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|
/**
* Copyright (C) 2018-present MongoDB, Inc.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the Server Side Public License, version 1,
* as published by MongoDB, Inc.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* Server Side Public License for more details.
*
* You should have received a copy of the Server Side Public License
* along with this program. If not, see
* <http://www.mongodb.com/licensing/server-side-public-license>.
*
* As a special exception, the copyright holders give permission to link the
* code of portions of this program with the OpenSSL library under certain
* conditions as described in each individual source file and distribute
* linked combinations including the program with the OpenSSL library. You
* must comply with the Server Side Public License in all respects for
* all of the code used other than as permitted herein. If you modify file(s)
* with this exception, you may extend this exception to your version of the
* file(s), but you are not obligated to do so. If you do not wish to do so,
* delete this exception statement from your version. If you delete this
* exception statement from all source files in the program, then also delete
* it in the license file.
*/
#define MONGO_LOGV2_DEFAULT_COMPONENT ::mongo::logv2::LogComponent::kReplicationInitialSync
#include "mongo/platform/basic.h"
#include "initial_syncer.h"
#include <algorithm>
#include <memory>
#include <utility>
#include "mongo/base/counter.h"
#include "mongo/base/status.h"
#include "mongo/bson/simple_bsonobj_comparator.h"
#include "mongo/bson/util/bson_extract.h"
#include "mongo/client/fetcher.h"
#include "mongo/client/remote_command_retry_scheduler.h"
#include "mongo/db/commands/feature_compatibility_version_parser.h"
#include "mongo/db/commands/server_status_metric.h"
#include "mongo/db/concurrency/d_concurrency.h"
#include "mongo/db/index_builds_coordinator.h"
#include "mongo/db/jsobj.h"
#include "mongo/db/namespace_string.h"
#include "mongo/db/repl/all_database_cloner.h"
#include "mongo/db/repl/initial_sync_state.h"
#include "mongo/db/repl/initial_syncer_factory.h"
#include "mongo/db/repl/member_state.h"
#include "mongo/db/repl/oplog_buffer.h"
#include "mongo/db/repl/oplog_fetcher.h"
#include "mongo/db/repl/optime.h"
#include "mongo/db/repl/repl_server_parameters_gen.h"
#include "mongo/db/repl/replication_consistency_markers.h"
#include "mongo/db/repl/replication_process.h"
#include "mongo/db/repl/storage_interface.h"
#include "mongo/db/repl/sync_source_selector.h"
#include "mongo/db/repl/tenant_migration_access_blocker_util.h"
#include "mongo/db/repl/transaction_oplog_application.h"
#include "mongo/db/session_txn_record_gen.h"
#include "mongo/executor/task_executor.h"
#include "mongo/executor/thread_pool_task_executor.h"
#include "mongo/logv2/log.h"
#include "mongo/rpc/metadata/repl_set_metadata.h"
#include "mongo/util/assert_util.h"
#include "mongo/util/destructor_guard.h"
#include "mongo/util/fail_point.h"
#include "mongo/util/scopeguard.h"
#include "mongo/util/str.h"
#include "mongo/util/system_clock_source.h"
#include "mongo/util/time_support.h"
#include "mongo/util/timer.h"
#include "mongo/util/version/releases.h"
namespace mongo {
namespace repl {
// Failpoint for initial sync
MONGO_FAIL_POINT_DEFINE(failInitialSyncWithBadHost);
// Failpoint which fails initial sync and leaves an oplog entry in the buffer.
MONGO_FAIL_POINT_DEFINE(failInitSyncWithBufferedEntriesLeft);
// Failpoint which causes the initial sync function to hang after getting the oldest active
// transaction timestamp from the sync source.
MONGO_FAIL_POINT_DEFINE(initialSyncHangAfterGettingBeginFetchingTimestamp);
// Failpoint which causes the initial sync function to hang before creating shared data and
// splitting control flow between the oplog fetcher and the cloners.
MONGO_FAIL_POINT_DEFINE(initialSyncHangBeforeSplittingControlFlow);
// Failpoint which causes the initial sync function to hang before copying databases.
MONGO_FAIL_POINT_DEFINE(initialSyncHangBeforeCopyingDatabases);
// Failpoint which causes the initial sync function to hang before finishing.
MONGO_FAIL_POINT_DEFINE(initialSyncHangBeforeFinish);
// Failpoint which causes the initial sync function to hang before creating the oplog.
MONGO_FAIL_POINT_DEFINE(initialSyncHangBeforeCreatingOplog);
// Failpoint which stops the applier.
MONGO_FAIL_POINT_DEFINE(rsSyncApplyStop);
// Failpoint which causes the initial sync function to hang after cloning all databases.
MONGO_FAIL_POINT_DEFINE(initialSyncHangAfterDataCloning);
// Failpoint which skips clearing _initialSyncState after a successful initial sync attempt.
MONGO_FAIL_POINT_DEFINE(skipClearInitialSyncState);
// Failpoint which causes the initial sync function to fail and hang before starting a new attempt.
MONGO_FAIL_POINT_DEFINE(failAndHangInitialSync);
// Failpoint which fails initial sync before it applies the next batch of oplog entries.
MONGO_FAIL_POINT_DEFINE(failInitialSyncBeforeApplyingBatch);
// Failpoint which fasserts if applying a batch fails.
MONGO_FAIL_POINT_DEFINE(initialSyncFassertIfApplyingBatchFails);
// Failpoint which causes the initial sync function to hang before stopping the oplog fetcher.
MONGO_FAIL_POINT_DEFINE(initialSyncHangBeforeCompletingOplogFetching);
// Failpoint which causes the initial sync function to hang before choosing a sync source.
MONGO_FAIL_POINT_DEFINE(initialSyncHangBeforeChoosingSyncSource);
// Failpoint which causes the initial sync function to hang after finishing.
MONGO_FAIL_POINT_DEFINE(initialSyncHangAfterFinish);
// Failpoints for synchronization, shared with cloners.
extern FailPoint initialSyncFuzzerSynchronizationPoint1;
extern FailPoint initialSyncFuzzerSynchronizationPoint2;
namespace {
using namespace executor;
using CallbackArgs = executor::TaskExecutor::CallbackArgs;
using Event = executor::TaskExecutor::EventHandle;
using Handle = executor::TaskExecutor::CallbackHandle;
using QueryResponseStatus = StatusWith<Fetcher::QueryResponse>;
using UniqueLock = stdx::unique_lock<Latch>;
using LockGuard = stdx::lock_guard<Latch>;
// Used to reset the oldest timestamp during initial sync to a non-null timestamp.
const Timestamp kTimestampOne(0, 1);
// The number of initial sync attempts that have failed since server startup. Each instance of
// InitialSyncer may run multiple attempts to fulfill an initial sync request that is triggered
// when InitialSyncer::startup() is called.
Counter64 initialSyncFailedAttempts;
// The number of initial sync requests that have been requested and failed. Each instance of
// InitialSyncer (upon successful startup()) corresponds to a single initial sync request.
// This value does not include the number of times where a InitialSyncer is created successfully
// but failed in startup().
Counter64 initialSyncFailures;
// The number of initial sync requests that have been requested and completed successfully. Each
// instance of InitialSyncer corresponds to a single initial sync request.
Counter64 initialSyncCompletes;
ServerStatusMetricField<Counter64> displaySSInitialSyncFailedAttempts(
"repl.initialSync.failedAttempts", &initialSyncFailedAttempts);
ServerStatusMetricField<Counter64> displaySSInitialSyncFailures("repl.initialSync.failures",
&initialSyncFailures);
ServerStatusMetricField<Counter64> displaySSInitialSyncCompleted("repl.initialSync.completed",
&initialSyncCompletes);
ServiceContext::UniqueOperationContext makeOpCtx() {
return cc().makeOperationContext();
}
StatusWith<OpTimeAndWallTime> parseOpTimeAndWallTime(const QueryResponseStatus& fetchResult) {
if (!fetchResult.isOK()) {
return fetchResult.getStatus();
}
const auto docs = fetchResult.getValue().documents;
const auto hasDoc = docs.begin() != docs.end();
if (!hasDoc) {
return StatusWith<OpTimeAndWallTime>{ErrorCodes::NoMatchingDocument,
"no oplog entry found"};
}
return OpTimeAndWallTime::parseOpTimeAndWallTimeFromOplogEntry(docs.front());
}
void pauseAtInitialSyncFuzzerSyncronizationPoints(std::string msg) {
// Set and unset by the InitialSyncTest fixture to cause initial sync to pause so that the
// Initial Sync Fuzzer can run commands on the sync source.
