587 lines
23 KiB
C++
587 lines
23 KiB
C++
/*
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* Coordination.actor.cpp
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*
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* This source file is part of the FoundationDB open source project
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*
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* Copyright 2013-2018 Apple Inc. and the FoundationDB project authors
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#include "fdbserver/CoordinationInterface.h"
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#include "fdbserver/IKeyValueStore.h"
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#include "fdbserver/Knobs.h"
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#include "fdbserver/WorkerInterface.actor.h"
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#include "fdbserver/Status.h"
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#include "flow/ActorCollection.h"
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#include "flow/UnitTest.h"
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#include "flow/IndexedSet.h"
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#include "fdbclient/MonitorLeader.h"
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#include "flow/actorcompiler.h" // This must be the last #include.
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// This module implements coordinationServer() and the interfaces in CoordinationInterface.h
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struct GenerationRegVal {
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UniqueGeneration readGen, writeGen;
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Optional<Value> val;
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//To change this serialization, ProtocolVersion::GenerationRegVal must be updated, and downgrades need to be considered
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template <class Ar>
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void serialize(Ar& ar) {
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serializer(ar, readGen, writeGen, val);
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}
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};
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// The order of UIDs here must match the order in which makeWellKnownEndpoint is called.
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// UID WLTOKEN_CLIENTLEADERREG_GETLEADER( -1, 2 ); // from fdbclient/MonitorLeader.actor.cpp
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// UID WLTOKEN_CLIENTLEADERREG_OPENDATABASE( -1, 3 ); // from fdbclient/MonitorLeader.actor.cpp
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UID WLTOKEN_LEADERELECTIONREG_CANDIDACY( -1, 4 );
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UID WLTOKEN_LEADERELECTIONREG_ELECTIONRESULT( -1, 5 );
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UID WLTOKEN_LEADERELECTIONREG_LEADERHEARTBEAT( -1, 6 );
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UID WLTOKEN_LEADERELECTIONREG_FORWARD( -1, 7 );
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UID WLTOKEN_GENERATIONREG_READ( -1, 8 );
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UID WLTOKEN_GENERATIONREG_WRITE( -1, 9 );
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GenerationRegInterface::GenerationRegInterface( NetworkAddress remote )
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: read( Endpoint({remote}, WLTOKEN_GENERATIONREG_READ) ),
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write( Endpoint({remote}, WLTOKEN_GENERATIONREG_WRITE) )
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{
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}
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GenerationRegInterface::GenerationRegInterface( INetwork* local )
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{
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read.makeWellKnownEndpoint( WLTOKEN_GENERATIONREG_READ, TaskPriority::Coordination );
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write.makeWellKnownEndpoint( WLTOKEN_GENERATIONREG_WRITE, TaskPriority::Coordination );
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}
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LeaderElectionRegInterface::LeaderElectionRegInterface(NetworkAddress remote)
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: ClientLeaderRegInterface(remote),
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candidacy( Endpoint({remote}, WLTOKEN_LEADERELECTIONREG_CANDIDACY) ),
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electionResult( Endpoint({remote}, WLTOKEN_LEADERELECTIONREG_ELECTIONRESULT) ),
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leaderHeartbeat( Endpoint({remote}, WLTOKEN_LEADERELECTIONREG_LEADERHEARTBEAT) ),
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forward( Endpoint({remote}, WLTOKEN_LEADERELECTIONREG_FORWARD) )
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{
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}
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LeaderElectionRegInterface::LeaderElectionRegInterface(INetwork* local)
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: ClientLeaderRegInterface(local)
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{
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candidacy.makeWellKnownEndpoint( WLTOKEN_LEADERELECTIONREG_CANDIDACY, TaskPriority::Coordination );
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electionResult.makeWellKnownEndpoint( WLTOKEN_LEADERELECTIONREG_ELECTIONRESULT, TaskPriority::Coordination );
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leaderHeartbeat.makeWellKnownEndpoint( WLTOKEN_LEADERELECTIONREG_LEADERHEARTBEAT, TaskPriority::Coordination );
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forward.makeWellKnownEndpoint( WLTOKEN_LEADERELECTIONREG_FORWARD, TaskPriority::Coordination );
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}
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ServerCoordinators::ServerCoordinators( Reference<ClusterConnectionFile> cf )
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: ClientCoordinators(cf)
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{
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ClusterConnectionString cs = ccf->getConnectionString();
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for(auto s = cs.coordinators().begin(); s != cs.coordinators().end(); ++s) {
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leaderElectionServers.push_back( LeaderElectionRegInterface( *s ) );
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stateServers.push_back( GenerationRegInterface( *s ) );
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}
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}
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// The coordination server wants to create its key value store only if it is actually used
