/** * @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 cctx Registry. * @param keys Keys to lock. * @param tx Transaction. * @param read Read flag. * @param retval Flag to return value or not. * @param timeout Lock acquisition timeout. * @param filter Filter. */ public GridNearLockFuture( GridCacheContext<K, V> cctx, Collection<? extends K> keys, @Nullable GridNearTxLocal<K, V> tx, boolean read, boolean retval, long timeout, GridPredicate<GridCacheEntry<K, V>>[] filter) { super(cctx.kernalContext(), CU.boolReducer()); assert cctx != null; assert keys != null; this.cctx = cctx; this.keys = keys; this.tx = tx; this.read = read; this.retval = retval; this.timeout = timeout; this.filter = filter; threadId = tx == null ? Thread.currentThread().getId() : tx.threadId(); lockVer = tx != null ? tx.xidVersion() : cctx.versions().next(); futId = GridUuid.randomUuid(); entries = new ArrayList<>(keys.size()); log = U.logger(ctx, logRef, GridNearLockFuture.class); if (timeout > 0) { timeoutObj = new LockTimeoutObject(); cctx.time().addTimeoutObject(timeoutObj); } valMap = new ConcurrentHashMap8<>(keys.size(), 1f); }
/** Clears values for this partition. */ private void clearAll() { GridCacheVersion clearVer = cctx.versions().next(); boolean swap = cctx.isSwapOrOffheapEnabled(); boolean rec = cctx.events().isRecordable(EVT_CACHE_REBALANCE_OBJECT_UNLOADED); Iterator<GridDhtCacheEntry> it = map.values().iterator(); GridCloseableIterator<Map.Entry<byte[], GridCacheSwapEntry>> swapIt = null; if (swap && GridQueryProcessor.isEnabled(cctx.config())) { // Indexing needs to unswap cache values. Iterator<GridDhtCacheEntry> unswapIt = null; try { swapIt = cctx.swap().iterator(id); unswapIt = unswapIterator(swapIt); } catch (Exception e) { U.error(log, "Failed to clear swap for evicted partition: " + this, e); } if (unswapIt != null) it = F.concat(it, unswapIt); } try { while (it.hasNext()) { GridDhtCacheEntry cached = it.next(); try { if (cached.clearInternal(clearVer, swap)) { map.remove(cached.key(), cached); if (!cached.isInternal()) { mapPubSize.decrement(); if (rec) cctx.events() .addEvent( cached.partition(), cached.key(), cctx.localNodeId(), (IgniteUuid) null, null, EVT_CACHE_REBALANCE_OBJECT_UNLOADED, null, false, cached.rawGet(), cached.hasValue(), null, null, null); } } } catch (IgniteCheckedException e) { U.error(log, "Failed to clear cache entry for evicted partition: " + cached, e); } } } finally { U.close(swapIt, log); } }