOrElse(nl, evtThrottleCntrKey, 0L);
// When we first time arrive onto a node to get its local events,
// we'll grab only last those events that not older than given period to make sure we are
// not grabbing GBs of data accidentally.
final long notOlderThan = System.currentTimeMillis() - EVENTS_COLLECT_TIME_WINDOW;
// Flag for detecting gaps between events.
final AtomicBoolean lastFound = new AtomicBoolean(lastOrder < 0);
IgnitePredicate<Event> p =
new IgnitePredicate<Event>() {
/** */
private static final long serialVersionUID = 0L;
@Override
public boolean apply(Event e) {
// Detects that events were lost.
if (!lastFound.get() && (lastOrder == e.localOrder())) lastFound.set(true);
// Retains events by lastOrder, period and type.
return e.localOrder() > lastOrder
&& e.timestamp() > notOlderThan
&& F.contains(evtTypes, e.type());
}
};
Collection<Event> evts = ignite.events().localQuery(p);
// Update latest order in node local, if not empty.
if (!evts.isEmpty()) {
Event maxEvt = Collections.max(evts, EVTS_ORDER_COMPARATOR);
nl.put(evtOrderKey, maxEvt.localOrder());
}
// Update throttle counter.
if (!lastFound.get())
nl.put(evtThrottleCntrKey, throttle == 0 ? EVENTS_LOST_THROTTLE : throttle - 1);
boolean lost = !lastFound.get() && throttle == 0;
Collection<VisorGridEvent> res = new ArrayList<>(evts.size() + (lost ? 1 : 0));
if (lost) res.add(new VisorGridEventsLost(ignite.cluster().localNode().id()));
for (Event e : evts) {
VisorGridEvent visorEvt = evtMapper.apply(e);
if (visorEvt != null) res.add(visorEvt);
}
return res;
}
/**
* Sets list of servers this client should connect to.
*
* @param srvs List of servers.
*/
public void setServers(Collection<String> srvs) {
this.srvs = srvs != null ? srvs : Collections.<String>emptySet();
}
/**
* Updates value for single partition.
*
* @param p Partition.
* @param nodeId Node ID.
* @param state State.
* @param updateSeq Update sequence.
*/
@SuppressWarnings({"MismatchedQueryAndUpdateOfCollection"})
private void updateLocal(int p, UUID nodeId, GridDhtPartitionState state, long updateSeq) {
assert lock.isWriteLockedByCurrentThread();
assert nodeId.equals(cctx.nodeId());
// In case if node joins, get topology at the time of joining node.
ClusterNode oldest = CU.oldestAliveCacheServerNode(cctx.shared(), topVer);
assert oldest != null;
// If this node became the oldest node.
if (oldest.id().equals(cctx.nodeId())) {
long seq = node2part.updateSequence();
if (seq != updateSeq) {
if (seq > updateSeq) {
if (this.updateSeq.get() < seq) {
// Update global counter if necessary.
boolean b = this.updateSeq.compareAndSet(this.updateSeq.get(), seq + 1);
assert b
: "Invalid update sequence [updateSeq="
+ updateSeq
+ ", seq="
+ seq
+ ", curUpdateSeq="
+ this.updateSeq.get()
+ ", node2part="
+ node2part.toFullString()
+ ']';
updateSeq = seq + 1;
} else updateSeq = seq;
}
node2part.updateSequence(updateSeq);
}
}
GridDhtPartitionMap map = node2part.get(nodeId);
if (map == null)
node2part.put(
nodeId,
map =
new GridDhtPartitionMap(
nodeId,
updateSeq,
Collections.<Integer, GridDhtPartitionState>emptyMap(),
false));
map.updateSequence(updateSeq);
map.put(p, state);
Set<UUID> ids = part2node.get(p);
if (ids == null) part2node.put(p, ids = U.newHashSet(3));
ids.add(nodeId);
}
/**
* @param updateSeq Update sequence.
* @return Checks if any of the local partitions need to be evicted.
*/
private boolean checkEvictions(long updateSeq) {
assert lock.isWriteLockedByCurrentThread();
boolean changed = false;
UUID locId = cctx.nodeId();
for (GridDhtLocalPartition part : locParts.values()) {
GridDhtPartitionState state = part.state();
if (state.active()) {
int p = part.id();
List<ClusterNode> affNodes = cctx.affinity().nodes(p, topVer);
if (!affNodes.contains(cctx.localNode())) {
Collection<UUID> nodeIds = F.nodeIds(nodes(p, topVer, OWNING));
// If all affinity nodes are owners, then evict partition from local node.
if (nodeIds.containsAll(F.nodeIds(affNodes))) {
part.rent(false);
updateLocal(part.id(), locId, part.state(), updateSeq);
changed = true;
if (log.isDebugEnabled())
log.debug("Evicted local partition (all affinity nodes are owners): " + part);
} else {
int ownerCnt = nodeIds.size();
int affCnt = affNodes.size();
if (ownerCnt > affCnt) {
List<ClusterNode> sorted = new ArrayList<>(cctx.discovery().nodes(nodeIds));
// Sort by node orders in ascending order.