if (MONGO_unlikely(initialSyncFuzzerSynchronizationPoint1.shouldFail())) {
LOGV2(21158,
"initialSyncFuzzerSynchronizationPoint1 fail point enabled",
"failpointMessage"_attr = msg);
initialSyncFuzzerSynchronizationPoint1.pauseWhileSet();
}
if (MONGO_unlikely(initialSyncFuzzerSynchronizationPoint2.shouldFail())) {
LOGV2(21160, "initialSyncFuzzerSynchronizationPoint2 fail point enabled");
initialSyncFuzzerSynchronizationPoint2.pauseWhileSet();
}
}
} // namespace
ServiceContext::ConstructorActionRegisterer initialSyncerRegisterer(
"InitialSyncerRegisterer",
{"InitialSyncerFactoryRegisterer"} /* dependency list */,
[](ServiceContext* service) {
InitialSyncerFactory::get(service)->registerInitialSyncer(
"logical",
[](InitialSyncerInterface::Options opts,
std::unique_ptr<DataReplicatorExternalState> dataReplicatorExternalState,
ThreadPool* writerPool,
StorageInterface* storage,
ReplicationProcess* replicationProcess,
const InitialSyncerInterface::OnCompletionFn& onCompletion) {
return std::make_shared<InitialSyncer>(opts,
std::move(dataReplicatorExternalState),
writerPool,
storage,
replicationProcess,
onCompletion);
});
});
InitialSyncer::InitialSyncer(
InitialSyncerInterface::Options opts,
std::unique_ptr<DataReplicatorExternalState> dataReplicatorExternalState,
ThreadPool* writerPool,
StorageInterface* storage,
ReplicationProcess* replicationProcess,
const OnCompletionFn& onCompletion)
: _fetchCount(0),
_opts(opts),
_dataReplicatorExternalState(std::move(dataReplicatorExternalState)),
_exec(_dataReplicatorExternalState->getSharedTaskExecutor()),
_clonerExec(_exec),
_writerPool(writerPool),
_storage(storage),
_replicationProcess(replicationProcess),
_onCompletion(onCompletion),
_createClientFn(
[] { return std::make_unique<DBClientConnection>(true /* autoReconnect */); }),
_createOplogFetcherFn(CreateOplogFetcherFn::get()) {
uassert(ErrorCodes::BadValue, "task executor cannot be null", _exec);
uassert(ErrorCodes::BadValue, "invalid storage interface", _storage);
uassert(ErrorCodes::BadValue, "invalid replication process", _replicationProcess);
uassert(ErrorCodes::BadValue, "invalid getMyLastOptime function", _opts.getMyLastOptime);
uassert(ErrorCodes::BadValue, "invalid setMyLastOptime function", _opts.setMyLastOptime);
uassert(ErrorCodes::BadValue, "invalid resetOptimes function", _opts.resetOptimes);
uassert(ErrorCodes::BadValue, "invalid sync source selector", _opts.syncSourceSelector);
uassert(ErrorCodes::BadValue, "callback function cannot be null", _onCompletion);
}
InitialSyncer::~InitialSyncer() {
DESTRUCTOR_GUARD({
shutdown().transitional_ignore();
join();
});
}
bool InitialSyncer::isActive() const {
stdx::lock_guard<Latch> lock(_mutex);
return _isActive_inlock();
}
bool InitialSyncer::_isActive_inlock() const {
return State::kRunning == _state || State::kShuttingDown == _state;
}
Status InitialSyncer::startup(OperationContext* opCtx,
std::uint32_t initialSyncMaxAttempts) noexcept {
invariant(opCtx);
invariant(initialSyncMaxAttempts >= 1U);
stdx::lock_guard<Latch> lock(_mutex);
switch (_state) {
case State::kPreStart:
_state = State::kRunning;
break;
case State::kRunning:
return Status(ErrorCodes::IllegalOperation, "initial syncer already started");
case State::kShuttingDown:
return Status(ErrorCodes::ShutdownInProgress, "initial syncer shutting down");
case State::kComplete:
return Status(ErrorCodes::ShutdownInProgress, "initial syncer completed");
}
_setUp_inlock(opCtx, initialSyncMaxAttempts);
// Start first initial sync attempt.
std::uint32_t initialSyncAttempt = 0;
_attemptExec = std::make_unique<executor::ScopedTaskExecutor>(
_exec, Status(ErrorCodes::CallbackCanceled, "Initial Sync Attempt Canceled"));
_clonerAttemptExec = std::make_unique<executor::ScopedTaskExecutor>(
_clonerExec, Status(ErrorCodes::CallbackCanceled, "Initial Sync Attempt Canceled"));
auto status = _scheduleWorkAndSaveHandle_inlock(
[=](const executor::TaskExecutor::CallbackArgs& args) {
_startInitialSyncAttemptCallback(args, initialSyncAttempt, initialSyncMaxAttempts);
},
&_startInitialSyncAttemptHandle,
str::stream() << "_startInitialSyncAttemptCallback-" << initialSyncAttempt);
if (!status.isOK()) {
_state = State::kComplete;
return status;
}
return Status::OK();
}
Status InitialSyncer::shutdown() {
stdx::lock_guard<Latch> lock(_mutex);
switch (_state) {
case State::kPreStart:
// Transition directly from PreStart to Complete if not started yet.
_state = State::kComplete;
return Status::OK();
case State::kRunning:
_state = State::kShuttingDown;
break;
case State::kShuttingDown:
case State::kComplete:
// Nothing to do if we are already in ShuttingDown or Complete state.
return Status::OK();
}
_cancelRemainingWork_inlock();
return Status::OK();
}
void InitialSyncer::cancelCurrentAttempt() {
stdx::lock_guard lk(_mutex);
if (_isActive_inlock()) {
LOGV2_DEBUG(4427201,
1,
"Cancelling the current initial sync attempt.",
"currentAttempt"_attr = _stats.failedInitialSyncAttempts + 1);
_cancelRemainingWork_inlock();
} else {
LOGV2_DEBUG(4427202,
1,
"There is no initial sync attempt to cancel because the initial syncer is not "
"currently active.");
}
}
void InitialSyncer::_cancelRemainingWork_inlock() {
_cancelHandle_inlock(_startInitialSyncAttemptHandle);
_cancelHandle_inlock(_chooseSyncSourceHandle);
_cancelHandle_inlock(_getBaseRollbackIdHandle);
_cancelHandle_inlock(_getLastRollbackIdHandle);
_cancelHandle_inlock(_getNextApplierBatchHandle);
_shutdownComponent_inlock(_oplogFetcher);
if (_sharedData) {
// We actually hold the required lock, but the lock object itself is not passed through.
_clearRetriableError(WithLock::withoutLock());
stdx::lock_guard<InitialSyncSharedData> lock(*_sharedData);
_sharedData->setStatusIfOK(
lock, Status{ErrorCodes::CallbackCanceled, "Initial sync attempt canceled"});
}
if (_client) {
_client->shutdownAndDisallowReconnect();
}
_shutdownComponent_inlock(_applier);
_shutdownComponent_inlock(_fCVFetcher);
_shutdownComponent_inlock(_lastOplogEntryFetcher);
_shutdownComponent_inlock(_beginFetchingOpTimeFetcher);
(*_attemptExec)->shutdown();
(*_clonerAttemptExec)->shutdown();
_attemptCanceled = true;
}
void InitialSyncer::join() {
stdx::unique_lock<Latch> lk(_mutex);
_stateCondition.wait(lk, [this]() { return !_isActive_inlock(); });
}
InitialSyncer::State InitialSyncer::getState_forTest() const {
stdx::lock_guard<Latch> lk(_mutex);
return _state;
}
Date_t InitialSyncer::getWallClockTime_forTest() const {
stdx::lock_guard<Latch> lk(_mutex);
return _lastApplied.wallTime;
}
void InitialSyncer::setAllowedOutageDuration_forTest(Milliseconds allowedOutageDuration) {
stdx::lock_guard<Latch> lk(_mutex);
_allowedOutageDuration = allowedOutageDuration;
if (_sharedData) {
stdx::lock_guard<InitialSyncSharedData> lk(*_sharedData);
_sharedData->setAllowedOutageDuration_forTest(lk, allowedOutageDuration);
}
}
bool InitialSyncer::_isShuttingDown() const {
stdx::lock_guard<Latch> lock(_mutex);
return _isShuttingDown_inlock();
}
bool InitialSyncer::_isShuttingDown_inlock() const {
return State::kShuttingDown == _state;
}
std::string InitialSyncer::getDiagnosticString() const {
LockGuard lk(_mutex);
str::stream out;
out << "InitialSyncer -"
<< " oplogFetcher: " << _oplogFetcher->toString()
<< " opsBuffered: " << _oplogBuffer->getSize() << " active: " << _isActive_inlock()
<< " shutting down: " << _isShuttingDown_inlock();
if (_initialSyncState) {
out << " opsAppied: " << _initialSyncState->appliedOps;
}
return out;
}
BSONObj InitialSyncer::getInitialSyncProgress() const {
LockGuard lk(_mutex);
// We return an empty BSON object after an initial sync attempt has been successfully
// completed. When an initial sync attempt completes successfully, initialSyncCompletes is
// incremented and then _initialSyncState is cleared. We check that _initialSyncState has been
// cleared because an initial sync attempt can fail even after initialSyncCompletes is
// incremented, and we also check that initialSyncCompletes is positive because an initial sync
// attempt can also fail before _initialSyncState is initialized.
if (!_initialSyncState && initialSyncCompletes.get() > 0) {
return BSONObj();
}
return _getInitialSyncProgress_inlock();
}
void InitialSyncer::_appendInitialSyncProgressMinimal_inlock(BSONObjBuilder* bob) const {
_stats.append(bob);
if (!_initialSyncState) {
return;
}
if (_initialSyncState->allDatabaseCloner) {
const auto allDbClonerStats = _initialSyncState->allDatabaseCloner->getStats();
const auto approxTotalDataSize = allDbClonerStats.dataSize;
bob->appendNumber("approxTotalDataSize", approxTotalDataSize);
long long approxTotalBytesCopied = 0;
for (auto dbClonerStats : allDbClonerStats.databaseStats) {
for (auto collClonerStats : dbClonerStats.collectionStats) {
approxTotalBytesCopied += collClonerStats.approxBytesCopied;
}
}
bob->appendNumber("approxTotalBytesCopied", approxTotalBytesCopied);
if (approxTotalBytesCopied > 0) {
const auto statsObj = bob->asTempObj();
auto totalInitialSyncElapsedMillis =
statsObj.getField("totalInitialSyncElapsedMillis").safeNumberLong();
const auto downloadRate =
(double)totalInitialSyncElapsedMillis / (double)approxTotalBytesCopied;
const auto remainingInitialSyncEstimatedMillis =
downloadRate * (double)(approxTotalDataSize - approxTotalBytesCopied);
bob->appendNumber("remainingInitialSyncEstimatedMillis",
(long long)remainingInitialSyncEstimatedMillis);
}
}
bob->appendNumber("appliedOps", static_cast<long long>(_initialSyncState->appliedOps));
if (!_initialSyncState->beginApplyingTimestamp.isNull()) {
bob->append("initialSyncOplogStart", _initialSyncState->beginApplyingTimestamp);
}
// Only include the beginFetchingTimestamp if it's different from the beginApplyingTimestamp.
