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The Apache Cassandra Project develops a highly scalable second-generation distributed database, bringing together Dynamo's fully distributed design and Bigtable's ColumnFamily-based data model.
/*
* Licensed to the Apache Software Foundation (ASF) under one
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* distributed with this work for additional information
* regarding copyright ownership. The ASF 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.apache.cassandra.locator;
import com.google.common.collect.Iterables;
import org.apache.cassandra.db.ConsistencyLevel;
import org.apache.cassandra.db.Keyspace;
import org.apache.cassandra.db.PartitionPosition;
import org.apache.cassandra.dht.AbstractBounds;
import java.util.function.Predicate;
public abstract class ReplicaPlan>
{
protected final Keyspace keyspace;
protected final ConsistencyLevel consistencyLevel;
// The snapshot of the replication strategy when instantiating.
// It could be different than the one fetched from Keyspace later, e.g. RS altered during the query.
// Use the snapshot to calculate {@code blockFor} in order to have a consistent view of RS for the query.
protected final AbstractReplicationStrategy replicationStrategy;
// all nodes we will contact via any mechanism, including hints
// i.e., for:
// - reads, only live natural replicas
// ==> live.natural().subList(0, blockFor + initial speculate)
// - writes, includes all full, and any pending replicas, (and only any necessary transient ones to make up the difference)
// ==> liveAndDown.natural().filter(isFull) ++ liveAndDown.pending() ++ live.natural.filter(isTransient, req)
// - paxos, includes all live replicas (natural+pending), for this DC if SERIAL_LOCAL
// ==> live.all() (if consistencyLevel.isDCLocal(), then .filter(consistencyLevel.isLocal))
private final E contacts;
ReplicaPlan(Keyspace keyspace, AbstractReplicationStrategy replicationStrategy, ConsistencyLevel consistencyLevel, E contacts)
{
assert contacts != null;
this.keyspace = keyspace;
this.replicationStrategy = replicationStrategy;
this.consistencyLevel = consistencyLevel;
this.contacts = contacts;
}
public abstract int blockFor();
public E contacts() { return contacts; }
// TODO: should this semantically return true if we contain the endpoint, not the exact replica?
public boolean contacts(Replica replica) { return contacts.contains(replica); }
public Keyspace keyspace() { return keyspace; }
public AbstractReplicationStrategy replicationStrategy() { return replicationStrategy; }
public ConsistencyLevel consistencyLevel() { return consistencyLevel; }
public static abstract class ForRead> extends ReplicaPlan
{
// all nodes we *could* contacts; typically all natural replicas that are believed to be alive
// we will consult this collection to find uncontacted nodes we might contact if we doubt we will meet consistency level
private final E candidates;
ForRead(Keyspace keyspace, AbstractReplicationStrategy replicationStrategy, ConsistencyLevel consistencyLevel, E candidates, E contacts)
{
super(keyspace, replicationStrategy, consistencyLevel, contacts);
this.candidates = candidates;
}
public int blockFor() { return consistencyLevel.blockFor(replicationStrategy); }
public E candidates() { return candidates; }
public Replica firstUncontactedCandidate(Predicate extraPredicate)
{
return Iterables.tryFind(candidates(), r -> extraPredicate.test(r) && !contacts(r)).orNull();
}
public Replica lookup(InetAddressAndPort endpoint)
{
return candidates().byEndpoint().get(endpoint);
}
public String toString()
{
return "ReplicaPlan.ForRead [ CL: " + consistencyLevel + " keyspace: " + keyspace + " candidates: " + candidates + " contacts: " + contacts() + " ]";
}
}
public static class ForTokenRead extends ForRead
{
public ForTokenRead(Keyspace keyspace,
AbstractReplicationStrategy replicationStrategy,
ConsistencyLevel consistencyLevel,
EndpointsForToken candidates,
EndpointsForToken contacts)
{
super(keyspace, replicationStrategy, consistencyLevel, candidates, contacts);
}
ForTokenRead withContact(EndpointsForToken newContact)
{
return new ForTokenRead(keyspace, replicationStrategy, consistencyLevel, candidates(), newContact);
}
}
public static class ForRangeRead extends ForRead
{
final AbstractBounds range;
final int vnodeCount;
public ForRangeRead(Keyspace keyspace,
AbstractReplicationStrategy replicationStrategy,
ConsistencyLevel consistencyLevel,
AbstractBounds range,
EndpointsForRange candidates,
EndpointsForRange contact,
int vnodeCount)
{
super(keyspace, replicationStrategy, consistencyLevel, candidates, contact);
this.range = range;
this.vnodeCount = vnodeCount;
}
public AbstractBounds range() { return range; }
/**
* @return number of vnode ranges covered by the range
*/
public int vnodeCount() { return vnodeCount; }
ForRangeRead withContact(EndpointsForRange newContact)
{
return new ForRangeRead(keyspace, replicationStrategy, consistencyLevel, range, candidates(), newContact, vnodeCount);
}
}
public static abstract class ForWrite> extends ReplicaPlan
{
// TODO: this is only needed because of poor isolation of concerns elsewhere - we can remove it soon, and will do so in a follow-up patch
final E pending;
final E liveAndDown;
final E live;