Collections.sort(sorted, CU.nodeComparator(true));
int diff = sorted.size() - affCnt;
for (int i = 0; i < diff; i++) {
ClusterNode n = sorted.get(i);
if (locId.equals(n.id())) {
part.rent(false);
updateLocal(part.id(), locId, part.state(), updateSeq);
changed = true;
if (log.isDebugEnabled())
log.debug(
"Evicted local partition (this node is oldest non-affinity node): " + part);
break;
}
}
}
}
}
}
}
return changed;
}
/** @return Map of versions to be verified. */
public Map<IgniteTxKey, GridCacheVersion> dhtVersions() {
return dhtVers == null ? Collections.<IgniteTxKey, GridCacheVersion>emptyMap() : dhtVers;
}
/**
* Starts activity.
*
* @throws IgniteInterruptedCheckedException If interrupted.
*/
public void init() throws IgniteInterruptedCheckedException {
if (isDone()) return;
if (init.compareAndSet(false, true)) {
if (isDone()) return;
try {
// Wait for event to occur to make sure that discovery
// will return corresponding nodes.
U.await(evtLatch);
assert discoEvt != null : this;
assert !dummy && !forcePreload : this;
ClusterNode oldest = CU.oldestAliveCacheServerNode(cctx, exchId.topologyVersion());
oldestNode.set(oldest);
startCaches();
// True if client node joined or failed.
boolean clientNodeEvt;
if (F.isEmpty(reqs)) {
int type = discoEvt.type();
assert type == EVT_NODE_JOINED || type == EVT_NODE_LEFT || type == EVT_NODE_FAILED
: discoEvt;
clientNodeEvt = CU.clientNode(discoEvt.eventNode());
} else {
assert discoEvt.type() == EVT_DISCOVERY_CUSTOM_EVT : discoEvt;
boolean clientOnlyStart = true;
for (DynamicCacheChangeRequest req : reqs) {
if (!req.clientStartOnly()) {
clientOnlyStart = false;
break;
}
}
clientNodeEvt = clientOnlyStart;
}
if (clientNodeEvt) {
ClusterNode node = discoEvt.eventNode();
// Client need to initialize affinity for local join event or for stated client caches.
if (!node.isLocal()) {
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (cacheCtx.isLocal()) continue;
GridDhtPartitionTopology top = cacheCtx.topology();
top.updateTopologyVersion(exchId, this, -1, stopping(cacheCtx.cacheId()));
if (cacheCtx.affinity().affinityTopologyVersion() == AffinityTopologyVersion.NONE) {
initTopology(cacheCtx);
top.beforeExchange(this);
} else
cacheCtx.affinity().clientEventTopologyChange(discoEvt, exchId.topologyVersion());
}
if (exchId.isLeft())
cctx.mvcc().removeExplicitNodeLocks(exchId.nodeId(), exchId.topologyVersion());
onDone(exchId.topologyVersion());
skipPreload = cctx.kernalContext().clientNode();
return;
}
}
if (cctx.kernalContext().clientNode()) {
skipPreload = true;
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (cacheCtx.isLocal()) continue;
GridDhtPartitionTopology top = cacheCtx.topology();
top.updateTopologyVersion(exchId, this, -1, stopping(cacheCtx.cacheId()));
}
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (cacheCtx.isLocal()) continue;
initTopology(cacheCtx);
}
if (oldestNode.get() != null) {
rmtNodes =
new ConcurrentLinkedQueue<>(
CU.aliveRemoteServerNodesWithCaches(cctx, exchId.topologyVersion()));
rmtIds = Collections.unmodifiableSet(new HashSet<>(F.nodeIds(rmtNodes)));
ready.set(true);
initFut.onDone(true);
if (log.isDebugEnabled()) log.debug("Initialized future: " + this);
sendPartitions();
} else onDone(exchId.topologyVersion());
return;
}
assert oldestNode.get() != null;
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (isCacheAdded(cacheCtx.cacheId(), exchId.topologyVersion())) {
if (cacheCtx
.discovery()
.cacheAffinityNodes(cacheCtx.name(), topologyVersion())
.isEmpty())
U.quietAndWarn(log, "No server nodes found for cache client: " + cacheCtx.namex());
}
cacheCtx.preloader().onExchangeFutureAdded();
}
List<String> cachesWithoutNodes = null;
if (exchId.isLeft()) {
for (String name : cctx.cache().cacheNames()) {
if (cctx.discovery().cacheAffinityNodes(name, topologyVersion()).isEmpty()) {
if (cachesWithoutNodes == null) cachesWithoutNodes = new ArrayList<>();
cachesWithoutNodes.add(name);
// Fire event even if there is no client cache started.
