/**
* @param ctx Cache registry.
* @param implicit Implicit flag.
* @param implicitSingle Implicit with one key flag.
* @param concurrency Concurrency.
* @param isolation Isolation.
* @param timeout Timeout.
* @param invalidate Invalidation policy.
* @param syncCommit Synchronous commit flag.
* @param syncRollback Synchronous rollback flag.
* @param swapEnabled Whether to use swap storage.
* @param storeEnabled Whether to use read/write through.
*/
GridNearTxLocal(
GridCacheContext<K, V> ctx,
boolean implicit,
boolean implicitSingle,
GridCacheTxConcurrency concurrency,
GridCacheTxIsolation isolation,
long timeout,
boolean invalidate,
boolean syncCommit,
boolean syncRollback,
boolean swapEnabled,
boolean storeEnabled) {
super(
ctx,
ctx.versions().next(),
implicit,
implicitSingle,
concurrency,
isolation,
timeout,
invalidate,
swapEnabled,
storeEnabled);
assert ctx != null;
this.syncCommit = syncCommit;
this.syncRollback = syncRollback;
}
/** @param m Mapping. */
@SuppressWarnings({"unchecked"})
private void finish(GridDistributedTxMapping<K, V> m) {
GridRichNode n = m.node();
assert !m.empty();
GridNearTxFinishRequest req =
new GridNearTxFinishRequest<K, V>(
futId,
tx.xidVersion(),
tx.commitVersion(),
tx.threadId(),
commit,
tx.isInvalidate(),
m.explicitLock(),
tx.topologyVersion(),
null,
null,
null,
commit && tx.pessimistic() ? m.writes() : null,
tx.syncCommit() && commit || tx.syncRollback() && !commit);
// 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.
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);
}
}
}
/**
* @param entry Transaction entry.
* @param nodes Nodes.
*/
private void map(GridCacheTxEntry<K, V> entry, Collection<GridRichNode> nodes) {
GridRichNode primary = CU.primary0(cctx.affinity(entry.key(), nodes));
GridDistributedTxMapping<K, V> t = mappings.get(primary.id());
if (t == null) mappings.put(primary.id(), t = new GridDistributedTxMapping<K, V>(primary));
t.add(entry);
}
/** {@inheritDoc} */
@Override
public boolean onDone(GridCacheTx tx, Throwable err) {
if (initialized() && super.onDone(tx, err)) {
// Don't forget to clean up.
cctx.mvcc().removeFuture(this);
return true;
}
return false;
}
/**
* @param cctx Context.
* @param tx Transaction.
* @param commit Commit flag.
*/
public GridNearTxFinishFuture(
GridCacheContext<K, V> cctx, GridNearTxLocal<K, V> tx, boolean commit) {
super(cctx.kernalContext(), F.<GridCacheTx>identityReducer(tx));
assert cctx != null;
this.cctx = cctx;
this.tx = tx;
this.commit = commit;
mappings = tx.mappings();
futId = GridUuid.randomUuid();
log = U.logger(ctx, logRef, GridNearTxFinishFuture.class);
}
/** @param ctx Context. */
public GridNearCache(GridCacheContext<K, V> ctx) {
super(ctx, ctx.config().getNearStartSize());
}
/** @param ctx Cache registry. */
public GridReplicatedCache(GridCacheContext<K, V> ctx) {
super(ctx, ctx.config().getStartSize());
}
/** @return DHT cache. */
private GridDhtCache<K, V> dht() {
return cctx.near().dht();
}