if (!_initialSyncState->beginFetchingTimestamp.isNull() &&
_initialSyncState->beginFetchingTimestamp != _initialSyncState->beginApplyingTimestamp) {
bob->append("initialSyncOplogFetchingStart", _initialSyncState->beginFetchingTimestamp);
}
if (!_initialSyncState->stopTimestamp.isNull()) {
bob->append("initialSyncOplogEnd", _initialSyncState->stopTimestamp);
}
if (_sharedData) {
stdx::lock_guard<InitialSyncSharedData> sdLock(*_sharedData);
auto unreachableSince = _sharedData->getSyncSourceUnreachableSince(sdLock);
if (unreachableSince != Date_t()) {
bob->append("syncSourceUnreachableSince", unreachableSince);
bob->append("currentOutageDurationMillis",
durationCount<Milliseconds>(_sharedData->getCurrentOutageDuration(sdLock)));
}
bob->append("totalTimeUnreachableMillis",
durationCount<Milliseconds>(_sharedData->getTotalTimeUnreachable(sdLock)));
}
}
BSONObj InitialSyncer::_getInitialSyncProgress_inlock() const {
try {
BSONObjBuilder bob;
_appendInitialSyncProgressMinimal_inlock(&bob);
if (_initialSyncState) {
if (_initialSyncState->allDatabaseCloner) {
BSONObjBuilder dbsBuilder(bob.subobjStart("databases"));
_initialSyncState->allDatabaseCloner->getStats().append(&dbsBuilder);
dbsBuilder.doneFast();
}
}
return bob.obj();
} catch (const DBException& e) {
LOGV2(21161,
"Error creating initial sync progress object: {error}",
"Error creating initial sync progress object",
"error"_attr = e.toString());
}
BSONObjBuilder bob;
_appendInitialSyncProgressMinimal_inlock(&bob);
return bob.obj();
}
void InitialSyncer::setCreateClientFn_forTest(const CreateClientFn& createClientFn) {
LockGuard lk(_mutex);
_createClientFn = createClientFn;
}
void InitialSyncer::setCreateOplogFetcherFn_forTest(
std::unique_ptr<OplogFetcherFactory> createOplogFetcherFn) {
LockGuard lk(_mutex);
_createOplogFetcherFn = std::move(createOplogFetcherFn);
}
OplogFetcher* InitialSyncer::getOplogFetcher_forTest() const {
// Wait up to 10 seconds.
for (auto i = 0; i < 100; i++) {
{
LockGuard lk(_mutex);
if (_oplogFetcher) {
return _oplogFetcher.get();
}
}
sleepmillis(100);
}
invariant(false, "Timed out getting OplogFetcher pointer for test");
return nullptr;
}
void InitialSyncer::setClonerExecutor_forTest(std::shared_ptr<executor::TaskExecutor> clonerExec) {
_clonerExec = clonerExec;
}
void InitialSyncer::waitForCloner_forTest() {
_initialSyncState->allDatabaseClonerFuture.wait();
}
void InitialSyncer::_setUp_inlock(OperationContext* opCtx, std::uint32_t initialSyncMaxAttempts) {
// 'opCtx' is passed through from startup().
_replicationProcess->getConsistencyMarkers()->setInitialSyncFlag(opCtx);
_replicationProcess->getConsistencyMarkers()->clearInitialSyncId(opCtx);
auto serviceCtx = opCtx->getServiceContext();
_storage->setInitialDataTimestamp(serviceCtx, Timestamp::kAllowUnstableCheckpointsSentinel);
_storage->setStableTimestamp(serviceCtx, Timestamp::min());
LOGV2_DEBUG(21162, 1, "Creating oplogBuffer");
_oplogBuffer = _dataReplicatorExternalState->makeInitialSyncOplogBuffer(opCtx);
_oplogBuffer->startup(opCtx);
_stats.initialSyncStart = _exec->now();
_stats.maxFailedInitialSyncAttempts = initialSyncMaxAttempts;
_stats.failedInitialSyncAttempts = 0;
_allowedOutageDuration = Seconds(initialSyncTransientErrorRetryPeriodSeconds.load());
}
void InitialSyncer::_tearDown_inlock(OperationContext* opCtx,
const StatusWith<OpTimeAndWallTime>& lastApplied) {
_stats.initialSyncEnd = _exec->now();
// This might not be necessary if we failed initial sync.
invariant(_oplogBuffer);
_oplogBuffer->shutdown(opCtx);
if (!lastApplied.isOK()) {
return;
}
const auto lastAppliedOpTime = lastApplied.getValue().opTime;
auto initialDataTimestamp = lastAppliedOpTime.getTimestamp();
// A node coming out of initial sync must guarantee at least one oplog document is visible
// such that others can sync from this node. Oplog visibility is only advanced when applying
// oplog entries during initial sync. Correct the visibility to match the initial sync time
// before transitioning to steady state replication.
const bool orderedCommit = true;
_storage->oplogDiskLocRegister(opCtx, initialDataTimestamp, orderedCommit);
tenant_migration_access_blocker::recoverTenantMigrationAccessBlockers(opCtx);
reconstructPreparedTransactions(opCtx, repl::OplogApplication::Mode::kInitialSync);
_replicationProcess->getConsistencyMarkers()->setInitialSyncIdIfNotSet(opCtx);
_replicationProcess->getConsistencyMarkers()->clearInitialSyncFlag(opCtx);
// All updates that represent initial sync must be completed before setting the initial data
// timestamp.
_storage->setInitialDataTimestamp(opCtx->getServiceContext(), initialDataTimestamp);
auto currentLastAppliedOpTime = _opts.getMyLastOptime();
if (currentLastAppliedOpTime.isNull()) {
_opts.setMyLastOptime(lastApplied.getValue());
} else {
invariant(currentLastAppliedOpTime == lastAppliedOpTime);
}
LOGV2(21163,
"initial sync done; took "
"{duration}.",
"Initial sync done",
"duration"_attr =
duration_cast<Seconds>(_stats.initialSyncEnd - _stats.initialSyncStart));
initialSyncCompletes.increment();
}
void InitialSyncer::_startInitialSyncAttemptCallback(
const executor::TaskExecutor::CallbackArgs& callbackArgs,
std::uint32_t initialSyncAttempt,
std::uint32_t initialSyncMaxAttempts) noexcept {
auto status = [&] {
stdx::lock_guard<Latch> lock(_mutex);
return _checkForShutdownAndConvertStatus_inlock(
callbackArgs,
str::stream() << "error while starting initial sync attempt "
<< (initialSyncAttempt + 1) << " of " << initialSyncMaxAttempts);
}();
if (!status.isOK()) {
_finishInitialSyncAttempt(status);
return;
}
LOGV2(21164,
"Starting initial sync (attempt {initialSyncAttempt} of {initialSyncMaxAttempts})",
"Starting initial sync attempt",
"initialSyncAttempt"_attr = (initialSyncAttempt + 1),
"initialSyncMaxAttempts"_attr = initialSyncMaxAttempts);
// This completion guard invokes _finishInitialSyncAttempt on destruction.
auto cancelRemainingWorkInLock = [this]() { _cancelRemainingWork_inlock(); };
auto finishInitialSyncAttemptFn = [this](const StatusWith<OpTimeAndWallTime>& lastApplied) {
_finishInitialSyncAttempt(lastApplied);
};
auto onCompletionGuard =
std::make_shared<OnCompletionGuard>(cancelRemainingWorkInLock, finishInitialSyncAttemptFn);
// Lock guard must be declared after completion guard because completion guard destructor
// has to run outside lock.
stdx::lock_guard<Latch> lock(_mutex);
_oplogApplier = {};
LOGV2_DEBUG(
21165, 2, "Resetting sync source so a new one can be chosen for this initial sync attempt");
_syncSource = HostAndPort();
LOGV2_DEBUG(21166, 2, "Resetting all optimes before starting this initial sync attempt");
_opts.resetOptimes();
_lastApplied = {OpTime(), Date_t()};
_lastFetched = {};
LOGV2_DEBUG(
21167, 2, "Resetting the oldest timestamp before starting this initial sync attempt");
auto storageEngine = getGlobalServiceContext()->getStorageEngine();
if (storageEngine) {
// Set the oldestTimestamp to one because WiredTiger does not allow us to set it to zero
// since that would also set the all_durable point to zero. We specifically don't set
// the stable timestamp here because that will trigger taking a first stable checkpoint even
// though the initialDataTimestamp is still set to kAllowUnstableCheckpointsSentinel.
storageEngine->setOldestTimestamp(kTimestampOne);
}
LOGV2_DEBUG(21168,
2,
"Resetting feature compatibility version to last-lts. If the sync source is in "
"latest feature compatibility version, we will find out when we clone the "
"server configuration collection (admin.system.version)");
serverGlobalParams.mutableFeatureCompatibility.reset();
// Clear the oplog buffer.
_oplogBuffer->clear(makeOpCtx().get());
// Get sync source.
std::uint32_t chooseSyncSourceAttempt = 0;
std::uint32_t chooseSyncSourceMaxAttempts =
static_cast<std::uint32_t>(numInitialSyncConnectAttempts.load());
// _scheduleWorkAndSaveHandle_inlock() is shutdown-aware.
status = _scheduleWorkAndSaveHandle_inlock(
[=](const executor::TaskExecutor::CallbackArgs& args) {
_chooseSyncSourceCallback(
args, chooseSyncSourceAttempt, chooseSyncSourceMaxAttempts, onCompletionGuard);
},
&_chooseSyncSourceHandle,
str::stream() << "_chooseSyncSourceCallback-" << chooseSyncSourceAttempt);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
}
void InitialSyncer::_chooseSyncSourceCallback(
const executor::TaskExecutor::CallbackArgs& callbackArgs,
std::uint32_t chooseSyncSourceAttempt,
std::uint32_t chooseSyncSourceMaxAttempts,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) noexcept try {
if (MONGO_unlikely(initialSyncHangBeforeChoosingSyncSource.shouldFail())) {
LOGV2(5284800, "initialSyncHangBeforeChoosingSyncSource fail point enabled");
initialSyncHangBeforeChoosingSyncSource.pauseWhileSet();
}
stdx::unique_lock<Latch> lock(_mutex);
// Cancellation should be treated the same as other errors. In this case, the most likely cause
// of a failed _chooseSyncSourceCallback() task is a cancellation triggered by
// InitialSyncer::shutdown() or the task executor shutting down.
auto status =
_checkForShutdownAndConvertStatus_inlock(callbackArgs, "error while choosing sync source");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
if (MONGO_unlikely(failInitialSyncWithBadHost.shouldFail())) {
status = Status(ErrorCodes::InvalidSyncSource,
"initial sync failed - failInitialSyncWithBadHost failpoint is set.");
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
auto syncSource = _chooseSyncSource_inlock();
if (!syncSource.isOK()) {
if (chooseSyncSourceAttempt + 1 >= chooseSyncSourceMaxAttempts) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::InitialSyncOplogSourceMissing,
"No valid sync source found in current replica set to do an initial sync."));
return;
}
auto when = (*_attemptExec)->now() + _opts.syncSourceRetryWait;
LOGV2_DEBUG(21169,
1,
"Error getting sync source: '{error}', trying again in "
"{syncSourceRetryWait} at {retryTime}. Attempt {chooseSyncSourceAttempt} of "
"{numInitialSyncConnectAttempts}",
"Error getting sync source. Waiting to retry",
"error"_attr = syncSource.getStatus(),
"syncSourceRetryWait"_attr = _opts.syncSourceRetryWait,
"retryTime"_attr = when.toString(),
"chooseSyncSourceAttempt"_attr = (chooseSyncSourceAttempt + 1),
"numInitialSyncConnectAttempts"_attr = numInitialSyncConnectAttempts.load());
auto status = _scheduleWorkAtAndSaveHandle_inlock(
when,
[=](const executor::TaskExecutor::CallbackArgs& args) {
_chooseSyncSourceCallback(args,
chooseSyncSourceAttempt + 1,
chooseSyncSourceMaxAttempts,
onCompletionGuard);
},
&_chooseSyncSourceHandle,
str::stream() << "_chooseSyncSourceCallback-" << (chooseSyncSourceAttempt + 1));
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
return;
}
if (MONGO_unlikely(initialSyncHangBeforeCreatingOplog.shouldFail())) {
// This log output is used in js tests so please leave it.