if (cctx.gridEvents().isRecordable(EventType.EVT_CACHE_NODES_LEFT)) {
Event evt =
new CacheEvent(
name,
cctx.localNode(),
cctx.localNode(),
"All server nodes have left the cluster.",
EventType.EVT_CACHE_NODES_LEFT,
0,
false,
null,
null,
null,
null,
false,
null,
false,
null,
null,
null);
cctx.gridEvents().record(evt);
}
}
}
}
if (cachesWithoutNodes != null) {
StringBuilder sb =
new StringBuilder(
"All server nodes for the following caches have left the cluster: ");
for (int i = 0; i < cachesWithoutNodes.size(); i++) {
String cache = cachesWithoutNodes.get(i);
sb.append('\'').append(cache).append('\'');
if (i != cachesWithoutNodes.size() - 1) sb.append(", ");
}
U.quietAndWarn(log, sb.toString());
U.quietAndWarn(log, "Must have server nodes for caches to operate.");
}
assert discoEvt != null;
assert exchId.nodeId().equals(discoEvt.eventNode().id());
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
GridClientPartitionTopology clientTop =
cctx.exchange().clearClientTopology(cacheCtx.cacheId());
long updSeq = clientTop == null ? -1 : clientTop.lastUpdateSequence();
// Update before waiting for locks.
if (!cacheCtx.isLocal())
cacheCtx
.topology()
.updateTopologyVersion(exchId, this, updSeq, stopping(cacheCtx.cacheId()));
}
// Grab all alive remote nodes with order of equal or less than last joined node.
rmtNodes =
new ConcurrentLinkedQueue<>(
CU.aliveRemoteServerNodesWithCaches(cctx, exchId.topologyVersion()));
rmtIds = Collections.unmodifiableSet(new HashSet<>(F.nodeIds(rmtNodes)));
for (Map.Entry<UUID, GridDhtPartitionsSingleMessage> m : singleMsgs.entrySet())
// If received any messages, process them.
onReceive(m.getKey(), m.getValue());
for (Map.Entry<UUID, GridDhtPartitionsFullMessage> m : fullMsgs.entrySet())
// If received any messages, process them.
onReceive(m.getKey(), m.getValue());
AffinityTopologyVersion topVer = exchId.topologyVersion();
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (cacheCtx.isLocal()) continue;
// Must initialize topology after we get discovery event.
initTopology(cacheCtx);
cacheCtx.preloader().updateLastExchangeFuture(this);
}
IgniteInternalFuture<?> partReleaseFut = cctx.partitionReleaseFuture(topVer);
// Assign to class variable so it will be included into toString() method.
this.partReleaseFut = partReleaseFut;
if (log.isDebugEnabled()) log.debug("Before waiting for partition release future: " + this);
while (true) {
try {
partReleaseFut.get(2 * cctx.gridConfig().getNetworkTimeout(), TimeUnit.MILLISECONDS);
break;
} catch (IgniteFutureTimeoutCheckedException ignored) {
// Print pending transactions and locks that might have led to hang.
dumpPendingObjects();
}
}
if (log.isDebugEnabled()) log.debug("After waiting for partition release future: " + this);
if (!F.isEmpty(reqs)) blockGateways();
if (exchId.isLeft())
cctx.mvcc().removeExplicitNodeLocks(exchId.nodeId(), exchId.topologyVersion());
IgniteInternalFuture<?> locksFut = cctx.mvcc().finishLocks(exchId.topologyVersion());
while (true) {
try {
locksFut.get(2 * cctx.gridConfig().getNetworkTimeout(), TimeUnit.MILLISECONDS);
break;
} catch (IgniteFutureTimeoutCheckedException ignored) {
U.warn(
log,
"Failed to wait for locks release future. "
+ "Dumping pending objects that might be the cause: "
+ cctx.localNodeId());
U.warn(log, "Locked entries:");
Map<IgniteTxKey, Collection<GridCacheMvccCandidate>> locks =
cctx.mvcc().unfinishedLocks(exchId.topologyVersion());
for (Map.Entry<IgniteTxKey, Collection<GridCacheMvccCandidate>> e : locks.entrySet())
U.warn(log, "Locked entry [key=" + e.getKey() + ", mvcc=" + e.getValue() + ']');
}
}
for (GridCacheContext cacheCtx : cctx.cacheContexts()) {
if (cacheCtx.isLocal()) continue;
// Notify replication manager.
GridCacheContext drCacheCtx =
cacheCtx.isNear() ? cacheCtx.near().dht().context() : cacheCtx;
if (drCacheCtx.isDrEnabled()) drCacheCtx.dr().beforeExchange(topVer, exchId.isLeft());
// Partition release future is done so we can flush the write-behind store.
cacheCtx.store().forceFlush();
// Process queued undeploys prior to sending/spreading map.
cacheCtx.preloader().unwindUndeploys();
GridDhtPartitionTopology top = cacheCtx.topology();
assert topVer.equals(top.topologyVersion())
: "Topology version is updated only in this class instances inside single ExchangeWorker thread.";
top.beforeExchange(this);
}
for (GridClientPartitionTopology top : cctx.exchange().clientTopologies()) {
top.updateTopologyVersion(exchId, this, -1, stopping(top.cacheId()));
top.beforeExchange(this);
}
} catch (IgniteInterruptedCheckedException e) {
onDone(e);
throw e;
} catch (Throwable e) {
U.error(
log,
"Failed to reinitialize local partitions (preloading will be stopped): " + exchId,
e);
onDone(e);
if (e instanceof Error) throw (Error) e;
return;
}
if (F.isEmpty(rmtIds)) {
onDone(exchId.topologyVersion());
return;
}
ready.set(true);
initFut.onDone(true);
if (log.isDebugEnabled()) log.debug("Initialized future: " + this);
// If this node is not oldest.
if (!oldestNode.get().id().equals(cctx.localNodeId())) sendPartitions();
else {
boolean allReceived = allReceived();
if (allReceived && replied.compareAndSet(false, true)) {
if (spreadPartitions()) onDone(exchId.topologyVersion());
}
}
scheduleRecheck();
} else assert false : "Skipped init future: " + this;
}
/**
* Collection of {@code 'host:port'} pairs representing remote grid servers used to establish
* initial connection to the grid. Once connection is established, Ignite will get a full view on
* grid topology and will be able to connect to any available remote node.
