@Override public void readFrom(StreamInput in) throws IOException { sizeInBytes = in.readVLong(); if (in.readBoolean()) { int size = in.readVInt(); fields = new ObjectLongHashMap<>(size); for (int i = 0; i < size; i++) { fields.put(in.readString(), in.readVLong()); } } }
@Override public void writeTo(StreamOutput out) throws IOException { out.writeVLong(sizeInBytes); if (fields == null) { out.writeBoolean(false); } else { out.writeBoolean(true); out.writeVInt(fields.size()); assert !fields.containsKey(null); final Object[] keys = fields.keys; final long[] values = fields.values; for (int i = 0; i < keys.length; i++) { if (keys[i] != null) { out.writeString((String) keys[i]); out.writeVLong(values[i]); } } } }
@Override public XContentBuilder toXContent(XContentBuilder builder, Params params) throws IOException { builder.startObject(Fields.COMPLETION); builder.byteSizeField(Fields.SIZE_IN_BYTES, Fields.SIZE, sizeInBytes); if (fields != null) { builder.startObject(Fields.FIELDS); assert !fields.containsKey(null); final Object[] keys = fields.keys; final long[] values = fields.values; for (int i = 0; i < keys.length; i++) { if (keys[i] != null) { builder.startObject((String) keys[i], XContentBuilder.FieldCaseConversion.NONE); builder.byteSizeField(Fields.SIZE_IN_BYTES, Fields.SIZE, values[i]); builder.endObject(); } } builder.endObject(); } builder.endObject(); return builder; }
public void add(CompletionStats completion) { if (completion == null) { return; } sizeInBytes += completion.getSizeInBytes(); if (completion.fields != null) { if (fields == null) { fields = completion.fields.clone(); } else { assert !completion.fields.containsKey(null); final Object[] keys = completion.fields.keys; final long[] values = completion.fields.values; for (int i = 0; i < keys.length; i++) { if (keys[i] != null) { fields.addTo((String) keys[i], values[i]); } } } } }
public boolean allocateUnassigned(RoutingAllocation allocation) { boolean changed = false; DiscoveryNodes nodes = allocation.nodes(); RoutingNodes routingNodes = allocation.routingNodes(); // First, handle primaries, they must find a place to be allocated on here final MetaData metaData = routingNodes.metaData(); RoutingNodes.UnassignedShards unassigned = routingNodes.unassigned(); unassigned.sort( new PriorityComparator() { @Override protected Settings getIndexSettings(String index) { IndexMetaData indexMetaData = metaData.index(index); return indexMetaData.getSettings(); } }); // sort for priority ordering Iterator<ShardRouting> unassignedIterator = unassigned.iterator(); while (unassignedIterator.hasNext()) { ShardRouting shard = unassignedIterator.next(); if (!shard.primary()) { continue; } // this is an API allocation, ignore since we know there is no data... if (!routingNodes .routingTable() .index(shard.index()) .shard(shard.id()) .primaryAllocatedPostApi()) { continue; } AsyncShardFetch<TransportNodesListGatewayStartedShards.NodeGatewayStartedShards> fetch = asyncFetchStarted.get(shard.shardId()); if (fetch == null) { fetch = new InternalAsyncFetch<>(logger, "shard_started", shard.shardId(), startedAction); asyncFetchStarted.put(shard.shardId(), fetch); } AsyncShardFetch.FetchResult<TransportNodesListGatewayStartedShards.NodeGatewayStartedShards> shardState = fetch.fetchData(nodes, metaData, allocation.getIgnoreNodes(shard.shardId())); if (shardState.hasData() == false) { logger.trace("{}: ignoring allocation, still fetching shard started state", shard); unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); continue; } shardState.processAllocation(allocation); IndexMetaData indexMetaData = metaData.index(shard.getIndex()); /** * Build a map of DiscoveryNodes to shard state number for the given shard. A state of -1 * means the shard does not exist on the node, where any shard state >= 0 is the state version * of the shard on that node's disk. * * <p>A shard on shared storage will return at least shard state 0 for all nodes, indicating * that the shard can be allocated to any node. */ ObjectLongHashMap<DiscoveryNode> nodesState = new ObjectLongHashMap<>(); for (TransportNodesListGatewayStartedShards.NodeGatewayStartedShards nodeShardState : shardState.getData().values()) { long version = nodeShardState.version(); // -1 version means it does not exists, which is what the API returns, and what we expect to logger.trace( "[{}] on node [{}] has