LOGV2(21170,
"initial sync - initialSyncHangBeforeCreatingOplog fail point "
"enabled. Blocking until fail point is disabled.");
lock.unlock();
while (MONGO_unlikely(initialSyncHangBeforeCreatingOplog.shouldFail()) &&
!_isShuttingDown()) {
mongo::sleepsecs(1);
}
lock.lock();
}
// There is no need to schedule separate task to create oplog collection since we are already in
// a callback and we are certain there's no existing operation context (required for creating
// collections and dropping user databases) attached to the current thread.
status = _truncateOplogAndDropReplicatedDatabases();
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
_syncSource = syncSource.getValue();
// Schedule rollback ID checker.
_rollbackChecker = std::make_unique<RollbackChecker>(*_attemptExec, _syncSource);
auto scheduleResult = _rollbackChecker->reset([=](const RollbackChecker::Result& result) {
return _rollbackCheckerResetCallback(result, onCompletionGuard);
});
status = scheduleResult.getStatus();
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
_getBaseRollbackIdHandle = scheduleResult.getValue();
} catch (const DBException&) {
// Report exception as an initial syncer failure.
stdx::unique_lock<Latch> lock(_mutex);
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, exceptionToStatus());
}
Status InitialSyncer::_truncateOplogAndDropReplicatedDatabases() {
// truncate oplog; drop user databases.
LOGV2_DEBUG(4540700,
1,
"About to truncate the oplog, if it exists, ns:{namespace}, and drop all "
"user databases (so that we can clone them).",
"About to truncate the oplog, if it exists, and drop all user databases (so that "
"we can clone them)",
"namespace"_attr = NamespaceString::kRsOplogNamespace);
auto opCtx = makeOpCtx();
// We are not replicating nor validating these writes.
UnreplicatedWritesBlock unreplicatedWritesBlock(opCtx.get());
// 1.) Truncate the oplog.
LOGV2_DEBUG(4540701,
2,
"Truncating the existing oplog: {namespace}",
"Truncating the existing oplog",
"namespace"_attr = NamespaceString::kRsOplogNamespace);
Timer timer;
auto status = _storage->truncateCollection(opCtx.get(), NamespaceString::kRsOplogNamespace);
LOGV2(21173,
"Initial syncer oplog truncation finished in: {durationMillis}ms",
"Initial syncer oplog truncation finished",
"durationMillis"_attr = timer.millis());
if (!status.isOK()) {
// 1a.) Create the oplog.
LOGV2_DEBUG(4540702,
2,
"Creating the oplog: {namespace}",
"Creating the oplog",
"namespace"_attr = NamespaceString::kRsOplogNamespace);
status = _storage->createOplog(opCtx.get(), NamespaceString::kRsOplogNamespace);
if (!status.isOK()) {
return status;
}
}
// 2a.) Abort any index builds started during initial sync.
IndexBuildsCoordinator::get(opCtx.get())
->abortAllIndexBuildsForInitialSync(opCtx.get(), "Aborting index builds for initial sync");
// 2b.) Drop user databases.
LOGV2_DEBUG(21175, 2, "Dropping user databases");
return _storage->dropReplicatedDatabases(opCtx.get());
}
void InitialSyncer::_rollbackCheckerResetCallback(
const RollbackChecker::Result& result, std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
stdx::lock_guard<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(result.getStatus(),
"error while getting base rollback ID");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
// Since the beginFetchingOpTime is retrieved before significant work is done copying
// data from the sync source, we allow the OplogEntryFetcher to use its default retry strategy
// which retries up to 'numInitialSyncOplogFindAttempts' times'. This will fail relatively
// quickly in the presence of network errors, allowing us to choose a different sync source.
status = _scheduleLastOplogEntryFetcher_inlock(
[=](const StatusWith<mongo::Fetcher::QueryResponse>& response,
mongo::Fetcher::NextAction*,
mongo::BSONObjBuilder*) mutable {
_lastOplogEntryFetcherCallbackForDefaultBeginFetchingOpTime(response,
onCompletionGuard);
},
kFetcherHandlesRetries);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
}
void InitialSyncer::_lastOplogEntryFetcherCallbackForDefaultBeginFetchingOpTime(
const StatusWith<Fetcher::QueryResponse>& result,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
stdx::unique_lock<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(
result.getStatus(), "error while getting last oplog entry for begin timestamp");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
const auto opTimeResult = parseOpTimeAndWallTime(result);
status = opTimeResult.getStatus();
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
// This is the top of the oplog before we query for the oldest active transaction timestamp. If
// that query returns that there are no active transactions, we will use this as the
// beginFetchingTimestamp.
const auto& defaultBeginFetchingOpTime = opTimeResult.getValue().opTime;
std::string logMsg = str::stream() << "Initial Syncer got the defaultBeginFetchingTimestamp: "
<< defaultBeginFetchingOpTime.toString();
pauseAtInitialSyncFuzzerSyncronizationPoints(logMsg);
status = _scheduleGetBeginFetchingOpTime_inlock(onCompletionGuard, defaultBeginFetchingOpTime);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
}
Status InitialSyncer::_scheduleGetBeginFetchingOpTime_inlock(
std::shared_ptr<OnCompletionGuard> onCompletionGuard,
const OpTime& defaultBeginFetchingOpTime) {
const auto preparedState = DurableTxnState_serializer(DurableTxnStateEnum::kPrepared);
const auto inProgressState = DurableTxnState_serializer(DurableTxnStateEnum::kInProgress);
// Obtain the oldest active transaction timestamp from the remote by querying their
// transactions table. To prevent oplog holes from causing this query to return an inaccurate
// timestamp, we specify an afterClusterTime of Timestamp(0, 1) so that we wait for all previous
// writes to be visible.
BSONObjBuilder cmd;
cmd.append("find", NamespaceString::kSessionTransactionsTableNamespace.coll().toString());
cmd.append("filter",
BSON("state" << BSON("$in" << BSON_ARRAY(preparedState << inProgressState))));
cmd.append("sort", BSON(SessionTxnRecord::kStartOpTimeFieldName << 1));
cmd.append("readConcern",
BSON("level"
<< "local"
<< "afterClusterTime" << Timestamp(0, 1)));
cmd.append("limit", 1);
_beginFetchingOpTimeFetcher = std::make_unique<Fetcher>(
*_attemptExec,
_syncSource,
NamespaceString::kSessionTransactionsTableNamespace.db().toString(),
cmd.obj(),
[=](const StatusWith<mongo::Fetcher::QueryResponse>& response,
mongo::Fetcher::NextAction*,
mongo::BSONObjBuilder*) mutable {
_getBeginFetchingOpTimeCallback(
response, onCompletionGuard, defaultBeginFetchingOpTime);
},
ReadPreferenceSetting::secondaryPreferredMetadata(),
RemoteCommandRequest::kNoTimeout /* find network timeout */,
RemoteCommandRequest::kNoTimeout /* getMore network timeout */,
RemoteCommandRetryScheduler::makeRetryPolicy<ErrorCategory::RetriableError>(
numInitialSyncOplogFindAttempts.load(), executor::RemoteCommandRequest::kNoTimeout));
Status scheduleStatus = _beginFetchingOpTimeFetcher->schedule();
if (!scheduleStatus.isOK()) {
_beginFetchingOpTimeFetcher.reset();
}
return scheduleStatus;
}
void InitialSyncer::_getBeginFetchingOpTimeCallback(
const StatusWith<Fetcher::QueryResponse>& result,
std::shared_ptr<OnCompletionGuard> onCompletionGuard,
const OpTime& defaultBeginFetchingOpTime) {
stdx::unique_lock<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(
result.getStatus(),
"error while getting oldest active transaction timestamp for begin fetching timestamp");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
const auto docs = result.getValue().documents;
if (docs.size() > 1) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::TooManyMatchingDocuments,
str::stream() << "Expected to receive one document for the oldest active "
"transaction entry, but received: "
<< docs.size() << ". First: " << redact(docs.front())
<< ". Last: " << redact(docs.back())));
return;
}
// Set beginFetchingOpTime if the oldest active transaction timestamp actually exists. Otherwise
// use the sync source's top of the oplog from before querying for the oldest active transaction
// timestamp. This will mean that even if a transaction is started on the sync source after
// querying for the oldest active transaction timestamp, the node will still fetch its oplog
// entries.