*
* <p>Note that only these addresses are used to perform topology updates in background and to
* detect Grid connectivity status.
*
* @return Collection of {@code 'host:port'} pairs representing remote grid servers.
* @see GridClient#connected()
*/
public Collection<String> getServers() {
return Collections.unmodifiableCollection(srvs);
}
/** Java client configuration. */
public class GridClientConfiguration {
/** Default client protocol. */
public static final GridClientProtocol DFLT_CLIENT_PROTOCOL = GridClientProtocol.TCP;
/** Default topology refresh frequency is 2 sec. */
public static final int DFLT_TOP_REFRESH_FREQ = 2000;
/** Default maximum time connection can be idle. */
public static final long DFLT_MAX_CONN_IDLE_TIME = 30000;
/** Default ping interval in milliseconds. */
public static final long DFLT_PING_INTERVAL = 5000;
/** Default ping timeout in milliseconds. */
public static final long DFLT_PING_TIMEOUT = 7000;
/** Default connect timeout in milliseconds. */
public static final int DFLT_CONNECT_TIMEOUT = 10000;
/** Default flag setting for TCP_NODELAY option. */
public static final boolean DFLT_TCP_NODELAY = true;
/** List of servers to connect to. */
private Collection<String> srvs = Collections.emptySet();
/** List of routers to connect to. */
private Collection<String> routers = Collections.emptySet();
/** Client protocol. */
private GridClientProtocol proto = DFLT_CLIENT_PROTOCOL;
/** Socket connect timeout. */
private int connectTimeout = DFLT_CONNECT_TIMEOUT;
/** TCP_NODELAY flag. */
private boolean tcpNoDelay = DFLT_TCP_NODELAY;
/** SSL context factory */
private GridSslContextFactory sslCtxFactory;
/** Flag indicating whether metrics cache is enabled. */
private boolean enableMetricsCache = true;
/** Flag indicating whether attributes cache is enabled. */
private boolean enableAttrsCache = true;
/** Flag indicating whether metrics should be automatically fetched. */
private boolean autoFetchMetrics = true;
/** Flag indicating whether attributes should be automatically fetched. */
private boolean autoFetchAttrs = true;
/** Topology refresh frequency. */
private long topRefreshFreq = DFLT_TOP_REFRESH_FREQ;
/** Max time of connection idleness. */
private long maxConnIdleTime = DFLT_MAX_CONN_IDLE_TIME;
/** Ping interval. */
private long pingInterval = DFLT_PING_INTERVAL;
/** Ping timeout. */
private long pingTimeout = DFLT_PING_TIMEOUT;
/** Default balancer. */
private GridClientLoadBalancer balancer = new GridClientRandomBalancer();
/** Collection of data configurations. */
private Map<String, GridClientDataConfiguration> dataCfgs = Collections.emptyMap();
/** Credentials. */
private SecurityCredentialsProvider credProvider;
/** Executor. */
private ExecutorService executor;
/** Marshaller. */
private GridClientMarshaller marshaller =
new GridClientOptimizedMarshaller(U.allPluginProviders());
/** Daemon flag. */
private boolean daemon;
/** Creates default configuration. */
public GridClientConfiguration() {
// No-op.
}
/**
* Copy constructor.
*
* @param cfg Configuration to be copied.
*/
public GridClientConfiguration(GridClientConfiguration cfg) {
// Preserve alphabetical order for maintenance;
autoFetchAttrs = cfg.isAutoFetchAttributes();
autoFetchMetrics = cfg.isAutoFetchMetrics();
balancer = cfg.getBalancer();
connectTimeout = cfg.getConnectTimeout();
credProvider = cfg.getSecurityCredentialsProvider();
enableAttrsCache = cfg.isEnableAttributesCache();
enableMetricsCache = cfg.isEnableMetricsCache();
executor = cfg.getExecutorService();
marshaller = cfg.getMarshaller();
maxConnIdleTime = cfg.getMaxConnectionIdleTime();
pingInterval = cfg.getPingInterval();
pingTimeout = cfg.getPingTimeout();
proto = cfg.getProtocol();
routers = cfg.getRouters();
srvs = cfg.getServers();
sslCtxFactory = cfg.getSslContextFactory();
tcpNoDelay = cfg.isTcpNoDelay();
topRefreshFreq = cfg.getTopologyRefreshFrequency();
daemon = cfg.isDaemon();
marshaller = cfg.getMarshaller();
setDataConfigurations(cfg.getDataConfigurations());
}
/**
* Creates properties-based configuration based on passed in properties.
*
* @param in Client configuration in properties format.
* @throws GridClientException If parsing configuration failed.