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struct OnDemandStore {
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public:
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OnDemandStore( std::string folder, UID myID ) : folder(folder), store(nullptr), myID(myID) {}
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~OnDemandStore() { if (store) store->close(); }
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IKeyValueStore* get() {
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if (!store) open();
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return store;
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}
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bool exists() {
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if (store)
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return true;
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return fileExists( joinPath(folder, "coordination-0.fdq") ) || fileExists( joinPath(folder, "coordination-1.fdq") ) || fileExists( joinPath(folder, "coordination.fdb") );
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}
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IKeyValueStore* operator->() { return get(); }
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Future<Void> getError() { return onErr(err.getFuture()); }
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private:
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std::string folder;
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UID myID;
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IKeyValueStore* store;
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Promise<Future<Void>> err;
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ACTOR static Future<Void> onErr( Future<Future<Void>> e ) {
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Future<Void> f = wait(e);
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wait(f);
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return Void();
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}
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void open() {
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platform::createDirectory( folder );
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store = keyValueStoreMemory( joinPath(folder, "coordination-"), myID, 500e6 );
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err.send( store->getError() );
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}
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};
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ACTOR Future<Void> localGenerationReg( GenerationRegInterface interf, OnDemandStore* pstore ) {
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state GenerationRegVal v;
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state OnDemandStore& store = *pstore;
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// SOMEDAY: concurrent access to different keys?
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loop choose {
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when ( GenerationRegReadRequest _req = waitNext( interf.read.getFuture() ) ) {
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TraceEvent("GenerationRegReadRequest").detail("From", _req.reply.getEndpoint().getPrimaryAddress()).detail("K", _req.key);
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state GenerationRegReadRequest req = _req;
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Optional<Value> rawV = wait( store->readValue( req.key ) );
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v = rawV.present() ? BinaryReader::fromStringRef<GenerationRegVal>( rawV.get(), IncludeVersion() ) : GenerationRegVal();
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TraceEvent("GenerationRegReadReply").detail("RVSize", rawV.present() ? rawV.get().size() : -1).detail("VWG", v.writeGen.generation);
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if (v.readGen < req.gen) {
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v.readGen = req.gen;
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store->set( KeyValueRef( req.key, BinaryWriter::toValue(v, IncludeVersion(ProtocolVersion::withGenerationRegVal())) ) );
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wait(store->commit());
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}
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req.reply.send( GenerationRegReadReply( v.val, v.writeGen, v.readGen ) );
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}
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when ( GenerationRegWriteRequest _wrq = waitNext( interf.write.getFuture() ) ) {
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state GenerationRegWriteRequest wrq = _wrq;
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Optional<Value> rawV = wait( store->readValue( wrq.kv.key ) );
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v = rawV.present() ? BinaryReader::fromStringRef<GenerationRegVal>( rawV.get(), IncludeVersion() ) : GenerationRegVal();
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if (v.readGen <= wrq.gen && v.writeGen < wrq.gen) {
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v.writeGen = wrq.gen;
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v.val = wrq.kv.value;
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store->set( KeyValueRef( wrq.kv.key, BinaryWriter::toValue(v, IncludeVersion(ProtocolVersion::withGenerationRegVal())) ) );
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wait(store->commit());
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TraceEvent("GenerationRegWrote").detail("From", wrq.reply.getEndpoint().getPrimaryAddress()).detail("Key", wrq.kv.key)
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.detail("ReqGen", wrq.gen.generation).detail("Returning", v.writeGen.generation);
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wrq.reply.send( v.writeGen );
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} else {
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TraceEvent("GenerationRegWriteFail").detail("From", wrq.reply.getEndpoint().getPrimaryAddress()).detail("Key", wrq.kv.key)
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.detail("ReqGen", wrq.gen.generation).detail("ReadGen", v.readGen.generation).detail("WriteGen", v.writeGen.generation);
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wrq.reply.send( std::max( v.readGen, v.writeGen ) );
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}
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}
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}
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}
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TEST_CASE("/fdbserver/Coordination/localGenerationReg/simple") {
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state GenerationRegInterface reg;
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state OnDemandStore store("simfdb/unittests/", //< FIXME
