/**
* @param reads Read entries.
* @param writes Write entries.
*/
@SuppressWarnings({"unchecked"})
private void prepare(
Iterable<GridCacheTxEntry<K, V>> reads, Iterable<GridCacheTxEntry<K, V>> writes) {
Collection<GridRichNode> nodes = CU.allNodes(cctx);
// Assign keys to primary nodes.
for (GridCacheTxEntry<K, V> read : reads) map(read, nodes);
for (GridCacheTxEntry<K, V> write : writes) map(write, nodes);
// Create mini futures.
for (GridDistributedTxMapping<K, V> m : mappings.values()) finish(m);
}
/**
* @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 cctx Cache context.
* @param prj Projection (optional).
* @return Collection of data nodes in provided projection (if any).
*/
private static Collection<GridNode> nodes(
final GridCacheContext<?, ?> cctx, @Nullable final GridProjection prj) {
assert cctx != null;
return F.view(
CU.allNodes(cctx),
new P1<GridNode>() {
@Override
public boolean apply(GridNode n) {
GridCacheDistributionMode mode = U.distributionMode(n, cctx.name());
return (mode == PARTITIONED_ONLY || mode == NEAR_PARTITIONED)
&& (prj == null || prj.node(n.id()) != null);
}
});
}
/**
* Removes locks regardless of whether they are owned or not for given version and keys.
*
* @param ver Lock version.
* @param keys Keys.
*/
@SuppressWarnings({"unchecked"})
public void removeLocks(GridCacheVersion ver, Collection<? extends K> keys) {
if (keys.isEmpty()) return;
try {
Collection<GridRichNode> affNodes = null;
int keyCnt = -1;
Map<GridNode, GridNearUnlockRequest<K, V>> map = null;
for (K key : keys) {
// Send request to remove from remote nodes.
GridNearUnlockRequest<K, V> req = null;
while (true) {
GridDistributedCacheEntry<K, V> entry = peekExx(key);
try {
if (entry != null) {
GridCacheMvccCandidate<K> cand = entry.candidate(ver);
if (cand != null) {
if (affNodes == null) {
affNodes = CU.allNodes(ctx, cand.topologyVersion());
keyCnt = (int) Math.ceil((double) keys.size() / affNodes.size());
map = new HashMap<GridNode, GridNearUnlockRequest<K, V>>(affNodes.size());
}
GridRichNode primary = CU.primary0(ctx.affinity(key, affNodes));
if (!primary.isLocal()) {
req = map.get(primary);
if (req == null) {
map.put(primary, req = new GridNearUnlockRequest<K, V>(keyCnt));
req.version(ver);
}
}
// Remove candidate from local node first.
if (entry.removeLock(cand.version())) {
if (primary.isLocal()) {
dht.removeLocks(primary.id(), ver, F.asList(key), true);
assert req == null;
continue;
}
req.addKey(entry.key(), entry.getOrMarshalKeyBytes(), ctx);
}
}
}
break;
} catch (GridCacheEntryRemovedException ignored) {
if (log.isDebugEnabled())
log.debug(
"Attempted to remove lock from removed entry (will retry) [rmvVer="
+ ver
+ ", entry="
+ entry
+ ']');
}
}
}
if (map == null || map.isEmpty()) return;
Collection<GridCacheVersion> committed = ctx.tm().committedVersions(ver);
Collection<GridCacheVersion> rolledback = ctx.tm().rolledbackVersions(ver);
for (Map.Entry<GridNode, GridNearUnlockRequest<K, V>> mapping : map.entrySet()) {
GridNode n = mapping.getKey();
GridDistributedUnlockRequest<K, V> req = mapping.getValue();
if (!req.keyBytes().isEmpty()) {
req.completedVersions(committed, rolledback);
// We don't wait for reply to this message.
ctx.io().send(n, req);
}
}
} catch (GridException ex) {
U.error(log, "Failed to unlock the lock for keys: " + keys, ex);
}
}
/** {@inheritDoc} */
@Override
public void unlockAll(
Collection<? extends K> keys, GridPredicate<? super GridCacheEntry<K, V>>[] filter) {
if (keys.isEmpty()) return;
try {
GridCacheVersion ver = null;
Collection<GridRichNode> affNodes = null;
int keyCnt = -1;
Map<GridRichNode, GridNearUnlockRequest<K, V>> map = null;
Collection<K> locKeys = new LinkedList<K>();
GridCacheVersion obsoleteVer = ctx.versions().next();
for (K key : keys) {
while (true) {
GridDistributedCacheEntry<K, V> entry = peekExx(key);
if (entry == null || !ctx.isAll(entry.wrap(false), filter)) break; // While.
try {
GridCacheMvccCandidate<K> cand =
entry.candidate(ctx.nodeId(), Thread.currentThread().getId());
if (cand != null) {
ver = cand.version();
if (affNodes == null) {
affNodes = CU.allNodes(ctx, cand.topologyVersion());
keyCnt = (int) Math.ceil((double) keys.size() / affNodes.size());
map = new HashMap<GridRichNode, GridNearUnlockRequest<K, V>>(affNodes.size());
}
// Send request to remove from remote nodes.