*/
public GridClientConfiguration(Properties in) throws GridClientException {
this("ignite.client", in);
}
/**
* Creates properties-based configuration.
*
* @param prefix Prefix for the client properties.
* @param in Properties map to load configuration from.
* @throws GridClientException If parsing configuration failed.
*/
public GridClientConfiguration(String prefix, Properties in) throws GridClientException {
load(prefix, in);
}
/**
* Collection of {@code 'host:port'} pairs representing remote grid servers used to establish
* initial connection to the grid. Once connection is established, Ignite will get a full view on
* grid topology and will be able to connect to any available remote node.
*
* <p>Note that only these addresses are used to perform topology updates in background and to
* detect Grid connectivity status.
*
* @return Collection of {@code 'host:port'} pairs representing remote grid servers.
* @see GridClient#connected()
*/
public Collection<String> getServers() {
return Collections.unmodifiableCollection(srvs);
}
/**
* Collection of {@code 'host:port'} pairs representing grid routers used to establish connection
* to the grid.
*
* <p>Addresses here could be owned by Routers as well as by individual Grid nodes. No additional
* connections will be made even if other Grid nodes are available.
*
* <p>This configuration mode is designated for cases when some Grid nodes are unavailable (due to
* security restrictions for example). So only few nodes acting as routers or dedicated router
* components used to access entire Grid.
*
* <p>This configuration parameter will not be used and direct connections to all grid nodes will
* be established if {@link #getServers()} return non-empty collection value.
*
* <p>Note that only these addresses are used to perform topology updates in background and to
* detect Grid connectivity status.
*
* @return Collection of {@code 'host:port'} pairs representing routers.
* @see GridClient#connected()
*/
public Collection<String> getRouters() {
return routers;
}
/**
* Sets list of servers this client should connect to.
*
* @param srvs List of servers.
*/
public void setServers(Collection<String> srvs) {
this.srvs = srvs != null ? srvs : Collections.<String>emptySet();
}
/**
* Sets list of routers this client should connect to.
*
* @param routers List of routers.
*/
public void setRouters(Collection<String> routers) {
this.routers = routers != null ? routers : Collections.<String>emptySet();
}
/**
* Gets protocol for communication between client and remote grid. Default is defined by {@link
* #DFLT_CLIENT_PROTOCOL} constant.
*
* @return Protocol for communication between client and remote grid.
*/
public GridClientProtocol getProtocol() {
return proto;
}
/**
* Sets protocol type that should be used in communication. Protocol type cannot be changed after
* client is created.
*
* @param proto Protocol type.
* @see GridClientProtocol
*/
public void setProtocol(GridClientProtocol proto) {
this.proto = proto;
}
/**
* Gets timeout for socket connect operation in milliseconds. If {@code 0} - then wait infinitely.
* Default is defined by {@link #DFLT_CONNECT_TIMEOUT} constant.
*
* @return Connect timeout in milliseconds.
*/
public int getConnectTimeout() {
return connectTimeout;
}
/**
* Gets flag indicating whether {@code TCP_NODELAY} flag should be enabled for outgoing
* connections. This flag reduces communication latency and in the majority of cases should be set
* to true. For more information, see {@link Socket#setTcpNoDelay(boolean)}
*
* <p>If not set, default value is {@link #DFLT_TCP_NODELAY}
*
* @return If {@code TCP_NODELAY} should be set on underlying sockets.
*/
public boolean isTcpNoDelay() {
return tcpNoDelay;
}
/**
* Sets whether {@code TCP_NODELAY} flag should be set on underlying socket connections.
*
* @param tcpNoDelay {@code True} if flag should be set.
*/
public void setTcpNoDelay(boolean tcpNoDelay) {
this.tcpNoDelay = tcpNoDelay;
}
/**
* Sets timeout for socket connect operation.
*
* @param connectTimeout Connect timeout in milliseconds.
*/
public void setConnectTimeout(int connectTimeout) {
this.connectTimeout = connectTimeout;
}
/**
* Gets a factory that should be used for SSL context creation. If it returns {@code null} then
* SSL is considered disabled.
*
* @return Factory instance.
* @see GridSslContextFactory
*/
public GridSslContextFactory getSslContextFactory() {
return sslCtxFactory;
}
/**
* Sets SSL context factory that will be used for creation of secure connections.
*
* @param sslCtxFactory Context factory.
*/
public void setSslContextFactory(GridSslContextFactory sslCtxFactory) {
this.sslCtxFactory = sslCtxFactory;
}
/**
* Default balancer to be used for computational client. It can be overridden for different
* compute instances. By default {@link GridClientRandomBalancer} is used.
*
* @return Default balancer to be used for computational client.
*/
public GridClientLoadBalancer getBalancer() {
return balancer;
}
/**
* Sets default compute balancer.
*
* @param balancer Balancer to use.
*/
public void setBalancer(GridClientLoadBalancer balancer) {
this.balancer = balancer;
}
/**
* Gets client credentials provider to authenticate with.
*
* @return Credentials provider.
*/
public SecurityCredentialsProvider getSecurityCredentialsProvider() {
return credProvider;
}
/**
* Sets client credentials provider used in authentication process.
*
* @param credProvider Client credentials provider.