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deterministicRandom()->randomUniqueID());
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state Future<Void> actor = localGenerationReg(reg, &store);
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state Key the_key(deterministicRandom()->randomAlphaNumeric( deterministicRandom()->randomInt(0, 10)));
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state UniqueGeneration firstGen(0, deterministicRandom()->randomUniqueID());
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{
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GenerationRegReadReply r = wait(reg.read.getReply(GenerationRegReadRequest(the_key, firstGen)));
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// If there was no prior write(_,_,0) or a data loss fault,
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// returns (Optional(),0,gen2)
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ASSERT(!r.value.present());
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ASSERT(r.gen == UniqueGeneration());
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ASSERT(r.rgen == firstGen);
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}
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{
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UniqueGeneration g = wait(reg.write.getReply(GenerationRegWriteRequest(KeyValueRef(the_key, LiteralStringRef("Value1")), firstGen)));
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// (gen1==gen is considered a "successful" write)
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ASSERT(g == firstGen);
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}
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{
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GenerationRegReadReply r = wait(reg.read.getReply(GenerationRegReadRequest(the_key, UniqueGeneration())));
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// read(key,gen2) returns (value,gen,rgen).
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// There was some earlier or concurrent write(key,value,gen).
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ASSERT(r.value == LiteralStringRef("Value1"));
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ASSERT(r.gen == firstGen);
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// There was some earlier or concurrent read(key,rgen).
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ASSERT(r.rgen == firstGen);
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// If there is a write(key,_,gen1)=>gen1 s.t. gen1 < gen2 OR the write completed before this read started, then gen >= gen1.
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ASSERT(r.gen >= firstGen);
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// If there is a read(key,gen1) that completed before this read started, then rgen >= gen1
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ASSERT(r.rgen >= firstGen);
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ASSERT(!actor.isReady());
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}
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return Void();
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}
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ACTOR Future<Void> openDatabase(ClientData* db, int* clientCount, Reference<AsyncVar<bool>> hasConnectedClients, OpenDatabaseCoordRequest req) {
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++(*clientCount);
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hasConnectedClients->set(true);
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if(req.supportedVersions.size() > 0) {
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db->clientStatusInfoMap[req.reply.getEndpoint().getPrimaryAddress()] = ClientStatusInfo(req.traceLogGroup, req.supportedVersions, req.issues);
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}
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while (db->clientInfo->get().read().id == req.knownClientInfoID && !db->clientInfo->get().read().forward.present()) {
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choose {
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when (wait( yieldedFuture(db->clientInfo->onChange()) )) {}
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when (wait( delayJittered( SERVER_KNOBS->CLIENT_REGISTER_INTERVAL ) )) { break; } // The client might be long gone!
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}
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}
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if(req.supportedVersions.size() > 0) {
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db->clientStatusInfoMap.erase(req.reply.getEndpoint().getPrimaryAddress());
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}
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req.reply.send( db->clientInfo->get() );
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if(--(*clientCount) == 0) {
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hasConnectedClients->set(false);
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}
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return Void();
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}
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ACTOR Future<Void> remoteMonitorLeader( int* clientCount, Reference<AsyncVar<bool>> hasConnectedClients, Reference<AsyncVar<Optional<LeaderInfo>>> currentElectedLeader, ElectionResultRequest req ) {
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++(*clientCount);
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hasConnectedClients->set(true);
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while (!currentElectedLeader->get().present() || req.knownLeader == currentElectedLeader->get().get().changeID) {
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choose {
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when (wait( yieldedFuture(currentElectedLeader->onChange()) ) ) {}
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when (wait( delayJittered( SERVER_KNOBS->CLIENT_REGISTER_INTERVAL ) )) { break; }
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}
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}
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req.reply.send( currentElectedLeader->get() );
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if(--(*clientCount) == 0) {
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hasConnectedClients->set(false);
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}
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return Void();
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}
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// This actor implements a *single* leader-election register (essentially, it ignores
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// the .key member of each request). It returns any time the leader election is in the
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// default state, so that only active registers consume memory.