version [{}] of shard", shard, nodeShardState.getNode(), version); nodesState.put(nodeShardState.getNode(), version); } int numberOfAllocationsFound = 0; long highestVersion = -1; final Map<DiscoveryNode, Long> nodesWithVersion = Maps.newHashMap(); assert !nodesState.containsKey(null); final Object[] keys = nodesState.keys; final long[] values = nodesState.values; Settings idxSettings = indexMetaData.settings(); for (int i = 0; i < keys.length; i++) { if (keys[i] == null) { continue; } DiscoveryNode node = (DiscoveryNode) keys[i]; long version = values[i]; // since we don't check in NO allocation, we need to double check here if (allocation.shouldIgnoreShardForNode(shard.shardId(), node.id())) { continue; } if (recoverOnAnyNode(idxSettings)) { numberOfAllocationsFound++; if (version > highestVersion) { highestVersion = version; } // We always put the node without clearing the map nodesWithVersion.put(node, version); } else if (version != -1) { numberOfAllocationsFound++; // If we've found a new "best" candidate, clear the // current candidates and add it if (version > highestVersion) { highestVersion = version; nodesWithVersion.clear(); nodesWithVersion.put(node, version); } else if (version == highestVersion) { // If the candidate is the same, add it to the // list, but keep the current candidate nodesWithVersion.put(node, version); } } } // Now that we have a map of nodes to versions along with the // number of allocations found (and not ignored), we need to sort // it so the node with the highest version is at the beginning List<DiscoveryNode> nodesWithHighestVersion = Lists.newArrayList(); nodesWithHighestVersion.addAll(nodesWithVersion.keySet()); CollectionUtil.timSort( nodesWithHighestVersion, new Comparator<DiscoveryNode>() { @Override public int compare(DiscoveryNode o1, DiscoveryNode o2) { return Long.compare(nodesWithVersion.get(o2), nodesWithVersion.get(o1)); } }); if (logger.isDebugEnabled()) { logger.debug( "[{}][{}] found {} allocations of {}, highest version: [{}]", shard.index(), shard.id(), numberOfAllocationsFound, shard, highestVersion); } if (logger.isTraceEnabled()) { StringBuilder sb = new StringBuilder("["); for (DiscoveryNode n : nodesWithHighestVersion) { sb.append("["); sb.append(n.getName()); sb.append("]"); sb.append(" -> "); sb.append(nodesWithVersion.get(n)); sb.append(", "); } sb.append("]"); logger.trace("{} candidates for allocation: {}", shard, sb.toString()); } // check if the counts meets the minimum set int requiredAllocation = 1; // if we restore from a repository one copy is more then enough if (shard.restoreSource() == null) { try { String initialShards = indexMetaData .settings() .get( INDEX_RECOVERY_INITIAL_SHARDS, settings.get(INDEX_RECOVERY_INITIAL_SHARDS, this.initialShards)); if ("quorum".equals(initialShards)) { if (indexMetaData.numberOfReplicas() > 1) { requiredAllocation = ((1 + indexMetaData.numberOfReplicas()) / 2) + 1; } } else if ("quorum-1".equals(initialShards) || "half".equals(initialShards)) { if (indexMetaData.numberOfReplicas() > 2) { requiredAllocation = ((1 + indexMetaData.numberOfReplicas()) / 2); } } else if ("one".equals(initialShards)) { requiredAllocation = 1; } else if ("full".equals(initialShards) || "all".equals(initialShards)) { requiredAllocation = indexMetaData.numberOfReplicas() + 1; } else if ("full-1".equals(initialShards) || "all-1".equals(initialShards)) { if (indexMetaData.numberOfReplicas() > 1) { requiredAllocation = indexMetaData.numberOfReplicas(); } } else { requiredAllocation = Integer.parseInt(initialShards); } } catch (Exception e) { logger.warn( "[{}][{}] failed to derived initial_shards from value {}, ignore allocation for {}", shard.index(), shard.id(), initialShards, shard); } } // not enough found for this shard, continue... if (numberOfAllocationsFound < requiredAllocation) { // if we are restoring this shard we still can allocate if (shard.restoreSource() == null) { // we can't really allocate, so ignore it and continue unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: not allocating, number_of_allocated_shards_found [{}], required_number [{}]", shard.index(), shard.id(), numberOfAllocationsFound, requiredAllocation); } } else if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: missing local data, will restore from [{}]", shard.index(), shard.id(), shard.restoreSource()); } continue; } Set<DiscoveryNode> throttledNodes = Sets.newHashSet(); Set<DiscoveryNode> noNodes = Sets.newHashSet(); for (DiscoveryNode discoNode : nodesWithHighestVersion) { RoutingNode node = routingNodes.node(discoNode.id()); if (node == null) { continue; } Decision decision = allocation.deciders().canAllocate(shard, node, allocation); if (decision.type() == Decision.Type.THROTTLE) { throttledNodes.add(discoNode); } else if (decision.type() == Decision.Type.NO) { noNodes.add(discoNode); } else { if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: allocating [{}] to [{}] on primary allocation", shard.index(), shard.id(), shard, discoNode); } // we found a match changed = true; // make sure we create one with the version from the recovered state routingNodes.initialize(new ShardRouting(shard, highestVersion), node.nodeId()); unassignedIterator.remove(); // found a node, so no throttling, no "no", and break out of the loop throttledNodes.clear(); noNodes.clear(); break; } } if (throttledNodes.isEmpty()) { // if we have a node that we "can't" allocate to, force allocation, since this is our master // data! if (!noNodes.isEmpty()) { DiscoveryNode discoNode = noNodes.iterator().next(); RoutingNode node = routingNodes.node(discoNode.id()); if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: forcing allocating [{}] to [{}] on primary allocation", shard.index(), shard.id(), shard, discoNode); } // we found a match changed = true; // make sure we create one with the version from the recovered state routingNodes.initialize(new ShardRouting(shard, highestVersion), node.nodeId()); unassignedIterator.remove(); } } else { if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: throttling allocation [{}] to [{}] on primary allocation", shard.index(), shard.id(), shard, throttledNodes); } // we are throttling this, but we have enough to allocate to this node, ignore it for now unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); } } if (!routingNodes.hasUnassigned()) { return changed; } // Now, handle replicas, try to assign them to nodes that are similar to the one the primary was // allocated on unassignedIterator = unassigned.iterator(); while (unassignedIterator.hasNext()) { ShardRouting shard = unassignedIterator.next(); if (shard.primary()) { continue; } // pre-check if it can be allocated to any node that currently exists, so we won't list the // store for it for nothing boolean canBeAllocatedToAtLeastOneNode = false; for (ObjectCursor<DiscoveryNode> cursor : nodes.dataNodes().values()) { RoutingNode node = routingNodes.node(cursor.value.id()); if (node == null) { continue; } // if we can't allocate it on a node, ignore it, for example, this handles // cases for only allocating a replica after a primary Decision decision = allocation.deciders().canAllocate(shard, node, allocation); if (decision.type() == Decision.Type.YES) { canBeAllocatedToAtLeastOneNode = true; break; } } if (!canBeAllocatedToAtLeastOneNode) { logger.trace("{}: ignoring allocation, can't be allocated on any node", shard); unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); continue; } AsyncShardFetch<TransportNodesListShardStoreMetaData.NodeStoreFilesMetaData> fetch = asyncFetchStore.get(shard.shardId()); if (fetch == null) { fetch = new InternalAsyncFetch<>(logger, "shard_store", shard.shardId(), storeAction); asyncFetchStore.put(shard.shardId(), fetch); } AsyncShardFetch.FetchResult<TransportNodesListShardStoreMetaData.NodeStoreFilesMetaData> shardStores = fetch.fetchData(nodes, metaData, allocation.getIgnoreNodes(shard.shardId())); if (shardStores.hasData() == false) { logger.trace("{}: ignoring allocation, still fetching shard stores", shard); unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); continue; // still fetching } shardStores.processAllocation(allocation); long lastSizeMatched = 0; DiscoveryNode lastDiscoNodeMatched = null; RoutingNode lastNodeMatched = null; boolean hasReplicaData = false; IndexMetaData indexMetaData = metaData.index(shard.getIndex()); for (Map.Entry<DiscoveryNode, TransportNodesListShardStoreMetaData.NodeStoreFilesMetaData> nodeStoreEntry : shardStores.getData().entrySet()) { DiscoveryNode discoNode = nodeStoreEntry.getKey(); TransportNodesListShardStoreMetaData.StoreFilesMetaData storeFilesMetaData = nodeStoreEntry.getValue().storeFilesMetaData(); logger.trace("{}: checking node [{}]", shard, discoNode); if (storeFilesMetaData == null) { // already allocated on that node... continue; } RoutingNode node = routingNodes.node(discoNode.id()); if (node == null) { continue; } // check if we can allocate on that node... // we only check for NO, since if this node is THROTTLING and it has enough "same data" // then we will try and assign it next time Decision decision = allocation.deciders().canAllocate(shard, node, allocation); if (decision.type() == Decision.Type.NO) { continue; } // if it is already allocated, we can't assign to it... if (storeFilesMetaData.allocated()) { continue; } if (!shard.primary()) { hasReplicaData |= storeFilesMetaData.iterator().hasNext(); ShardRouting primaryShard = routingNodes.activePrimary(shard); if (primaryShard != null) { assert primaryShard.active(); DiscoveryNode primaryNode = nodes.get(primaryShard.currentNodeId()); if (primaryNode != null) { TransportNodesListShardStoreMetaData.NodeStoreFilesMetaData primaryNodeFilesStore = shardStores.getData().get(primaryNode); if (primaryNodeFilesStore != null) { TransportNodesListShardStoreMetaData.StoreFilesMetaData primaryNodeStore = primaryNodeFilesStore.storeFilesMetaData(); if (primaryNodeStore != null && primaryNodeStore.allocated()) { long sizeMatched = 0; String primarySyncId = primaryNodeStore.syncId(); String replicaSyncId = storeFilesMetaData.syncId(); // see if we have a sync id we can make use of if (replicaSyncId != null && replicaSyncId.equals(primarySyncId)) { logger.trace( "{}: node [{}] has same sync id {} as primary", shard, discoNode.name(), replicaSyncId); lastNodeMatched = node; lastSizeMatched = Long.MAX_VALUE; lastDiscoNodeMatched = discoNode; } else { for (StoreFileMetaData storeFileMetaData : storeFilesMetaData) { String metaDataFileName = storeFileMetaData.name(); if (primaryNodeStore.fileExists(metaDataFileName) && primaryNodeStore.file(metaDataFileName).isSame(storeFileMetaData)) { sizeMatched += storeFileMetaData.length(); } } logger.trace( "{}: node [{}] has [{}/{}] bytes of re-usable data", shard, discoNode.name(), new ByteSizeValue(sizeMatched), sizeMatched); if (sizeMatched > lastSizeMatched) { lastSizeMatched = sizeMatched; lastDiscoNodeMatched = discoNode; lastNodeMatched = node; } } } } } } } } if (lastNodeMatched != null) { // we only check on THROTTLE since we checked before before on NO Decision decision = allocation.deciders().canAllocate(shard, lastNodeMatched, allocation); if (decision.type() == Decision.Type.THROTTLE) { if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: throttling allocation [{}] to [{}] in order to reuse its unallocated persistent store with total_size [{}]", shard.index(), shard.id(), shard, lastDiscoNodeMatched, new ByteSizeValue(lastSizeMatched)); } // we are throttling this, but we have enough to allocate to this node, ignore it for now unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); } else { if (logger.isDebugEnabled()) { logger.debug( "[{}][{}]: allocating [{}] to [{}] in order to reuse its unallocated persistent store with total_size [{}]", shard.index(), shard.id(), shard, lastDiscoNodeMatched, new ByteSizeValue(lastSizeMatched)); } // we found a match changed = true; routingNodes.initialize(shard, lastNodeMatched.nodeId()); unassignedIterator.remove(); } } else if (hasReplicaData == false) { // if we didn't manage to find *any* data (regardless of matching sizes), check if the // allocation // of the replica shard needs to be delayed, and if so, add it to the ignore unassigned list // note: we only care about replica in delayed allocation, since if we have an unassigned // primary it // will anyhow wait to find an existing copy of the shard to be allocated // note: the other side of the equation is scheduling a reroute in a timely manner, which // happens in the RoutingService long delay = shard .unassignedInfo() .getDelayAllocationExpirationIn(settings, indexMetaData.getSettings()); if (delay > 0) { logger.debug( "[{}][{}]: delaying allocation of [{}] for [{}]", shard.index(), shard.id(), shard, TimeValue.timeValueMillis(delay)); /** * mark it as changed, since we want to kick a publishing to schedule future allocation, * see {@link * org.elasticsearch.cluster.routing.RoutingService#clusterChanged(ClusterChangedEvent)}). */ changed = true; unassignedIterator.remove(); routingNodes.ignoredUnassigned().add(shard); } } } return changed; }