*/
public void setSecurityCredentialsProvider(SecurityCredentialsProvider credProvider) {
this.credProvider = credProvider;
}
/**
* Gets a collection of data configurations specified by user.
*
* @return Collection of data configurations (possibly empty).
*/
public Collection<GridClientDataConfiguration> getDataConfigurations() {
return dataCfgs.values();
}
/**
* Sets data configurations.
*
* @param dataCfgs Data configurations.
*/
public void setDataConfigurations(Collection<? extends GridClientDataConfiguration> dataCfgs) {
this.dataCfgs = U.newHashMap(dataCfgs.size());
for (GridClientDataConfiguration dataCfg : dataCfgs)
this.dataCfgs.put(dataCfg.getName(), new GridClientDataConfiguration(dataCfg));
}
/**
* Gets data configuration for a cache with specified name.
*
* @param name Name of grid cache.
* @return Configuration or {@code null} if there is not configuration for specified name.
*/
public GridClientDataConfiguration getDataConfiguration(@Nullable String name) {
return dataCfgs.get(name);
}
/**
* Sets flag indicating whether node and cache metrics should be cached by client.
*
* @param enableMetricsCache {@code True} if cache should be enabled.
*/
public void setEnableMetricsCache(boolean enableMetricsCache) {
this.enableMetricsCache = enableMetricsCache;
}
/**
* Enables client to cache per-node and per-cache metrics internally. In memory sensitive
* environments, such as mobile platforms, caching metrics may be expensive and, hence, this
* parameter should be set to {@code false}.
*
* <p>Note that topology is refreshed automatically every {@link #getTopologyRefreshFrequency()}
* interval, and if {@link #isAutoFetchMetrics()} enabled then metrics will be updated with that
* frequency.
*
* <p>By default this value is {@code true} which means that metrics will be cached on the client
* side.
*
* @return {@code True} if metrics cache is enabled, {@code false} otherwise.
*/
public boolean isEnableMetricsCache() {
return enableMetricsCache;
}
/**
* Sets flag indicating whether node attributes should be cached by client.
*
* @param enableAttrsCache {@code True} if cache should be enabled.
*/
public void setEnableAttributesCache(boolean enableAttrsCache) {
this.enableAttrsCache = enableAttrsCache;
}
/**
* Enables client to cache per-node attributes internally. In memory sensitive environments, such
* as mobile platforms, caching node attributes may be expensive and, hence, this parameter should
* be set to {@code false}.
*
* <p>Note that node attributes are static and, if cached, there is no need to refresh them again.
* If {@link #isAutoFetchAttributes()} is enabled then attributes will be cached during client
* initialization.
*
* <p>By default this value is {@code true} which means that node attributes will be cached on the
* client side.
*
* @return {@code True} if attributes cache is enabled, {@code false} otherwise.
*/
public boolean isEnableAttributesCache() {
return enableAttrsCache;
}
/**
* Sets flag indicating whether node metrics should be fetched by client automatically.
*
* @param autoFetchMetrics {@code True} if metrics should be fetched.
*/
public void setAutoFetchMetrics(boolean autoFetchMetrics) {
this.autoFetchMetrics = autoFetchMetrics;
}
/**
* Allows client to fetch node metrics automatically with background topology refresh.
*
* <p>Note that this parameter will only affect auto-fetching of node metrics. Cache metrics still
* need to be fetched explicitly via {@link GridClientData#metrics()} or {@link
* GridClientData#metricsAsync()} methods.
*
* <p>By default this value is {@code true} which means that metrics will be fetched
* automatically.
*
* @return {@code true} if client should fetch metrics on topology refresh, {@code false}
* otherwise.
*/
public boolean isAutoFetchMetrics() {
return autoFetchMetrics;
}
/**
* Sets flag indicating whether node attributes should be fetched by client automatically.
*
* @param autoFetchAttrs {@code True} if attributes should be fetched.
*/
public void setAutoFetchAttributes(boolean autoFetchAttrs) {
this.autoFetchAttrs = autoFetchAttrs;
}
/**
* Allows client to fetch node attributes automatically with background topology refresh.
*
* <p>By default this value is {@code true} which means that attributes will be fetched
* automatically.
*
* @return {@code True} if client should fetch attributes once on topology refresh, {@code false}
* otherwise.
*/
public boolean isAutoFetchAttributes() {
return autoFetchAttrs;
}
/**
* Gets topology refresh frequency. Default is defined by {@link #DFLT_TOP_REFRESH_FREQ} constant.
*
* @return Topology refresh frequency.
*/
public long getTopologyRefreshFrequency() {
return topRefreshFreq;
}
/**
* Sets topology refresh frequency. If topology cache is enabled, grid topology will be refreshed
* every {@code topRefreshFreq} milliseconds.
*
* @param topRefreshFreq Topology refresh frequency in milliseconds.
*/
public void setTopologyRefreshFrequency(long topRefreshFreq) {
this.topRefreshFreq = topRefreshFreq;
}
/**
* Gets maximum amount of time that client connection can be idle before it is closed. Default is
* defined by {@link #DFLT_MAX_CONN_IDLE_TIME} constant.
*
* @return Maximum idle time in milliseconds.
