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* this work for additional information regarding copyright
* ownership. Elasticsearch licenses this file to you under
* the Apache License, Version 2.0 (the "License"); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing,
* software distributed under the License is distributed on an
* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
* KIND, either express or implied. See the License for the
* specific language governing permissions and limitations
* under the License.
*/
package org.elasticsearch.gateway.local;
import com.carrotsearch.hppc.ObjectLongOpenHashMap;
import com.carrotsearch.hppc.ObjectOpenHashSet;
import com.carrotsearch.hppc.cursors.ObjectCursor;
import com.carrotsearch.hppc.predicates.ObjectPredicate;
import com.google.common.collect.Maps;
import com.google.common.collect.Sets;
import org.elasticsearch.ExceptionsHelper;
import org.elasticsearch.cluster.metadata.IndexMetaData;
import org.elasticsearch.cluster.node.DiscoveryNode;
import org.elasticsearch.cluster.node.DiscoveryNodes;
import org.elasticsearch.cluster.routing.MutableShardRouting;
import org.elasticsearch.cluster.routing.RoutingNode;
import org.elasticsearch.cluster.routing.RoutingNodes;
import org.elasticsearch.cluster.routing.ShardRouting;
import org.elasticsearch.cluster.routing.allocation.FailedRerouteAllocation;
import org.elasticsearch.cluster.routing.allocation.RoutingAllocation;
import org.elasticsearch.cluster.routing.allocation.StartedRerouteAllocation;
import org.elasticsearch.cluster.routing.allocation.allocator.GatewayAllocator;
import org.elasticsearch.cluster.routing.allocation.decider.Decision;
import org.elasticsearch.common.component.AbstractComponent;
import org.elasticsearch.common.inject.Inject;
import org.elasticsearch.common.settings.Settings;
import org.elasticsearch.common.unit.ByteSizeValue;
import org.elasticsearch.common.unit.TimeValue;
import org.elasticsearch.common.util.concurrent.ConcurrentCollections;
import org.elasticsearch.gateway.local.state.shards.TransportNodesListGatewayStartedShards;
import org.elasticsearch.index.shard.ShardId;
import org.elasticsearch.index.store.StoreFileMetaData;
import org.elasticsearch.indices.store.TransportNodesListShardStoreMetaData;
import org.elasticsearch.transport.ConnectTransportException;
import java.util.*;
import java.util.concurrent.ConcurrentMap;
/**
*
*/
public class LocalGatewayAllocator extends AbstractComponent implements GatewayAllocator {
public static final String INDEX_RECOVERY_INITIAL_SHARDS = "index.recovery.initial_shards";
private final TransportNodesListGatewayStartedShards listGatewayStartedShards;
private final TransportNodesListShardStoreMetaData listShardStoreMetaData;
private final ConcurrentMap<ShardId, Map<DiscoveryNode, TransportNodesListShardStoreMetaData.StoreFilesMetaData>> cachedStores = ConcurrentCollections.newConcurrentMap();
private final ConcurrentMap<ShardId, ObjectLongOpenHashMap<DiscoveryNode>> cachedShardsState = ConcurrentCollections.newConcurrentMap();
private final TimeValue listTimeout;
private final String initialShards;
@Inject
public LocalGatewayAllocator(Settings settings,
TransportNodesListGatewayStartedShards listGatewayStartedShards, TransportNodesListShardStoreMetaData listShardStoreMetaData) {
super(settings);
this.listGatewayStartedShards = listGatewayStartedShards;
this.listShardStoreMetaData = listShardStoreMetaData;
this.listTimeout = componentSettings.getAsTime("list_timeout", TimeValue.timeValueSeconds(30));
this.initialShards = componentSettings.get("initial_shards", "quorum");
logger.debug("using initial_shards [{}], list_timeout [{}]", initialShards, listTimeout);
}
@Override
public void applyStartedShards(StartedRerouteAllocation allocation) {
for (ShardRouting shardRouting : allocation.startedShards()) {