OpTime beginFetchingOpTime = defaultBeginFetchingOpTime;
if (docs.size() != 0) {
auto entry = SessionTxnRecord::parse(
IDLParserErrorContext("oldest active transaction optime for initial sync"),
docs.front());
auto optime = entry.getStartOpTime();
if (optime) {
beginFetchingOpTime = optime.get();
}
}
std::string logMsg = str::stream()
<< "Initial Syncer got the beginFetchingTimestamp: " << beginFetchingOpTime.toString();
pauseAtInitialSyncFuzzerSyncronizationPoints(logMsg);
if (MONGO_unlikely(initialSyncHangAfterGettingBeginFetchingTimestamp.shouldFail())) {
LOGV2(21176, "initialSyncHangAfterGettingBeginFetchingTimestamp fail point enabled");
initialSyncHangAfterGettingBeginFetchingTimestamp.pauseWhileSet();
}
// Since the beginFetchingOpTime is retrieved before significant work is done copying
// data from the sync source, we allow the OplogEntryFetcher to use its default retry strategy
// which retries up to 'numInitialSyncOplogFindAttempts' times'. This will fail relatively
// quickly in the presence of network errors, allowing us to choose a different sync source.
status = _scheduleLastOplogEntryFetcher_inlock(
[=](const StatusWith<mongo::Fetcher::QueryResponse>& response,
mongo::Fetcher::NextAction*,
mongo::BSONObjBuilder*) mutable {
_lastOplogEntryFetcherCallbackForBeginApplyingTimestamp(
response, onCompletionGuard, beginFetchingOpTime);
},
kFetcherHandlesRetries);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
}
void InitialSyncer::_lastOplogEntryFetcherCallbackForBeginApplyingTimestamp(
const StatusWith<Fetcher::QueryResponse>& result,
std::shared_ptr<OnCompletionGuard> onCompletionGuard,
OpTime& beginFetchingOpTime) {
stdx::unique_lock<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(
result.getStatus(), "error while getting last oplog entry for begin timestamp");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
const auto opTimeResult = parseOpTimeAndWallTime(result);
status = opTimeResult.getStatus();
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
const auto& lastOpTime = opTimeResult.getValue().opTime;
std::string logMsg = str::stream()
<< "Initial Syncer got the beginApplyingTimestamp: " << lastOpTime.toString();
pauseAtInitialSyncFuzzerSyncronizationPoints(logMsg);
BSONObjBuilder queryBob;
queryBob.append("find", NamespaceString::kServerConfigurationNamespace.coll());
auto filterBob = BSONObjBuilder(queryBob.subobjStart("filter"));
filterBob.append("_id", multiversion::kParameterName);
filterBob.done();
// As part of reading the FCV, we ensure the source node's all_durable timestamp has advanced
// to at least the timestamp of the last optime that we found in the lastOplogEntryFetcher.
// When document locking is used, there could be oplog "holes" which would result in
// inconsistent initial sync data if we didn't do this.
auto readConcernBob = BSONObjBuilder(queryBob.subobjStart("readConcern"));
readConcernBob.append("afterClusterTime", lastOpTime.getTimestamp());
readConcernBob.done();
_fCVFetcher = std::make_unique<Fetcher>(
*_attemptExec,
_syncSource,
NamespaceString::kServerConfigurationNamespace.db().toString(),
queryBob.obj(),
[=](const StatusWith<mongo::Fetcher::QueryResponse>& response,
mongo::Fetcher::NextAction*,
mongo::BSONObjBuilder*) mutable {
_fcvFetcherCallback(response, onCompletionGuard, lastOpTime, beginFetchingOpTime);
},
ReadPreferenceSetting::secondaryPreferredMetadata(),
RemoteCommandRequest::kNoTimeout /* find network timeout */,
RemoteCommandRequest::kNoTimeout /* getMore network timeout */,
RemoteCommandRetryScheduler::makeRetryPolicy<ErrorCategory::RetriableError>(
numInitialSyncOplogFindAttempts.load(), executor::RemoteCommandRequest::kNoTimeout));
Status scheduleStatus = _fCVFetcher->schedule();
if (!scheduleStatus.isOK()) {
_fCVFetcher.reset();
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, scheduleStatus);
return;
}
}
void InitialSyncer::_fcvFetcherCallback(const StatusWith<Fetcher::QueryResponse>& result,
std::shared_ptr<OnCompletionGuard> onCompletionGuard,
const OpTime& lastOpTime,
OpTime& beginFetchingOpTime) {
stdx::unique_lock<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(
result.getStatus(), "error while getting the remote feature compatibility version");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
const auto docs = result.getValue().documents;
if (docs.size() > 1) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::TooManyMatchingDocuments,
str::stream() << "Expected to receive one feature compatibility version "
"document, but received: "
<< docs.size() << ". First: " << redact(docs.front())
<< ". Last: " << redact(docs.back())));
return;
}
const auto hasDoc = docs.begin() != docs.end();
if (!hasDoc) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::IncompatibleServerVersion,
"Sync source had no feature compatibility version document"));
return;
}
auto fCVParseSW = FeatureCompatibilityVersionParser::parse(docs.front());
if (!fCVParseSW.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, fCVParseSW.getStatus());
return;
}
auto version = fCVParseSW.getValue();
// Changing the featureCompatibilityVersion during initial sync is unsafe.
// (Generic FCV reference): This FCV check should exist across LTS binary versions.
if (serverGlobalParams.featureCompatibility.isUpgradingOrDowngrading(version)) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::IncompatibleServerVersion,
str::stream() << "Sync source had unsafe feature compatibility version: "
<< multiversion::toString(version)));
return;
}
if (MONGO_unlikely(initialSyncHangBeforeSplittingControlFlow.shouldFail())) {
lock.unlock();
LOGV2(5032000,
"initial sync - initialSyncHangBeforeSplittingControlFlow fail point "
"enabled. Blocking until fail point is disabled.");
while (MONGO_unlikely(initialSyncHangBeforeSplittingControlFlow.shouldFail()) &&
!_isShuttingDown()) {
mongo::sleepsecs(1);
}
lock.lock();
}
// This is where the flow of control starts to split into two parallel tracks:
// - oplog fetcher
// - data cloning and applier
_sharedData =
std::make_unique<InitialSyncSharedData>(_rollbackChecker->getBaseRBID(),
_allowedOutageDuration,
getGlobalServiceContext()->getFastClockSource());
_client = _createClientFn();
_initialSyncState = std::make_unique<InitialSyncState>(std::make_unique<AllDatabaseCloner>(
_sharedData.get(), _syncSource, _client.get(), _storage, _writerPool));
// Create oplog applier.
auto consistencyMarkers = _replicationProcess->getConsistencyMarkers();
OplogApplier::Options options(OplogApplication::Mode::kInitialSync);
options.beginApplyingOpTime = lastOpTime;
_oplogApplier = _dataReplicatorExternalState->makeOplogApplier(_oplogBuffer.get(),
&noopOplogApplierObserver,
consistencyMarkers,
_storage,
options,
_writerPool);
_initialSyncState->beginApplyingTimestamp = lastOpTime.getTimestamp();
_initialSyncState->beginFetchingTimestamp = beginFetchingOpTime.getTimestamp();
invariant(_initialSyncState->beginApplyingTimestamp >=
_initialSyncState->beginFetchingTimestamp,
str::stream() << "beginApplyingTimestamp was less than beginFetchingTimestamp. "
"beginApplyingTimestamp: "
<< _initialSyncState->beginApplyingTimestamp.toBSON()
<< " beginFetchingTimestamp: "
<< _initialSyncState->beginFetchingTimestamp.toBSON());
invariant(!result.getValue().documents.empty());
LOGV2_DEBUG(4431600,
2,
"Setting begin applying timestamp to {beginApplyingTimestamp}, ns: "
"{namespace} and the begin fetching timestamp to {beginFetchingTimestamp}",
"Setting begin applying timestamp and begin fetching timestamp",
"beginApplyingTimestamp"_attr = _initialSyncState->beginApplyingTimestamp,
"namespace"_attr = NamespaceString::kRsOplogNamespace,
"beginFetchingTimestamp"_attr = _initialSyncState->beginFetchingTimestamp);
const auto configResult = _dataReplicatorExternalState->getCurrentConfig();
status = configResult.getStatus();
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
_initialSyncState.reset();
return;
}
const auto& config = configResult.getValue();
OplogFetcher::Config oplogFetcherConfig(
beginFetchingOpTime,
_syncSource,
config,
_rollbackChecker->getBaseRBID(),
initialSyncOplogFetcherBatchSize,
OplogFetcher::RequireFresherSyncSource::kDontRequireFresherSyncSource);
oplogFetcherConfig.startingPoint = OplogFetcher::StartingPoint::kEnqueueFirstDoc;
_oplogFetcher = (*_createOplogFetcherFn)(
*_attemptExec,
std::make_unique<OplogFetcherRestartDecisionInitialSyncer>(
_sharedData.get(), _opts.oplogFetcherMaxFetcherRestarts),
_dataReplicatorExternalState.get(),
[=](OplogFetcher::Documents::const_iterator first,
OplogFetcher::Documents::const_iterator last,
const OplogFetcher::DocumentsInfo& info) {
return _enqueueDocuments(first, last, info);
},
[=](const Status& s, int rbid) { _oplogFetcherCallback(s, onCompletionGuard); },
std::move(oplogFetcherConfig));
LOGV2_DEBUG(21178,
2,
"Starting OplogFetcher: {oplogFetcher}",
"Starting OplogFetcher",
"oplogFetcher"_attr = _oplogFetcher->toString());
// _startupComponent_inlock is shutdown-aware.
status = _startupComponent_inlock(_oplogFetcher);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
_initialSyncState->allDatabaseCloner.reset();
return;
}
if (MONGO_unlikely(initialSyncHangBeforeCopyingDatabases.shouldFail())) {
lock.unlock();
// This could have been done with a scheduleWorkAt but this is used only by JS tests where
// we run with multiple threads so it's fine to spin on this thread.
// This log output is used in js tests so please leave it.
LOGV2(21179,
"initial sync - initialSyncHangBeforeCopyingDatabases fail point "
"enabled. Blocking until fail point is disabled.");
while (MONGO_unlikely(initialSyncHangBeforeCopyingDatabases.shouldFail()) &&
!_isShuttingDown()) {
mongo::sleepsecs(1);
}
lock.lock();
}
LOGV2_DEBUG(21180,
2,
"Starting AllDatabaseCloner: {allDatabaseCloner}",
"Starting AllDatabaseCloner",
"allDatabaseCloner"_attr = _initialSyncState->allDatabaseCloner->toString());
auto [startClonerFuture, startCloner] =
_initialSyncState->allDatabaseCloner->runOnExecutorEvent(*_clonerAttemptExec);
// runOnExecutorEvent ensures the future is not ready unless an error has occurred.
if (startClonerFuture.isReady()) {
status = startClonerFuture.getNoThrow();
invariant(!status.isOK());
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
_initialSyncState->allDatabaseClonerFuture =
std::move(startClonerFuture).onCompletion([this, onCompletionGuard](Status status) mutable {
// The completion guard must run on the main executor, and never inline. In unit tests,
// without the executor call, it would run on the wrong executor. In both production
// and in unit tests, if the cloner finishes very quickly, the callback could run
// in-line and result in self-deadlock.
stdx::unique_lock<Latch> lock(_mutex);
auto exec_status = (*_attemptExec)
->scheduleWork([this, status, onCompletionGuard](
executor::TaskExecutor::CallbackArgs args) {
_allDatabaseClonerCallback(status, onCompletionGuard);
});
if (!exec_status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock,
exec_status.getStatus());
// In the shutdown case, it is possible the completion guard will be run
// from this thread (since the lambda holding another copy didn't schedule).