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ACTOR Future<Void> leaderRegister(LeaderElectionRegInterface interf, Key key) {
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state std::set<LeaderInfo> availableCandidates;
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state std::set<LeaderInfo> availableLeaders;
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state Optional<LeaderInfo> currentNominee;
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state Deque<ReplyPromise<Optional<LeaderInfo>>> notify;
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state Future<Void> nextInterval;
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state double candidateDelay = SERVER_KNOBS->CANDIDATE_MIN_DELAY;
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state int leaderIntervalCount = 0;
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state Future<Void> notifyCheck = delay(SERVER_KNOBS->NOTIFICATION_FULL_CLEAR_TIME / SERVER_KNOBS->MIN_NOTIFICATIONS);
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state ClientData clientData;
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state int clientCount = 0;
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state Reference<AsyncVar<bool>> hasConnectedClients = Reference<AsyncVar<bool>>( new AsyncVar<bool>(false) );
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state ActorCollection actors(false);
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state Future<Void> leaderMon;
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state AsyncVar<Value> leaderInterface;
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state Reference<AsyncVar<Optional<LeaderInfo>>> currentElectedLeader = Reference<AsyncVar<Optional<LeaderInfo>>>( new AsyncVar<Optional<LeaderInfo>>() );
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loop choose {
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when ( OpenDatabaseCoordRequest req = waitNext( interf.openDatabase.getFuture() ) ) {
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if (clientData.clientInfo->get().read().id != req.knownClientInfoID && !clientData.clientInfo->get().read().forward.present()) {
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req.reply.send(clientData.clientInfo->get());
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} else {
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if(!leaderMon.isValid()) {
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leaderMon = monitorLeaderForProxies(req.clusterKey, req.coordinators, &clientData, currentElectedLeader);
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}
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actors.add(openDatabase(&clientData, &clientCount, hasConnectedClients, req));
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}
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}
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when ( ElectionResultRequest req = waitNext( interf.electionResult.getFuture() ) ) {
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if (currentElectedLeader->get().present() && req.knownLeader != currentElectedLeader->get().get().changeID) {
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req.reply.send(currentElectedLeader->get());
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} else {
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if(!leaderMon.isValid()) {
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leaderMon = monitorLeaderForProxies(req.key, req.coordinators, &clientData, currentElectedLeader);
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}
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actors.add(remoteMonitorLeader(&clientCount, hasConnectedClients, currentElectedLeader, req));
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}
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}
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when ( GetLeaderRequest req = waitNext( interf.getLeader.getFuture() ) ) {
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if (currentNominee.present() && currentNominee.get().changeID != req.knownLeader) {
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req.reply.send( currentNominee.get() );
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} else {
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notify.push_back( req.reply );
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if(notify.size() > SERVER_KNOBS->MAX_NOTIFICATIONS) {
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TraceEvent(SevWarnAlways, "TooManyNotifications").detail("Amount", notify.size());
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for (uint32_t i=0; i<notify.size(); i++)
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notify[i].send( currentNominee.get() );
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notify.clear();
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} else if(!nextInterval.isValid()) {
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nextInterval = delay(0);
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}
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}
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}
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when ( CandidacyRequest req = waitNext( interf.candidacy.getFuture() ) ) {
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if(!nextInterval.isValid()) {
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nextInterval = delay(0);
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}
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availableCandidates.erase( LeaderInfo(req.prevChangeID) );
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availableCandidates.insert( req.myInfo );
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if (currentNominee.present() && currentNominee.get().changeID != req.knownLeader) {
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req.reply.send( currentNominee.get() );
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} else {
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notify.push_back( req.reply );
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if(notify.size() > SERVER_KNOBS->MAX_NOTIFICATIONS) {
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TraceEvent(SevWarnAlways, "TooManyNotifications").detail("Amount", notify.size());
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for (uint32_t i=0; i<notify.size(); i++)
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notify[i].send( currentNominee.get() );
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notify.clear();
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}
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}
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}
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when (LeaderHeartbeatRequest req = waitNext( interf.leaderHeartbeat.getFuture() ) ) {
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if(!nextInterval.isValid()) {
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nextInterval = delay(0);
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}
