/** @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); } } }
/** * 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); } } }); } } }