// If it does, we will self-deadlock if we're holding the lock, so release it.
lock.unlock();
}
// In unit tests, this reset ensures the completion guard does not run during the
// destruction of the lambda (which occurs on the wrong executor), except in the
// shutdown case.
onCompletionGuard.reset();
});
lock.unlock();
// Start (and therefore finish) the cloners outside the lock. This ensures onCompletion
// is not run with the mutex held, which would result in self-deadlock.
(*_clonerAttemptExec)->signalEvent(startCloner);
}
void InitialSyncer::_oplogFetcherCallback(const Status& oplogFetcherFinishStatus,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
stdx::lock_guard<Latch> lock(_mutex);
LOGV2(21181,
"Finished fetching oplog during initial sync: {oplogFetcherFinishStatus}. Last fetched "
"optime: {lastFetched}",
"Finished fetching oplog during initial sync",
"oplogFetcherFinishStatus"_attr = redact(oplogFetcherFinishStatus),
"lastFetched"_attr = _lastFetched.toString());
auto status = _checkForShutdownAndConvertStatus_inlock(
oplogFetcherFinishStatus, "error fetching oplog during initial sync");
// When the OplogFetcher completes early (instead of being canceled at shutdown), we log and let
// our reference to 'onCompletionGuard' go out of scope. Since we know the
// DatabasesCloner/MultiApplier will still have a reference to it, the actual function within
// the guard won't be fired yet.
// It is up to the DatabasesCloner and MultiApplier to determine if they can proceed without any
// additional data going into the oplog buffer.
// It is not common for the OplogFetcher to return with an OK status. The only time it returns
// an OK status is when the 'stopReplProducer' fail point is enabled, which causes the
// OplogFetcher to ignore the current sync source response and return early.
if (status.isOK()) {
LOGV2(21182,
"Finished fetching oplog fetching early. Last fetched optime: {lastFetched}",
"Finished fetching oplog fetching early",
"lastFetched"_attr = _lastFetched.toString());
return;
}
// During normal operation, this call to onCompletion->setResultAndCancelRemainingWork_inlock
// is a no-op because the other thread running the DatabasesCloner or MultiApplier will already
// have called it with the success/failed status.
// The OplogFetcher does not finish on its own because of the oplog tailing query it runs on the
// sync source. The most common OplogFetcher completion status is CallbackCanceled due to either
// a shutdown request or completion of the data cloning and oplog application phases.
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
}
void InitialSyncer::_allDatabaseClonerCallback(
const Status& databaseClonerFinishStatus,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
LOGV2(21183,
"Finished cloning data: {databaseClonerFinishStatus}. Beginning oplog replay.",
"Finished cloning data. Beginning oplog replay",
"databaseClonerFinishStatus"_attr = redact(databaseClonerFinishStatus));
_client->shutdownAndDisallowReconnect();
if (MONGO_unlikely(initialSyncHangAfterDataCloning.shouldFail())) {
// This could have been done with a scheduleWorkAt but this is used only by JS tests where
// we run with multiple threads so it's fine to spin on this thread.
// This log output is used in js tests so please leave it.
LOGV2(21184,
"initial sync - initialSyncHangAfterDataCloning fail point "
"enabled. Blocking until fail point is disabled.");
while (MONGO_unlikely(initialSyncHangAfterDataCloning.shouldFail()) && !_isShuttingDown()) {
mongo::sleepsecs(1);
}
}
stdx::lock_guard<Latch> lock(_mutex);
_client.reset();
auto status = _checkForShutdownAndConvertStatus_inlock(databaseClonerFinishStatus,
"error cloning databases");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
// Since the stopTimestamp is retrieved after we have done all the work of retrieving collection
// data, we handle retries within this class by retrying for
// 'initialSyncTransientErrorRetryPeriodSeconds' (default 24 hours). This is the same retry
// strategy used when retrieving collection data, and avoids retrieving all the data and then
// throwing it away due to a transient network outage.
status = _scheduleLastOplogEntryFetcher_inlock(
[=](const StatusWith<mongo::Fetcher::QueryResponse>& status,
mongo::Fetcher::NextAction*,
mongo::BSONObjBuilder*) {
_lastOplogEntryFetcherCallbackForStopTimestamp(status, onCompletionGuard);
},
kInitialSyncerHandlesRetries);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
}
void InitialSyncer::_lastOplogEntryFetcherCallbackForStopTimestamp(
const StatusWith<Fetcher::QueryResponse>& result,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
OpTimeAndWallTime resultOpTimeAndWallTime = {OpTime(), Date_t()};
{
stdx::lock_guard<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(
result.getStatus(), "error fetching last oplog entry for stop timestamp");
if (_shouldRetryError(lock, status)) {
auto scheduleStatus =
(*_attemptExec)
->scheduleWork([this,
onCompletionGuard](executor::TaskExecutor::CallbackArgs args) {
// It is not valid to schedule the retry from within this callback,
// hence we schedule a lambda to schedule the retry.
stdx::lock_guard<Latch> lock(_mutex);
// Since the stopTimestamp is retrieved after we have done all the work of
// retrieving collection data, we handle retries within this class by
// retrying for 'initialSyncTransientErrorRetryPeriodSeconds' (default 24
// hours). This is the same retry strategy used when retrieving collection
// data, and avoids retrieving all the data and then throwing it away due to
// a transient network outage.
auto status = _scheduleLastOplogEntryFetcher_inlock(
[=](const StatusWith<mongo::Fetcher::QueryResponse>& status,
mongo::Fetcher::NextAction*,
mongo::BSONObjBuilder*) {
_lastOplogEntryFetcherCallbackForStopTimestamp(status,
onCompletionGuard);
},
kInitialSyncerHandlesRetries);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
}
});
if (scheduleStatus.isOK())
return;
// If scheduling failed, we're shutting down and cannot retry.
// So just continue with the original failed status.
}
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
auto&& optimeStatus = parseOpTimeAndWallTime(result);
if (!optimeStatus.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock,
optimeStatus.getStatus());
return;
}
resultOpTimeAndWallTime = optimeStatus.getValue();
_initialSyncState->stopTimestamp = resultOpTimeAndWallTime.opTime.getTimestamp();
// If the beginFetchingTimestamp is different from the stopTimestamp, it indicates that
// there are oplog entries fetched by the oplog fetcher that need to be written to the oplog
// and/or there are operations that need to be applied.
if (_initialSyncState->beginFetchingTimestamp != _initialSyncState->stopTimestamp) {
invariant(_lastApplied.opTime.isNull());
_checkApplierProgressAndScheduleGetNextApplierBatch_inlock(lock, onCompletionGuard);
return;
}
}
// Oplog at sync source has not advanced since we started cloning databases, so we use the last
// oplog entry to seed the oplog before checking the rollback ID.
{
const auto& documents = result.getValue().documents;
invariant(!documents.empty());
const BSONObj oplogSeedDoc = documents.front();
LOGV2_DEBUG(21185,
2,
"Inserting oplog seed document: {oplogSeedDocument}",
"Inserting oplog seed document",
"oplogSeedDocument"_attr = oplogSeedDoc);
auto opCtx = makeOpCtx();
// StorageInterface::insertDocument() has to be called outside the lock because we may
// override its behavior in tests. See InitialSyncerReturnsCallbackCanceledAndDoesNot-
// ScheduleRollbackCheckerIfShutdownAfterInsertingInsertOplogSeedDocument in
// initial_syncer_test.cpp
auto status = _storage->insertDocument(
opCtx.get(),
NamespaceString::kRsOplogNamespace,
TimestampedBSONObj{oplogSeedDoc, resultOpTimeAndWallTime.opTime.getTimestamp()},
resultOpTimeAndWallTime.opTime.getTerm());
if (!status.isOK()) {
stdx::lock_guard<Latch> lock(_mutex);
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
const bool orderedCommit = true;
_storage->oplogDiskLocRegister(
opCtx.get(), resultOpTimeAndWallTime.opTime.getTimestamp(), orderedCommit);
}
stdx::lock_guard<Latch> lock(_mutex);
_lastApplied = resultOpTimeAndWallTime;
LOGV2(21186,
"No need to apply operations. (currently at {stopTimestamp})",
"No need to apply operations",
"stopTimestamp"_attr = _initialSyncState->stopTimestamp.toBSON());
// This sets the error in 'onCompletionGuard' and shuts down the OplogFetcher on error.
_scheduleRollbackCheckerCheckForRollback_inlock(lock, onCompletionGuard);
}
void InitialSyncer::_getNextApplierBatchCallback(
const executor::TaskExecutor::CallbackArgs& callbackArgs,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) noexcept try {
stdx::lock_guard<Latch> lock(_mutex);
auto status =
_checkForShutdownAndConvertStatus_inlock(callbackArgs, "error getting next applier batch");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
auto batchResult = _getNextApplierBatch_inlock();
if (!batchResult.isOK()) {
LOGV2_WARNING(21196,
"Failure creating next apply batch: {error}",
"Failure creating next apply batch",
"error"_attr = redact(batchResult.getStatus()));
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, batchResult.getStatus());
return;
}
std::string logMsg = str::stream()
<< "Initial Syncer is about to apply the next oplog batch of size: "
<< batchResult.getValue().size();
pauseAtInitialSyncFuzzerSyncronizationPoints(logMsg);
if (MONGO_unlikely(failInitialSyncBeforeApplyingBatch.shouldFail())) {
LOGV2(21187,
"initial sync - failInitialSyncBeforeApplyingBatch fail point enabled. Pausing until "
"fail point is disabled, then will fail initial sync");
failInitialSyncBeforeApplyingBatch.pauseWhileSet();
status = Status(ErrorCodes::CallbackCanceled,
"failInitialSyncBeforeApplyingBatch fail point enabled");
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
// Schedule MultiApplier if we have operations to apply.