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//TODO: use notify to only send a heartbeat once per interval
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availableLeaders.erase( LeaderInfo(req.prevChangeID) );
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availableLeaders.insert( req.myInfo );
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req.reply.send(
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LeaderHeartbeatReply{ currentNominee.present() && currentNominee.get().equalInternalId(req.myInfo) });
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}
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when (ForwardRequest req = waitNext( interf.forward.getFuture() ) ) {
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LeaderInfo newInfo;
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newInfo.forward = true;
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newInfo.serializedInfo = req.conn.toString();
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for(unsigned int i=0; i<notify.size(); i++)
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notify[i].send( newInfo );
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notify.clear();
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ClientDBInfo outInfo;
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outInfo.id = deterministicRandom()->randomUniqueID();
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outInfo.forward = req.conn.toString();
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clientData.clientInfo->set(CachedSerialization<ClientDBInfo>(outInfo));
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req.reply.send( Void() );
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if(!hasConnectedClients->get()) {
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return Void();
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}
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nextInterval = Future<Void>();
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}
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when ( wait(nextInterval.isValid() ? nextInterval : Never()) ) {
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if (!availableLeaders.size() && !availableCandidates.size() && !notify.size() &&
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!currentNominee.present())
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{
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// Our state is back to the initial state, so we can safely stop this actor
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TraceEvent("EndingLeaderNomination").detail("Key", key).detail("HasConnectedClients", hasConnectedClients->get());
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if(!hasConnectedClients->get()) {
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return Void();
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} else {
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nextInterval = Future<Void>();
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}
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} else {
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Optional<LeaderInfo> nextNominee;
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if( availableCandidates.size() && (!availableLeaders.size() || availableLeaders.begin()->leaderChangeRequired(*availableCandidates.begin())) ) {
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nextNominee = *availableCandidates.begin();
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} else if( availableLeaders.size() ) {
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nextNominee = *availableLeaders.begin();
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}
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if( !currentNominee.present() || !nextNominee.present() || !currentNominee.get().equalInternalId(nextNominee.get()) || nextNominee.get() > currentNominee.get() ) {
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TraceEvent("NominatingLeader").detail("NextNominee", nextNominee.present() ? nextNominee.get().changeID : UID())
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.detail("CurrentNominee", currentNominee.present() ? currentNominee.get().changeID : UID()).detail("Key", printable(key));
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for(unsigned int i=0; i<notify.size(); i++)
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notify[i].send( nextNominee );
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notify.clear();
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}
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currentNominee = nextNominee;
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if( availableLeaders.size() ) {
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nextInterval = delay( SERVER_KNOBS->POLLING_FREQUENCY );
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if(leaderIntervalCount++ > 5) {
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candidateDelay = SERVER_KNOBS->CANDIDATE_MIN_DELAY;
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}
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} else {
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nextInterval = delay( candidateDelay );
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candidateDelay = std::min(SERVER_KNOBS->CANDIDATE_MAX_DELAY, candidateDelay * SERVER_KNOBS->CANDIDATE_GROWTH_RATE);
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leaderIntervalCount = 0;
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}
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availableLeaders.clear();
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availableCandidates.clear();
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}
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}
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when( wait(notifyCheck) ) {
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notifyCheck = delay( SERVER_KNOBS->NOTIFICATION_FULL_CLEAR_TIME / std::max<double>(SERVER_KNOBS->MIN_NOTIFICATIONS, notify.size()) );
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if(!notify.empty() && currentNominee.present()) {
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notify.front().send( currentNominee.get() );
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notify.pop_front();
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}
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}
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when( wait(hasConnectedClients->onChange()) ) {
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if(!hasConnectedClients->get() && !nextInterval.isValid()) {
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TraceEvent("LeaderRegisterUnneeded").detail("Key", key);
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return Void();
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}
|
|
}
|
|
when( wait(actors.getResult()) ) {}
|
|
}
|
|
}
|
|
|
|
// Generation register values are stored without prefixing in the coordinated state, but always begin with an alphanumeric character
|
|
// (they are always derived from a ClusterConnectionString key).