ForWrite(Keyspace keyspace, AbstractReplicationStrategy replicationStrategy, ConsistencyLevel consistencyLevel, E pending, E liveAndDown, E live, E contact)
{
super(keyspace, replicationStrategy, consistencyLevel, contact);
this.pending = pending;
this.liveAndDown = liveAndDown;
this.live = live;
}
public int blockFor() { return consistencyLevel.blockForWrite(replicationStrategy, pending()); }
/** Replicas that a region of the ring is moving to; not yet ready to serve reads, but should receive writes */
public E pending() { return pending; }
/** Replicas that can participate in the write - this always includes all nodes (pending and natural) in all DCs, except for paxos LOCAL_QUORUM (which is local DC only) */
public E liveAndDown() { return liveAndDown; }
/** The live replicas present in liveAndDown, usually derived from FailureDetector.isReplicaAlive */
public E live() { return live; }
/** Calculate which live endpoints we could have contacted, but chose not to */
public E liveUncontacted() { return live().filter(r -> !contacts(r)); }
/** Test liveness, consistent with the upfront analysis done for this operation (i.e. test membership of live()) */
public boolean isAlive(Replica replica) { return live.endpoints().contains(replica.endpoint()); }
public Replica lookup(InetAddressAndPort endpoint)
{
return liveAndDown().byEndpoint().get(endpoint);
}
public String toString()
{
return "ReplicaPlan.ForWrite [ CL: " + consistencyLevel + " keyspace: " + keyspace + " liveAndDown: " + liveAndDown + " live: " + live + " contacts: " + contacts() + " ]";
}
}
public static class ForTokenWrite extends ForWrite
{
public ForTokenWrite(Keyspace keyspace, AbstractReplicationStrategy replicationStrategy, ConsistencyLevel consistencyLevel, EndpointsForToken pending, EndpointsForToken liveAndDown, EndpointsForToken live, EndpointsForToken contact)
{
super(keyspace, replicationStrategy, consistencyLevel, pending, liveAndDown, live, contact);
}
private ReplicaPlan.ForTokenWrite copy(ConsistencyLevel newConsistencyLevel, EndpointsForToken newContact)
{
return new ReplicaPlan.ForTokenWrite(keyspace, replicationStrategy, newConsistencyLevel, pending(), liveAndDown(), live(), newContact);
}
ForTokenWrite withConsistencyLevel(ConsistencyLevel newConsistencylevel) { return copy(newConsistencylevel, contacts()); }
public ForTokenWrite withContact(EndpointsForToken newContact) { return copy(consistencyLevel, newContact); }
}
public static class ForPaxosWrite extends ForWrite
{
final int requiredParticipants;
ForPaxosWrite(Keyspace keyspace, ConsistencyLevel consistencyLevel, EndpointsForToken pending, EndpointsForToken liveAndDown, EndpointsForToken live, EndpointsForToken contact, int requiredParticipants)
{
super(keyspace, keyspace.getReplicationStrategy(), consistencyLevel, pending, liveAndDown, live, contact);
this.requiredParticipants = requiredParticipants;
}
public int requiredParticipants() { return requiredParticipants; }
}
/**
* Used by AbstractReadExecutor, {Data,Digest}Resolver and ReadRepair to share a ReplicaPlan whose 'contacts' replicas
* we progressively modify via various forms of speculation (initial speculation, rr-read and rr-write)
*
* The internal reference is not volatile, despite being shared between threads. The initial reference provided to
* the constructor should be visible by the normal process of sharing data between threads (i.e. executors, etc)
* and any updates will either be seen or not seen, perhaps not promptly, but certainly not incompletely.
* The contained ReplicaPlan has only final member properties, so it cannot be seen partially initialised.
*/
public interface Shared, P extends ReplicaPlan>
{
/**
* add the provided replica to this shared plan, by updating the internal reference
*/
public void addToContacts(Replica replica);
/**
* get the shared replica plan, non-volatile (so maybe stale) but no risk of partially initialised
*/
public P get();
/**
* get the shared replica plan, non-volatile (so maybe stale) but no risk of partially initialised,
* but replace its 'contacts' with those provided
*/
public abstract P getWithContacts(E endpoints);
}
public static class SharedForTokenRead implements Shared
{
private ForTokenRead replicaPlan;
SharedForTokenRead(ForTokenRead replicaPlan) { this.replicaPlan = replicaPlan; }
public void addToContacts(Replica replica) { replicaPlan = replicaPlan.withContact(Endpoints.append(replicaPlan.contacts(), replica)); }
public ForTokenRead get() { return replicaPlan; }
public ForTokenRead getWithContacts(EndpointsForToken newContact) { return replicaPlan.withContact(newContact); }
}
public static class SharedForRangeRead implements Shared
{
private ForRangeRead replicaPlan;
SharedForRangeRead(ForRangeRead replicaPlan) { this.replicaPlan = replicaPlan; }
public void addToContacts(Replica replica) { replicaPlan = replicaPlan.withContact(Endpoints.append(replicaPlan.contacts(), replica)); }
public ForRangeRead get() { return replicaPlan; }
public ForRangeRead getWithContacts(EndpointsForRange newContact) { return replicaPlan.withContact(newContact); }
}
public static SharedForTokenRead shared(ForTokenRead replicaPlan) { return new SharedForTokenRead(replicaPlan); }
public static SharedForRangeRead shared(ForRangeRead replicaPlan) { return new SharedForRangeRead(replicaPlan); }
}