const auto& ops = batchResult.getValue();
if (!ops.empty()) {
_fetchCount.store(0);
MultiApplier::MultiApplyFn applyBatchOfOperationsFn = [this](OperationContext* opCtx,
std::vector<OplogEntry> ops) {
return _oplogApplier->applyOplogBatch(opCtx, std::move(ops));
};
OpTime lastApplied = ops.back().getOpTime();
Date_t lastAppliedWall = ops.back().getWallClockTime();
auto numApplied = ops.size();
MultiApplier::CallbackFn onCompletionFn = [=](const Status& s) {
return _multiApplierCallback(
s, {lastApplied, lastAppliedWall}, numApplied, onCompletionGuard);
};
_applier = std::make_unique<MultiApplier>(
*_attemptExec, ops, std::move(applyBatchOfOperationsFn), std::move(onCompletionFn));
status = _startupComponent_inlock(_applier);
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
return;
}
// If the oplog fetcher is no longer running (completed successfully) and the oplog buffer is
// empty, we are not going to make any more progress with this initial sync. Report progress so
// far and return a RemoteResultsUnavailable error.
if (!_oplogFetcher->isActive()) {
static constexpr char msg[] =
"The oplog fetcher is no longer running and we have applied all the oplog entries "
"in the oplog buffer. Aborting this initial sync attempt";
LOGV2(21188,
msg,
"lastApplied"_attr = _lastApplied.opTime,
"lastFetched"_attr = _lastFetched,
"operationsApplied"_attr = _initialSyncState->appliedOps);
status = Status(ErrorCodes::RemoteResultsUnavailable,
str::stream()
<< msg << ". Last applied: " << _lastApplied.opTime.toString()
<< ". Last fetched: " << _lastFetched.toString()
<< ". Number of operations applied: " << _initialSyncState->appliedOps);
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
// If there are no operations at the moment to apply and the oplog fetcher is still waiting on
// the sync source, we'll check the oplog buffer again in
// '_opts.getApplierBatchCallbackRetryWait' ms.
auto when = (*_attemptExec)->now() + _opts.getApplierBatchCallbackRetryWait;
status = _scheduleWorkAtAndSaveHandle_inlock(
when,
[=](const CallbackArgs& args) { _getNextApplierBatchCallback(args, onCompletionGuard); },
&_getNextApplierBatchHandle,
"_getNextApplierBatchCallback");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
} catch (const DBException&) {
// Report exception as an initial syncer failure.
stdx::unique_lock<Latch> lock(_mutex);
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, exceptionToStatus());
}
void InitialSyncer::_multiApplierCallback(const Status& multiApplierStatus,
OpTimeAndWallTime lastApplied,
std::uint32_t numApplied,
std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
stdx::lock_guard<Latch> lock(_mutex);
auto status =
_checkForShutdownAndConvertStatus_inlock(multiApplierStatus, "error applying batch");
// Set to cause initial sync to fassert instead of restart if applying a batch fails, so that
// tests can be robust to network errors but not oplog idempotency errors.
if (MONGO_unlikely(initialSyncFassertIfApplyingBatchFails.shouldFail())) {
LOGV2(21189, "initialSyncFassertIfApplyingBatchFails fail point enabled");
fassert(31210, status);
}
if (!status.isOK()) {
LOGV2_ERROR(21199,
"Failed to apply batch due to '{error}'",
"Failed to apply batch",
"error"_attr = redact(status));
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
_initialSyncState->appliedOps += numApplied;
_lastApplied = lastApplied;
const auto lastAppliedOpTime = _lastApplied.opTime;
_opts.setMyLastOptime(_lastApplied);
// Update oplog visibility after applying a batch so that while applying transaction oplog
// entries, the TransactionHistoryIterator can get earlier oplog entries associated with the
// transaction. Note that setting the oplog visibility timestamp here will be safe even if
// initial sync was restarted because until initial sync ends, no one else will try to read our
// oplog. It is also safe even if we tried to read from our own oplog because we never try to
// read from the oplog before applying at least one batch and therefore setting a value for the
// oplog visibility timestamp.
auto opCtx = makeOpCtx();
const bool orderedCommit = true;
_storage->oplogDiskLocRegister(opCtx.get(), lastAppliedOpTime.getTimestamp(), orderedCommit);
_checkApplierProgressAndScheduleGetNextApplierBatch_inlock(lock, onCompletionGuard);
}
void InitialSyncer::_rollbackCheckerCheckForRollbackCallback(
const RollbackChecker::Result& result, std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
stdx::lock_guard<Latch> lock(_mutex);
auto status = _checkForShutdownAndConvertStatus_inlock(result.getStatus(),
"error while getting last rollback ID");
if (_shouldRetryError(lock, status)) {
LOGV2_DEBUG(21190,
1,
"Retrying rollback checker because of network error {error}",
"Retrying rollback checker because of network error",
"error"_attr = status);
_scheduleRollbackCheckerCheckForRollback_inlock(lock, onCompletionGuard);
return;
}
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
auto hasHadRollback = result.getValue();
if (hasHadRollback) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::UnrecoverableRollbackError,
str::stream() << "Rollback occurred on our sync source " << _syncSource
<< " during initial sync"));
return;
}
if (MONGO_unlikely(initialSyncHangBeforeCompletingOplogFetching.shouldFail())) {
LOGV2(4599500, "initialSyncHangBeforeCompletingOplogFetching fail point enabled");
initialSyncHangBeforeCompletingOplogFetching.pauseWhileSet();
}
// Success!
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, _lastApplied);
}
void InitialSyncer::_finishInitialSyncAttempt(const StatusWith<OpTimeAndWallTime>& lastApplied) {
// Since _finishInitialSyncAttempt can be called from any component's callback function or
// scheduled task, it is possible that we may not be in a TaskExecutor-managed thread when this
// function is invoked.
// For example, if CollectionCloner fails while inserting documents into the
// CollectionBulkLoader, we will get here via one of CollectionCloner's TaskRunner callbacks
// which has an active OperationContext bound to the current Client. This would lead to an
// invariant when we attempt to create a new OperationContext for _tearDown(opCtx).
// To avoid this, we schedule _finishCallback against the TaskExecutor rather than calling it
// here synchronously.
// Unless dismissed, a scope guard will schedule _finishCallback() upon exiting this function.
// Since it is a requirement that _finishCallback be called outside the lock (which is possible
// if the task scheduling fails and we have to invoke _finishCallback() synchronously), we
// declare the scope guard before the lock guard.
auto result = lastApplied;
ScopeGuard finishCallbackGuard([this, &result] {
auto scheduleResult = _exec->scheduleWork(
[=](const mongo::executor::TaskExecutor::CallbackArgs&) { _finishCallback(result); });
if (!scheduleResult.isOK()) {
LOGV2_WARNING(21197,
"Unable to schedule initial syncer completion task due to "
"{error}. Running callback on current thread.",
"Unable to schedule initial syncer completion task. Running callback on "
"current thread",
"error"_attr = redact(scheduleResult.getStatus()));
_finishCallback(result);
}
});
LOGV2(21191, "Initial sync attempt finishing up");
stdx::lock_guard<Latch> lock(_mutex);
auto runTime = _initialSyncState ? _initialSyncState->timer.millis() : 0;
int rollBackId = -1;
int operationsRetried = 0;
int totalTimeUnreachableMillis = 0;
if (_sharedData) {
stdx::lock_guard<InitialSyncSharedData> sdLock(*_sharedData);
rollBackId = _sharedData->getRollBackId();
operationsRetried = _sharedData->getTotalRetries(sdLock);
totalTimeUnreachableMillis =
durationCount<Milliseconds>(_sharedData->getTotalTimeUnreachable(sdLock));
}
if (MONGO_unlikely(failAndHangInitialSync.shouldFail())) {
LOGV2(21193, "failAndHangInitialSync fail point enabled");
failAndHangInitialSync.pauseWhileSet();
result = Status(ErrorCodes::InternalError, "failAndHangInitialSync fail point enabled");
}
_stats.initialSyncAttemptInfos.emplace_back(
InitialSyncer::InitialSyncAttemptInfo{runTime,
result.getStatus(),
_syncSource,
rollBackId,
operationsRetried,
totalTimeUnreachableMillis});
if (!result.isOK()) {
// This increments the number of failed attempts for the current initial sync request.
++_stats.failedInitialSyncAttempts;
// This increments the number of failed attempts across all initial sync attempts since
// process startup.
initialSyncFailedAttempts.increment();
}
bool hasRetries = _stats.failedInitialSyncAttempts < _stats.maxFailedInitialSyncAttempts;
LOGV2(21192,
"Initial sync status: {status}, initial sync attempt statistics: {statistics}",
"Initial sync status and statistics",
"status"_attr = result.isOK() ? "successful" : (hasRetries ? "in_progress" : "failed"),
"statistics"_attr = redact(_getInitialSyncProgress_inlock()));
if (result.isOK()) {
// Scope guard will invoke _finishCallback().
return;
}
LOGV2_ERROR(21200,
"Initial sync attempt failed -- attempts left: "
"{attemptsLeft} cause: "
"{error}",
"Initial sync attempt failed",
"attemptsLeft"_attr =
(_stats.maxFailedInitialSyncAttempts - _stats.failedInitialSyncAttempts),
"error"_attr = redact(result.getStatus()));
// Check if need to do more retries.
if (!hasRetries) {
LOGV2_FATAL_CONTINUE(21202,
"The maximum number of retries have been exhausted for initial sync");
initialSyncFailures.increment();
// Scope guard will invoke _finishCallback().
return;
}
_attemptExec = std::make_unique<executor::ScopedTaskExecutor>(
_exec, Status(ErrorCodes::CallbackCanceled, "Initial Sync Attempt Canceled"));
_clonerAttemptExec = std::make_unique<executor::ScopedTaskExecutor>(
_clonerExec, Status(ErrorCodes::CallbackCanceled, "Initial Sync Attempt Canceled"));
_attemptCanceled = false;
auto when = (*_attemptExec)->now() + _opts.initialSyncRetryWait;
auto status = _scheduleWorkAtAndSaveHandle_inlock(
when,
[=](const executor::TaskExecutor::CallbackArgs& args) {
_startInitialSyncAttemptCallback(
args, _stats.failedInitialSyncAttempts, _stats.maxFailedInitialSyncAttempts);
},
&_startInitialSyncAttemptHandle,
str::stream() << "_startInitialSyncAttemptCallback-" << _stats.failedInitialSyncAttempts);
if (!status.isOK()) {
result = status;
// Scope guard will invoke _finishCallback().
return;
}
// Next initial sync attempt scheduled successfully and we do not need to call _finishCallback()
// until the next initial sync attempt finishes.
finishCallbackGuard.dismiss();
}
void InitialSyncer::_finishCallback(StatusWith<OpTimeAndWallTime> lastApplied) {
// After running callback function, clear '_onCompletion' to release any resources that might be
// held by this function object.