|
|
// Forwarding values are stored in this range:
|
|
const KeyRangeRef fwdKeys( LiteralStringRef( "\xff" "fwd" ), LiteralStringRef( "\xff" "fwe" ) );
|
|
|
|
struct LeaderRegisterCollection {
|
|
// SOMEDAY: Factor this into a generic tool? Extend ActorCollection to support removal actions? What?
|
|
ActorCollection actors;
|
|
Map<Key, LeaderElectionRegInterface> registerInterfaces;
|
|
Map<Key, LeaderInfo> forward;
|
|
OnDemandStore *pStore;
|
|
|
|
LeaderRegisterCollection( OnDemandStore *pStore ) : actors( false ), pStore( pStore ) {}
|
|
|
|
ACTOR static Future<Void> init( LeaderRegisterCollection *self ) {
|
|
if( !self->pStore->exists() )
|
|
return Void();
|
|
OnDemandStore &store = *self->pStore;
|
|
Standalone<RangeResultRef> forwardingInfo = wait( store->readRange( fwdKeys ) );
|
|
for( int i = 0; i < forwardingInfo.size(); i++ ) {
|
|
LeaderInfo forwardInfo;
|
|
forwardInfo.forward = true;
|
|
forwardInfo.serializedInfo = forwardingInfo[i].value;
|
|
self->forward[ forwardingInfo[i].key.removePrefix( fwdKeys.begin ) ] = forwardInfo;
|
|
}
|
|
return Void();
|
|
}
|
|
|
|
Future<Void> onError() { return actors.getResult(); }
|
|
|
|
Optional<LeaderInfo> getForward(KeyRef key) {
|
|
auto i = forward.find( key );
|
|
if (i == forward.end())
|
|
return Optional<LeaderInfo>();
|
|
return i->value;
|
|
}
|
|
|
|
ACTOR static Future<Void> setForward(LeaderRegisterCollection *self, KeyRef key, ClusterConnectionString conn) {
|
|
LeaderInfo forwardInfo;
|
|
forwardInfo.forward = true;
|
|
forwardInfo.serializedInfo = conn.toString();
|
|
self->forward[ key ] = forwardInfo;
|
|
OnDemandStore &store = *self->pStore;
|
|
store->set( KeyValueRef( key.withPrefix( fwdKeys.begin ), conn.toString() ) );
|
|
wait(store->commit());
|
|
return Void();
|
|
}
|
|
|
|
LeaderElectionRegInterface& getInterface(KeyRef key, UID id) {
|
|
auto i = registerInterfaces.find( key );
|
|
if (i == registerInterfaces.end()) {
|
|
Key k = key;
|
|
Future<Void> a = wrap(this, k, leaderRegister(registerInterfaces[k], k), id);
|
|
if (a.isError()) throw a.getError();
|
|
ASSERT( !a.isReady() );
|
|
actors.add( a );
|
|
i = registerInterfaces.find( key );
|
|
}
|
|
ASSERT( i != registerInterfaces.end() );
|
|
return i->value;
|
|
}
|
|
|
|
ACTOR static Future<Void> wrap( LeaderRegisterCollection* self, Key key, Future<Void> actor, UID id ) {
|
|
state Error e;
|
|
try {
|
|
// FIXME: Get worker ID here
|
|
startRole(Role::COORDINATOR, id, UID());
|
|
wait(actor || traceRole(Role::COORDINATOR, id));
|
|
endRole(Role::COORDINATOR, id, "Coordinator changed");
|
|
} catch (Error& err) {
|
|
endRole(Role::COORDINATOR, id, err.what(), err.code() == error_code_actor_cancelled, err);
|
|
if (err.code() == error_code_actor_cancelled)
|
|
throw;
|
|
e = err;
|
|
}
|
|
self->registerInterfaces.erase(key);
|
|
if (e.code() != invalid_error_code) throw e;
|
|
return Void();
|
|
}
|
|
|
|
};
|
|
|
|
// leaderServer multiplexes multiple leaderRegisters onto a single LeaderElectionRegInterface,
|
|
// creating and destroying them on demand.
