/** @return Tuple with acknowledge information. */ private IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> acknowledgeData() { assert size > 0; Map<Integer, Long> cntrs = new HashMap<>(updateCntrs); IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> res = new IgniteBiTuple<>(cntrs, topVers); topVers = U.newHashSet(1); size = 0; return res; }
private static class AcknowledgeBuffer { /** */ private int size; /** */ @GridToStringInclude private Map<Integer, Long> updateCntrs = new HashMap<>(); /** */ @GridToStringInclude private Set<AffinityTopologyVersion> topVers = U.newHashSet(1); /** * @param batch Batch. * @return Non-null tuple if acknowledge should be sent to backups. */ @SuppressWarnings("unchecked") @Nullable synchronized IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> onAcknowledged( GridContinuousBatch batch) { size += batch.size(); Collection<CacheContinuousQueryEntry> entries = (Collection) batch.collect(); for (CacheContinuousQueryEntry e : entries) addEntry(e); return size >= BACKUP_ACK_THRESHOLD ? acknowledgeData() : null; } /** * @param e Entry. * @return Non-null tuple if acknowledge should be sent to backups. */ @Nullable synchronized IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> onAcknowledged( CacheContinuousQueryEntry e) { size++; addEntry(e); return size >= BACKUP_ACK_THRESHOLD ? acknowledgeData() : null; } /** @param e Entry. */ private void addEntry(CacheContinuousQueryEntry e) { topVers.add(e.topologyVersion()); Long cntr0 = updateCntrs.get(e.partition()); if (cntr0 == null || e.updateCounter() > cntr0) updateCntrs.put(e.partition(), e.updateCounter()); } /** @return Non-null tuple if acknowledge should be sent to backups. */ @Nullable synchronized IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> acknowledgeOnTimeout() { return size > 0 ? acknowledgeData() : null; } /** @return Tuple with acknowledge information. */ private IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> acknowledgeData() { assert size > 0; Map<Integer, Long> cntrs = new HashMap<>(updateCntrs); IgniteBiTuple<Map<Integer, Long>, Set<AffinityTopologyVersion>> res = new IgniteBiTuple<>(cntrs, topVers); topVers = U.newHashSet(1); size = 0; return res; } /** {@inheritDoc} */ @Override public String toString() { return S.toString(AcknowledgeBuffer.class, this); } }
/** * 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); }
/** {@inheritDoc} */ @SuppressWarnings({"MismatchedQueryAndUpdateOfCollection"}) @Nullable @Override public GridDhtPartitionMap update( @Nullable GridDhtPartitionExchangeId exchId, GridDhtPartitionFullMap partMap) { if (log.isDebugEnabled()) log.debug( "Updating full partition map [exchId=" + exchId + ", parts=" + fullMapString() + ']'); assert partMap != null; lock.writeLock().lock(); try { if (stopping) return null; if (exchId != null && lastExchangeId != null && lastExchangeId.compareTo(exchId) >= 0) { if (log.isDebugEnabled()) log.debug( "Stale exchange id for full partition map update (will ignore) [lastExchId=" + lastExchangeId + ", exchId=" + exchId + ']'); return null; } if (node2part != null && node2part.compareTo(partMap) >= 0) { if (log.isDebugEnabled()) log.debug( "Stale partition map for full partition map update (will ignore) [lastExchId=" + lastExchangeId + ", exchId=" + exchId + ", curMap=" + node2part + ", newMap=" + partMap + ']'); return null; } long updateSeq = this.updateSeq.incrementAndGet(); if (exchId != null) lastExchangeId = exchId; if (node2part != null) { for (GridDhtPartitionMap part : node2part.values()) { GridDhtPartitionMap newPart = partMap.get(part.nodeId()); // If for some nodes current partition has a newer