GridRichNode primary = CU.primary0(ctx.affinity(key, affNodes));
GridNearUnlockRequest<K, V> req = map.get(primary);
if (req == null) {
map.put(primary, req = new GridNearUnlockRequest<K, V>(keyCnt));
req.version(ver);
}
// Remove candidate from local node first.
GridCacheMvccCandidate<K> rmv = entry.removeLock();
if (rmv != null) {
if (!rmv.reentry()) {
if (ver != null && !ver.equals(rmv.version()))
throw new GridException(
"Failed to unlock (if keys were locked separately, "
+ "then they need to be unlocked separately): "
+ keys);
if (!primary.isLocal()) {
assert req != null;
req.addKey(entry.key(), entry.getOrMarshalKeyBytes(), ctx);
} else locKeys.add(key);
if (log.isDebugEnabled()) log.debug("Removed lock (will distribute): " + rmv);
} else if (log.isDebugEnabled())
log.debug(
"Current thread still owns lock (or there are no other nodes)"
+ " [lock="
+ rmv
+ ", curThreadId="
+ Thread.currentThread().getId()
+ ']');
}
// Try to evict near entry if it's dht-mapped locally.
evictNearEntry(entry, obsoleteVer);
}
break;
} catch (GridCacheEntryRemovedException ignore) {
if (log.isDebugEnabled())
log.debug("Attempted to unlock removed entry (will retry): " + entry);
}
}
}
if (ver == null) return;
for (Map.Entry<GridRichNode, GridNearUnlockRequest<K, V>> mapping : map.entrySet()) {
GridRichNode n = mapping.getKey();
GridDistributedUnlockRequest<K, V> req = mapping.getValue();
if (n.isLocal()) dht.removeLocks(ctx.nodeId(), req.version(), locKeys, true);
else if (!req.keyBytes().isEmpty())
// We don't wait for reply to this message.
ctx.io().send(n, req);
}
} catch (GridException ex) {
U.error(log, "Failed to unlock the lock for keys: " + keys, ex);
}
}
/**
* @param e Transaction entry.
* @return {@code True} if entry is locally mapped as a primary or back up node.
*/
protected boolean isNearLocallyMapped(GridCacheEntryEx<K, V> e) {
return F.contains(ctx.affinity(e.key(), CU.allNodes(ctx)), ctx.localNode());
}
/**
* @param nodeId Reader to add.
* @param msgId Message ID.
* @return Future for all relevant transactions that were active at the time of adding reader, or
* {@code null} if reader was added
* @throws GridCacheEntryRemovedException If entry was removed.
*/
@Nullable
public GridFuture<Boolean> addReader(UUID nodeId, long msgId)
throws GridCacheEntryRemovedException {
// Don't add local node as reader.
if (cctx.nodeId().equals(nodeId)) return null;
GridNode node = cctx.discovery().node(nodeId);
// If remote node has no near cache, don't add it.
if (node == null || !U.hasNearCache(node, cctx.dht().near().name())) return null;
// If remote node is (primary?) or back up, don't add it as a reader.
if (U.nodeIds(cctx.affinity(partition(), CU.allNodes(cctx))).contains(nodeId)) return null;
boolean ret = false;
GridCacheMultiTxFuture<K, V> txFut;
Collection<GridCacheMvccCandidate<K>> cands = null;
synchronized (mux) {
checkObsolete();
txFut = this.txFut;
ReaderId reader = readerId(nodeId);
if (reader == null) {
reader = new ReaderId(nodeId, msgId);
readers = new LinkedList<ReaderId>(readers);
readers.add(reader);
// Seal.
readers = Collections.unmodifiableList(readers);
txFut = this.txFut = new GridCacheMultiTxFuture<K, V>(cctx);
cands = localCandidates();
ret = true;
} else {
long id = reader.messageId();
if (id < msgId) reader.messageId(msgId);
}
}
if (ret) {
assert txFut != null;
if (!F.isEmpty(cands)) {
for (GridCacheMvccCandidate<K> c : cands) {
GridCacheTxEx<K, V> tx = cctx.tm().<GridCacheTxEx<K, V>>tx(c.version());
if (tx != null) {
assert tx.local();
txFut.addTx(tx);
}
}
}
txFut.init();
if (!txFut.isDone()) {
txFut.listenAsync(
new CI1<GridFuture<?>>() {
@Override
public void apply(GridFuture<?> f) {
synchronized (mux) {
// Release memory.
GridDhtCacheEntry.this.txFut = null;
}
}
});
} else
// Release memory.
txFut = this.txFut = null;
}
return txFut;
}