*/
public long getMaxConnectionIdleTime() {
return maxConnIdleTime;
}
/**
* Sets maximum time in milliseconds which connection can be idle before it is closed by client.
*
* @param maxConnIdleTime Maximum time of connection idleness in milliseconds.
*/
public void setMaxConnectionIdleTime(long maxConnIdleTime) {
this.maxConnIdleTime = maxConnIdleTime;
}
/**
* Gets time interval in milliseconds between ping requests. Default is defined by {@link
* #DFLT_PING_INTERVAL} constant.
*
* <p>Ping requests used by {@link GridClientProtocol#TCP} protocol to detect network failures and
* half-opened sockets.
*
* @return Ping interval.
*/
public long getPingInterval() {
return pingInterval;
}
/**
* Sets ping interval in milliseconds.
*
* @param pingInterval Ping interval in milliseconds.
*/
public void setPingInterval(long pingInterval) {
this.pingInterval = pingInterval;
}
/**
* Gets ping timeout. Default is defined by {@link #DFLT_PING_TIMEOUT} constant.
*
* <p>Ping requests used by {@link GridClientProtocol#TCP} protocol to detect network failures and
* half-opened sockets. If no response received in period equal to this timeout than connection
* considered broken and closed.
*
* @return Ping timeout.
*/
public long getPingTimeout() {
return pingTimeout;
}
/**
* Sets ping timeout in milliseconds.
*
* @param pingTimeout Ping interval in milliseconds.
*/
public void setPingTimeout(long pingTimeout) {
this.pingTimeout = pingTimeout;
}
/**
* Gets {@link ExecutorService} where client could run asynchronous operations.
*
* <p>When using {@link GridClientProtocol#TCP} this executor should be able to serve at least
* {@code Runtime.getRuntime().availableProcessors()} parallel tasks.
*
* <p>Note that this executor will be automatically shut down when client get closed.
*
* @return {@link ExecutorService} instance to use.
*/
public ExecutorService getExecutorService() {
return executor;
}
/**
* Sets executor service.
*
* @param executor Executor service to use in client.
*/
public void setExecutorService(ExecutorService executor) {
this.executor = executor;
}
/**
* Gets the marshaller, that is used to communicate between client and server.
*
* <p>Options, that can be used out-of-the-box:
*
* <ul>
* <li>{@link GridClientOptimizedMarshaller} (default) - Ignite's optimized marshaller.
* <li>{@code GridClientPortableMarshaller} - Marshaller that supports portable objects.
* <li>{@link org.apache.ignite.internal.client.marshaller.jdk.GridClientJdkMarshaller} - JDK
* marshaller (not recommended).
* </ul>
*
* @return A marshaller to use.
*/
public GridClientMarshaller getMarshaller() {
return marshaller;
}
/**
* Sets the marshaller to use for communication.
*
* @param marshaller A marshaller to use.
*/
public void setMarshaller(GridClientMarshaller marshaller) {
this.marshaller = marshaller;
}
/**
* Load client configuration from the properties map.
*
* @param prefix Prefix for the client properties.
* @param in Properties map to load configuration from.
* @throws GridClientException If parsing configuration failed.
*/
public void load(String prefix, Properties in) throws GridClientException {
while (prefix.endsWith(".")) prefix = prefix.substring(0, prefix.length() - 1);
if (!prefix.isEmpty()) prefix += ".";
String balancer = in.getProperty(prefix + "balancer");
String connectTimeout = in.getProperty(prefix + "connectTimeout");
String cred = in.getProperty(prefix + "credentials");
String autoFetchMetrics = in.getProperty(prefix + "autoFetchMetrics");
String autoFetchAttrs = in.getProperty(prefix + "autoFetchAttributes");
String maxConnIdleTime = in.getProperty(prefix + "idleTimeout");
String proto = in.getProperty(prefix + "protocol");
String srvrs = in.getProperty(prefix + "servers");
String tcpNoDelay = in.getProperty(prefix + "tcp.noDelay");
String topRefreshFreq = in.getProperty(prefix + "topology.refresh");
String sslEnabled = in.getProperty(prefix + "ssl.enabled");
String sslProto = in.getProperty(prefix + "ssl.protocol", "TLS");
String sslKeyAlg = in.getProperty(prefix + "ssl.key.algorithm", "SunX509");
String keyStorePath = in.getProperty(prefix + "ssl.keystore.location");
String keyStorePwd = in.getProperty(prefix + "ssl.keystore.password");
String keyStoreType = in.getProperty(prefix + "ssl.keystore.type");
String trustStorePath = in.getProperty(prefix + "ssl.truststore.location");
String trustStorePwd = in.getProperty(prefix + "ssl.truststore.password");
String trustStoreType = in.getProperty(prefix + "ssl.truststore.type");
String dataCfgs = in.getProperty(prefix + "data.configurations");
setBalancer(resolveBalancer(balancer));
if (!F.isEmpty(connectTimeout)) setConnectTimeout(Integer.parseInt(connectTimeout));