map, // then we keep the newer value. if (newPart != null && newPart.updateSequence() < part.updateSequence()) { if (log.isDebugEnabled()) log.debug( "Overriding partition map in full update map [exchId=" + exchId + ", curPart=" + mapString(part) + ", newPart=" + mapString(newPart) + ']'); partMap.put(part.nodeId(), part); } } for (Iterator<UUID> it = partMap.keySet().iterator(); it.hasNext(); ) { UUID nodeId = it.next(); if (!cctx.discovery().alive(nodeId)) { if (log.isDebugEnabled()) log.debug( "Removing left node from full map update [nodeId=" + nodeId + ", partMap=" + partMap + ']'); it.remove(); } } } node2part = partMap; Map<Integer, Set<UUID>> p2n = new HashMap<>(cctx.affinity().partitions(), 1.0f); for (Map.Entry<UUID, GridDhtPartitionMap> e : partMap.entrySet()) { for (Integer p : e.getValue().keySet()) { Set<UUID> ids = p2n.get(p); if (ids == null) // Initialize HashSet to size 3 in anticipation that there won't be // more than 3 nodes per partitions. p2n.put(p, ids = U.newHashSet(3)); ids.add(e.getKey()); } } part2node = p2n; boolean changed = checkEvictions(updateSeq); consistencyCheck(); if (log.isDebugEnabled()) log.debug("Partition map after full update: " + fullMapString()); return changed ? localPartitionMap() : null; } finally { lock.writeLock().unlock(); } }
/** {@inheritDoc} */ @SuppressWarnings({"MismatchedQueryAndUpdateOfCollection"}) @Nullable @Override public GridDhtPartitionMap update( @Nullable GridDhtPartitionExchangeId exchId, GridDhtPartitionMap parts) { if (log.isDebugEnabled()) log.debug( "Updating single partition map [exchId=" + exchId + ", parts=" + mapString(parts) + ']'); if (!cctx.discovery().alive(parts.nodeId())) { if (log.isDebugEnabled()) log.debug( "Received partition update for non-existing node (will ignore) [exchId=" + exchId + ", parts=" + parts + ']'); return null; } lock.writeLock().lock(); try { if (stopping) return null; if (lastExchangeId != null && exchId != null && lastExchangeId.compareTo(exchId) > 0) { if (log.isDebugEnabled()) log.debug( "Stale exchange id for single partition map update (will ignore) [lastExchId=" + lastExchangeId + ", exchId=" + exchId + ']'); return null; } if (exchId != null) lastExchangeId = exchId; if (node2part == null) // Create invalid partition map. node2part = new GridDhtPartitionFullMap(); GridDhtPartitionMap cur = node2part.get(parts.nodeId()); if (cur != null && cur.updateSequence() >= parts.updateSequence()) { if (log.isDebugEnabled()) log.debug( "Stale update sequence for single partition map update (will ignore) [exchId=" + exchId + ", curSeq=" + cur.updateSequence() + ", newSeq=" + parts.updateSequence() + ']'); return null; } long updateSeq = this.updateSeq.incrementAndGet(); node2part = new GridDhtPartitionFullMap(node2part, updateSeq); boolean changed = false; if (cur == null || !cur.equals(parts)) changed = true; node2part.put(parts.nodeId(), parts); part2node = new HashMap<>(part2node); // Add new mappings. for (Integer p : parts.keySet()) { Set<UUID> ids = part2node.get(p); if (ids == null) // Initialize HashSet to size 3 in anticipation that there won't be // more than 3 nodes per partition. part2node.put(p, ids = U.newHashSet(3)); changed |= ids.add(parts.nodeId()); } // Remove obsolete mappings. if (cur != null) { for (Integer p : F.view(cur.keySet(), F0.notIn(parts.keySet()))) { Set<UUID> ids = part2node.get(p); if (ids != null) changed |= ids.remove(parts.nodeId()); } } changed |= checkEvictions(updateSeq); consistencyCheck(); if (log.isDebugEnabled()) log.debug("Partition map after single update: " + fullMapString()); return changed ? localPartitionMap() : null; } finally { lock.writeLock().unlock(); } }