cachedStores.remove(shardRouting.shardId());
cachedShardsState.remove(shardRouting.shardId());
}
}
@Override
public void applyFailedShards(FailedRerouteAllocation allocation) {
for (ShardRouting failedShard : allocation.failedShards()) {
cachedStores.remove(failedShard.shardId());
cachedShardsState.remove(failedShard.shardId());
}
}
@Override
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
Iterator<MutableShardRouting> unassignedIterator = routingNodes.unassigned().iterator();
while (unassignedIterator.hasNext()) {
MutableShardRouting 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;
}
ObjectLongOpenHashMap<DiscoveryNode> nodesState = buildShardStates(nodes, shard);
int numberOfAllocationsFound = 0;
long highestVersion = -1;
Set<DiscoveryNode> nodesWithHighestVersion = Sets.newHashSet();
final boolean[] states = nodesState.allocated;
final Object[] keys = nodesState.keys;
final long[] values = nodesState.values;
for (int i = 0; i < states.length; i++) {
if (!states[i]) {
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 (version != -1) {
numberOfAllocationsFound++;
if (highestVersion == -1) {
nodesWithHighestVersion.add(node);
highestVersion = version;
} else {
if (version > highestVersion) {
nodesWithHighestVersion.clear();
nodesWithHighestVersion.add(node);
highestVersion = version;
} else if (version == highestVersion) {
nodesWithHighestVersion.add(node);
}
}
}
}
// check if the counts meets the minimum set
int requiredAllocation = 1;
try {
IndexMetaData indexMetaData = routingNodes.metaData().index(shard.index());
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) {
// 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);
}
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
allocation.routingNodes().assign(new MutableShardRouting(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
allocation.routingNodes().assign(new MutableShardRouting(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 = routingNodes.unassigned().iterator();
while (unassignedIterator.hasNext()) {
MutableShardRouting shard = unassignedIterator.next();
// 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) {
continue;
}
Map<DiscoveryNode, TransportNodesListShardStoreMetaData.StoreFilesMetaData> shardStores = buildShardStores(nodes, shard);
long lastSizeMatched = 0;
DiscoveryNode lastDiscoNodeMatched = null;
RoutingNode lastNodeMatched = null;
for (Map.Entry<DiscoveryNode, TransportNodesListShardStoreMetaData.StoreFilesMetaData> nodeStoreEntry : shardStores.entrySet()) {
DiscoveryNode discoNode = nodeStoreEntry.getKey();
TransportNodesListShardStoreMetaData.StoreFilesMetaData storeFilesMetaData = nodeStoreEntry.getValue();
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()) {
MutableShardRouting primaryShard = routingNodes.activePrimary(shard);
if (primaryShard != null) {
assert primaryShard.active();
DiscoveryNode primaryNode = nodes.get(primaryShard.currentNodeId());
if (primaryNode != null) {
TransportNodesListShardStoreMetaData.StoreFilesMetaData primaryNodeStore = shardStores.get(primaryNode);
if (primaryNodeStore != null && primaryNodeStore.allocated()) {
long sizeMatched = 0;
for (StoreFileMetaData storeFileMetaData : storeFilesMetaData) {
if (primaryNodeStore.fileExists(storeFileMetaData.name()) && primaryNodeStore.file(storeFileMetaData.name()).isSame(storeFileMetaData)) {
sizeMatched += storeFileMetaData.length();
}
}
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.isTraceEnabled()) {
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;
allocation.routingNodes().assign(shard, lastNodeMatched.nodeId());
unassignedIterator.remove();
}
}
}
return changed;
}
private ObjectLongOpenHashMap<DiscoveryNode> buildShardStates(final DiscoveryNodes nodes, MutableShardRouting shard) {