if (!F.isEmpty(cred)) {
int idx = cred.indexOf(':');
if (idx >= 0 && idx < cred.length() - 1) {
setSecurityCredentialsProvider(
new SecurityCredentialsBasicProvider(
new SecurityCredentials(cred.substring(0, idx), cred.substring(idx + 1))));
} else {
setSecurityCredentialsProvider(
new SecurityCredentialsBasicProvider(new SecurityCredentials(null, null, cred)));
}
}
if (!F.isEmpty(autoFetchMetrics)) setAutoFetchMetrics(Boolean.parseBoolean(autoFetchMetrics));
if (!F.isEmpty(autoFetchAttrs)) setAutoFetchAttributes(Boolean.parseBoolean(autoFetchAttrs));
if (!F.isEmpty(maxConnIdleTime)) setMaxConnectionIdleTime(Integer.parseInt(maxConnIdleTime));
if (!F.isEmpty(proto)) setProtocol(GridClientProtocol.valueOf(proto));
if (!F.isEmpty(srvrs)) setServers(Arrays.asList(srvrs.replaceAll("\\s+", "").split(",")));
if (!F.isEmpty(tcpNoDelay)) setTcpNoDelay(Boolean.parseBoolean(tcpNoDelay));
if (!F.isEmpty(topRefreshFreq)) setTopologyRefreshFrequency(Long.parseLong(topRefreshFreq));
//
// SSL configuration section
//
if (!F.isEmpty(sslEnabled) && Boolean.parseBoolean(sslEnabled)) {
GridSslBasicContextFactory factory = new GridSslBasicContextFactory();
factory.setProtocol(F.isEmpty(sslProto) ? "TLS" : sslProto);
factory.setKeyAlgorithm(F.isEmpty(sslKeyAlg) ? "SunX509" : sslKeyAlg);
if (F.isEmpty(keyStorePath))
throw new IllegalArgumentException("SSL key store location is not specified.");
factory.setKeyStoreFilePath(keyStorePath);
if (keyStorePwd != null) factory.setKeyStorePassword(keyStorePwd.toCharArray());
factory.setKeyStoreType(F.isEmpty(keyStoreType) ? "jks" : keyStoreType);
if (F.isEmpty(trustStorePath))
factory.setTrustManagers(GridSslBasicContextFactory.getDisabledTrustManager());
else {
factory.setTrustStoreFilePath(trustStorePath);
if (trustStorePwd != null) factory.setTrustStorePassword(trustStorePwd.toCharArray());
factory.setTrustStoreType(F.isEmpty(trustStoreType) ? "jks" : trustStoreType);
}
setSslContextFactory(factory);
}
//
// Data configuration section
//
if (!F.isEmpty(dataCfgs)) {
String[] names = dataCfgs.replaceAll("\\s+", "").split(",");
Collection<GridClientDataConfiguration> list = new ArrayList<>();
for (String cfgName : names) {
if (F.isEmpty(cfgName)) continue;
String name = in.getProperty(prefix + "data." + cfgName + ".name");
String bal = in.getProperty(prefix + "data." + cfgName + ".balancer");
String aff = in.getProperty(prefix + "data." + cfgName + ".affinity");
GridClientDataConfiguration dataCfg = new GridClientDataConfiguration();
dataCfg.setName(F.isEmpty(name) ? null : name);
dataCfg.setBalancer(resolveBalancer(bal));
dataCfg.setAffinity(resolveAffinity(aff));
list.add(dataCfg);
}
setDataConfigurations(list);
}
}
/**
* Resolve load balancer from string definition.
*
* @param balancer Load balancer string definition.
* @return Resolved load balancer.
* @throws GridClientException If loading failed.
*/
private static GridClientLoadBalancer resolveBalancer(String balancer)
throws GridClientException {
if (F.isEmpty(balancer) || "random".equals(balancer)) return new GridClientRandomBalancer();
if ("roundrobin".equals(balancer)) return new GridClientRoundRobinBalancer();
return newInstance(GridClientLoadBalancer.class, balancer);
}
/**
* Resolve data affinity from string definition.
*
* @param affinity Data affinity string definition.
* @return Resolved data affinity.
* @throws GridClientException If loading failed.
*/
private static GridClientDataAffinity resolveAffinity(String affinity)
throws GridClientException {
if (F.isEmpty(affinity)) return null;
if ("partitioned".equals(affinity)) return new GridClientPartitionAffinity();
return newInstance(GridClientDataAffinity.class, affinity);
}
/**
* Constructs new instance of the specified class.
*
* @param exp Expected class for the new instance.
* @param clsName Class name to create new instance for.
* @param <T> Expected class type for the new instance.
* @return New instance of specified class.
* @throws GridClientException If loading failed.
*/
private static <T> T newInstance(Class<T> exp, String clsName) throws GridClientException {
Object obj;
try {
obj = Class.forName(clsName).newInstance();
}
// Catch all for convenience.
catch (Exception e) {
throw new GridClientException("Failed to create class instance: " + clsName, e);
}
return exp.cast(obj);
}
/**
* Set the daemon flag value. Communication threads will be created as daemons if this flag is
* set.
*
* @param daemon Daemon flag.
*/
public void setDaemon(boolean daemon) {
this.daemon = daemon;
}
/**
* Get the daemon flag.
*
* @return Daemon flag.
*/
public boolean isDaemon() {
return daemon;
}
}