|
|
ACTOR Future<Void> leaderServer(LeaderElectionRegInterface interf, OnDemandStore *pStore, UID id) {
|
|
state LeaderRegisterCollection regs( pStore );
|
|
state ActorCollection forwarders(false);
|
|
|
|
wait( LeaderRegisterCollection::init( ®s ) );
|
|
|
|
loop choose {
|
|
when ( OpenDatabaseCoordRequest req = waitNext( interf.openDatabase.getFuture() ) ) {
|
|
Optional<LeaderInfo> forward = regs.getForward(req.clusterKey);
|
|
if( forward.present() ) {
|
|
ClientDBInfo info;
|
|
info.id = deterministicRandom()->randomUniqueID();
|
|
info.forward = forward.get().serializedInfo;
|
|
req.reply.send( CachedSerialization<ClientDBInfo>(info) );
|
|
} else {
|
|
regs.getInterface(req.clusterKey, id).openDatabase.send( req );
|
|
}
|
|
}
|
|
when ( ElectionResultRequest req = waitNext( interf.electionResult.getFuture() ) ) {
|
|
Optional<LeaderInfo> forward = regs.getForward(req.key);
|
|
if( forward.present() ) {
|
|
req.reply.send( forward.get() );
|
|
} else {
|
|
regs.getInterface(req.key, id).electionResult.send( req );
|
|
}
|
|
}
|
|
when ( GetLeaderRequest req = waitNext( interf.getLeader.getFuture() ) ) {
|
|
Optional<LeaderInfo> forward = regs.getForward(req.key);
|
|
if( forward.present() )
|
|
req.reply.send( forward.get() );
|
|
else
|
|
regs.getInterface(req.key, id).getLeader.send( req );
|
|
}
|
|
when ( CandidacyRequest req = waitNext( interf.candidacy.getFuture() ) ) {
|
|
Optional<LeaderInfo> forward = regs.getForward(req.key);
|
|
if( forward.present() )
|
|
req.reply.send( forward.get() );
|
|
else
|
|
regs.getInterface(req.key, id).candidacy.send(req);
|
|
}
|
|
when ( LeaderHeartbeatRequest req = waitNext( interf.leaderHeartbeat.getFuture() ) ) {
|
|
Optional<LeaderInfo> forward = regs.getForward(req.key);
|
|
if( forward.present() )
|
|
req.reply.send(LeaderHeartbeatReply{ false });
|
|
else
|
|
regs.getInterface(req.key, id).leaderHeartbeat.send(req);
|
|
}
|
|
when ( ForwardRequest req = waitNext( interf.forward.getFuture() ) ) {
|
|
Optional<LeaderInfo> forward = regs.getForward(req.key);
|
|
if( forward.present() )
|
|
req.reply.send( Void() );
|
|
else {
|
|
forwarders.add( LeaderRegisterCollection::setForward( ®s, req.key, ClusterConnectionString(req.conn.toString()) ) );
|
|
regs.getInterface(req.key, id).forward.send(req);
|
|
}
|
|
}
|
|
when( wait( forwarders.getResult() ) ) { ASSERT(false); throw internal_error(); }
|
|
}
|
|
}
|
|
|
|
ACTOR Future<Void> coordinationServer(std::string dataFolder) {
|
|
state UID myID = deterministicRandom()->randomUniqueID();
|
|
state LeaderElectionRegInterface myLeaderInterface( g_network );
|
|
state GenerationRegInterface myInterface( g_network );
|
|
state OnDemandStore store( dataFolder, myID );
|
|
|
|
TraceEvent("CoordinationServer", myID).detail("MyInterfaceAddr", myInterface.read.getEndpoint().getPrimaryAddress()).detail("Folder", dataFolder);
|
|
|
|
try {
|
|
wait( localGenerationReg(myInterface, &store) || leaderServer(myLeaderInterface, &store, myID) || store.getError() );
|
|
throw internal_error();
|
|
} catch (Error& e) {
|
|
TraceEvent("CoordinationServerError", myID).error(e, true);
|
|
throw;
|
|
}
|
|
}
|