ObjectLongOpenHashMap<DiscoveryNode> shardStates = cachedShardsState.get(shard.shardId());
ObjectOpenHashSet<String> nodeIds;
if (shardStates == null) {
shardStates = new ObjectLongOpenHashMap<>();
cachedShardsState.put(shard.shardId(), shardStates);
nodeIds = ObjectOpenHashSet.from(nodes.dataNodes().keys());
} else {
// clean nodes that have failed
shardStates.keys().removeAll(new ObjectPredicate<DiscoveryNode>() {
@Override
public boolean apply(DiscoveryNode node) {
return !nodes.nodeExists(node.id());
}
});
nodeIds = ObjectOpenHashSet.newInstance();
// we have stored cached from before, see if the nodes changed, if they have, go fetch again
for (ObjectCursor<DiscoveryNode> cursor : nodes.dataNodes().values()) {
DiscoveryNode node = cursor.value;
if (!shardStates.containsKey(node)) {
nodeIds.add(node.id());
}
}
}
if (nodeIds.isEmpty()) {
return shardStates;
}
String[] nodesIdsArray = nodeIds.toArray(String.class);
TransportNodesListGatewayStartedShards.NodesLocalGatewayStartedShards response = listGatewayStartedShards.list(shard.shardId(), nodesIdsArray, listTimeout).actionGet();
if (logger.isDebugEnabled()) {
if (response.failures().length > 0) {
StringBuilder sb = new StringBuilder(shard + ": failures when trying to list shards on nodes:");
for (int i = 0; i < response.failures().length; i++) {
Throwable cause = ExceptionsHelper.unwrapCause(response.failures()[i]);
if (cause instanceof ConnectTransportException) {
continue;
}
sb.append("\n -> ").append(response.failures()[i].getDetailedMessage());
}
logger.debug(sb.toString());
}
}
for (TransportNodesListGatewayStartedShards.NodeLocalGatewayStartedShards nodeShardState : response) {
// -1 version means it does not exists, which is what the API returns, and what we expect to
shardStates.put(nodeShardState.getNode(), nodeShardState.version());
}
return shardStates;
}
private Map<DiscoveryNode, TransportNodesListShardStoreMetaData.StoreFilesMetaData> buildShardStores(DiscoveryNodes nodes, MutableShardRouting shard) {
Map<DiscoveryNode, TransportNodesListShardStoreMetaData.StoreFilesMetaData> shardStores = cachedStores.get(shard.shardId());
ObjectOpenHashSet<String> nodesIds;
if (shardStores == null) {
shardStores = Maps.newHashMap();
cachedStores.put(shard.shardId(), shardStores);
nodesIds = ObjectOpenHashSet.from(nodes.dataNodes().keys());
} else {
nodesIds = ObjectOpenHashSet.newInstance();
// clean nodes that have failed
for (Iterator<DiscoveryNode> it = shardStores.keySet().iterator(); it.hasNext(); ) {
DiscoveryNode node = it.next();
if (!nodes.nodeExists(node.id())) {
it.remove();
}
}
for (ObjectCursor<DiscoveryNode> cursor : nodes.dataNodes().values()) {
DiscoveryNode node = cursor.value;
if (!shardStores.containsKey(node)) {
nodesIds.add(node.id());
}
}
}
if (!nodesIds.isEmpty()) {
String[] nodesIdsArray = nodesIds.toArray(String.class);
TransportNodesListShardStoreMetaData.NodesStoreFilesMetaData nodesStoreFilesMetaData = listShardStoreMetaData.list(shard.shardId(), false, nodesIdsArray, listTimeout).actionGet();
if (logger.isTraceEnabled()) {
if (nodesStoreFilesMetaData.failures().length > 0) {
StringBuilder sb = new StringBuilder(shard + ": failures when trying to list stores on nodes:");
for (int i = 0; i < nodesStoreFilesMetaData.failures().length; i++) {
Throwable cause = ExceptionsHelper.unwrapCause(nodesStoreFilesMetaData.failures()[i]);
if (cause instanceof ConnectTransportException) {
continue;
}
sb.append("\n -> ").append(nodesStoreFilesMetaData.failures()[i].getDetailedMessage());
}
logger.trace(sb.toString());
}
}
for (TransportNodesListShardStoreMetaData.NodeStoreFilesMetaData nodeStoreFilesMetaData : nodesStoreFilesMetaData) {
if (nodeStoreFilesMetaData.storeFilesMetaData() != null) {
shardStores.put(nodeStoreFilesMetaData.getNode(), nodeStoreFilesMetaData.storeFilesMetaData());
}
}
}
return shardStores;
}
}