// '_onCompletion' must be moved to a temporary copy and destroyed outside the lock in case
// there is any logic that's invoked at the function object's destruction that might call into
// this InitialSyncer. 'onCompletion' must be destroyed outside the lock and this should happen
// before we transition the state to Complete.
decltype(_onCompletion) onCompletion;
{
stdx::lock_guard<Latch> lock(_mutex);
auto opCtx = makeOpCtx();
_tearDown_inlock(opCtx.get(), lastApplied);
invariant(_onCompletion);
std::swap(_onCompletion, onCompletion);
}
if (MONGO_unlikely(initialSyncHangBeforeFinish.shouldFail())) {
// This log output is used in js tests so please leave it.
LOGV2(21194,
"initial sync - initialSyncHangBeforeFinish fail point "
"enabled. Blocking until fail point is disabled.");
while (MONGO_unlikely(initialSyncHangBeforeFinish.shouldFail()) && !_isShuttingDown()) {
mongo::sleepsecs(1);
}
}
// Any _retryingOperation is no longer active. This must be done before signalling state
// Complete.
_retryingOperation = boost::none;
// Completion callback must be invoked outside mutex.
try {
onCompletion(lastApplied);
} catch (...) {
LOGV2_WARNING(21198,
"initial syncer finish callback threw exception: {error}",
"Initial syncer finish callback threw exception",
"error"_attr = redact(exceptionToStatus()));
}
// Destroy the remaining reference to the completion callback before we transition the state to
// Complete so that callers can expect any resources bound to '_onCompletion' to be released
// before InitialSyncer::join() returns.
onCompletion = {};
{
stdx::lock_guard<Latch> lock(_mutex);
invariant(_state != State::kComplete);
_state = State::kComplete;
_stateCondition.notify_all();
// Clear the initial sync progress after an initial sync attempt has been successfully
// completed.
if (lastApplied.isOK() && !MONGO_unlikely(skipClearInitialSyncState.shouldFail())) {
_initialSyncState.reset();
}
// Destroy shared references to executors.
_attemptExec = nullptr;
_clonerAttemptExec = nullptr;
_clonerExec = nullptr;
_exec = nullptr;
}
if (MONGO_unlikely(initialSyncHangAfterFinish.shouldFail())) {
LOGV2(5825800,
"initial sync finished - initialSyncHangAfterFinish fail point "
"enabled. Blocking until fail point is disabled.");
while (MONGO_unlikely(initialSyncHangAfterFinish.shouldFail()) && !_isShuttingDown()) {
mongo::sleepsecs(1);
}
}
}
Status InitialSyncer::_scheduleLastOplogEntryFetcher_inlock(
Fetcher::CallbackFn callback, LastOplogEntryFetcherRetryStrategy retryStrategy) {
BSONObj query =
BSON("find" << NamespaceString::kRsOplogNamespace.coll() << "sort" << BSON("$natural" << -1)
<< "limit" << 1 << ReadConcernArgs::kReadConcernFieldName
<< ReadConcernArgs::kImplicitDefault);
_lastOplogEntryFetcher = std::make_unique<Fetcher>(
*_attemptExec,
_syncSource,
NamespaceString::kRsOplogNamespace.db().toString(),
query,
callback,
ReadPreferenceSetting::secondaryPreferredMetadata(),
RemoteCommandRequest::kNoTimeout /* find network timeout */,
RemoteCommandRequest::kNoTimeout /* getMore network timeout */,
(retryStrategy == kFetcherHandlesRetries)
? RemoteCommandRetryScheduler::makeRetryPolicy<ErrorCategory::RetriableError>(
numInitialSyncOplogFindAttempts.load(),
executor::RemoteCommandRequest::kNoTimeout)
: RemoteCommandRetryScheduler::makeNoRetryPolicy());
Status scheduleStatus = _lastOplogEntryFetcher->schedule();
if (!scheduleStatus.isOK()) {
_lastOplogEntryFetcher.reset();
}
return scheduleStatus;
}
void InitialSyncer::_checkApplierProgressAndScheduleGetNextApplierBatch_inlock(
const stdx::lock_guard<Latch>& lock, std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
// We should check our current state because shutdown() could have been called before
// we re-acquired the lock.
if (_isShuttingDown_inlock()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::CallbackCanceled,
"failed to schedule applier to check for "
"rollback: initial syncer is shutting down"));
return;
}
// Basic sanity check on begin/stop timestamps.
if (_initialSyncState->beginApplyingTimestamp > _initialSyncState->stopTimestamp) {
static constexpr char msg[] = "Possible rollback on sync source";
LOGV2_ERROR(21201,
msg,
"syncSource"_attr = _syncSource,
"stopTimestamp"_attr = _initialSyncState->stopTimestamp.toBSON(),
"beginApplyingTimestamp"_attr =
_initialSyncState->beginApplyingTimestamp.toBSON());
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::OplogOutOfOrder,
str::stream() << msg << " " << _syncSource.toString() << ". Currently at "
<< _initialSyncState->stopTimestamp.toBSON() << ". Started at "
<< _initialSyncState->beginApplyingTimestamp.toBSON()));
return;
}
if (_lastApplied.opTime.isNull()) {
// Check if any ops occurred while cloning or any ops need to be fetched.
invariant(_initialSyncState->beginFetchingTimestamp < _initialSyncState->stopTimestamp);
LOGV2(21195,
"Writing to the oplog and applying operations until {stopTimestamp} "
"before initial sync can complete. (started fetching at "
"{beginFetchingTimestamp} and applying at "
"{beginApplyingTimestamp})",
"Writing to the oplog and applying operations until stopTimestamp before initial "
"sync can complete",
"stopTimestamp"_attr = _initialSyncState->stopTimestamp.toBSON(),
"beginFetchingTimestamp"_attr = _initialSyncState->beginFetchingTimestamp.toBSON(),
"beginApplyingTimestamp"_attr = _initialSyncState->beginApplyingTimestamp.toBSON());
// Fall through to scheduling _getNextApplierBatchCallback().
} else if (_lastApplied.opTime.getTimestamp() >= _initialSyncState->stopTimestamp) {
// Check for rollback if we have applied far enough to be consistent.
invariant(!_lastApplied.opTime.getTimestamp().isNull());
_scheduleRollbackCheckerCheckForRollback_inlock(lock, onCompletionGuard);
return;
}
// Get another batch to apply.
// _scheduleWorkAndSaveHandle_inlock() is shutdown-aware.
auto status = _scheduleWorkAndSaveHandle_inlock(
[=](const executor::TaskExecutor::CallbackArgs& args) {
return _getNextApplierBatchCallback(args, onCompletionGuard);
},
&_getNextApplierBatchHandle,
"_getNextApplierBatchCallback");
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
}
void InitialSyncer::_scheduleRollbackCheckerCheckForRollback_inlock(
const stdx::lock_guard<Latch>& lock, std::shared_ptr<OnCompletionGuard> onCompletionGuard) {
// We should check our current state because shutdown() could have been called before
// we re-acquired the lock.
if (_isShuttingDown_inlock()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(
lock,
Status(ErrorCodes::CallbackCanceled,
"failed to schedule rollback checker to check "
"for rollback: initial syncer is shutting "
"down"));
return;
}
auto scheduleResult =
_rollbackChecker->checkForRollback([=](const RollbackChecker::Result& result) {
_rollbackCheckerCheckForRollbackCallback(result, onCompletionGuard);
});
auto status = scheduleResult.getStatus();
if (!status.isOK()) {
onCompletionGuard->setResultAndCancelRemainingWork_inlock(lock, status);
return;
}
_getLastRollbackIdHandle = scheduleResult.getValue();
return;
}
bool InitialSyncer::_shouldRetryError(WithLock lk, Status status) {
if (ErrorCodes::isRetriableError(status)) {
stdx::lock_guard<InitialSyncSharedData> sharedDataLock(*_sharedData);
return _sharedData->shouldRetryOperation(sharedDataLock, &_retryingOperation);
}
// The status was OK or some error other than a retriable error, so clear the retriable error
// state and indicate that we should not retry.
_clearRetriableError(lk);
return false;
}
void InitialSyncer::_clearRetriableError(WithLock lk) {
_retryingOperation = boost::none;
}
Status InitialSyncer::_checkForShutdownAndConvertStatus_inlock(
const executor::TaskExecutor::CallbackArgs& callbackArgs, const std::string& message) {
return _checkForShutdownAndConvertStatus_inlock(callbackArgs.status, message);
}
Status InitialSyncer::_checkForShutdownAndConvertStatus_inlock(const Status& status,
const std::string& message) {
if (_isShuttingDown_inlock()) {
return Status(ErrorCodes::CallbackCanceled, message + ": initial syncer is shutting down");
}
return status.withContext(message);
}
Status InitialSyncer::_scheduleWorkAndSaveHandle_inlock(
executor::TaskExecutor::CallbackFn work,
executor::TaskExecutor::CallbackHandle* handle,
const std::string& name) {
invariant(handle);
if (_isShuttingDown_inlock()) {
return Status(ErrorCodes::CallbackCanceled,
str::stream() << "failed to schedule work " << name
<< ": initial syncer is shutting down");
}
auto result = (*_attemptExec)->scheduleWork(std::move(work));
if (!result.isOK()) {
return result.getStatus().withContext(str::stream() << "failed to schedule work " << name);
}
*handle = result.getValue();
return Status::OK();
}
Status InitialSyncer::_scheduleWorkAtAndSaveHandle_inlock(
Date_t when,
executor::TaskExecutor::CallbackFn work,
executor::TaskExecutor::CallbackHandle* handle,
const std::string& name) {
invariant(handle);
if (_isShuttingDown_inlock()) {
return Status(ErrorCodes::CallbackCanceled,
str::stream() << "failed to schedule work " << name << " at "
<< when.toString() << ": initial syncer is shutting down");
}
auto result = (*_attemptExec)->scheduleWorkAt(when, std::move(work));
if (!result.isOK()) {
return result.getStatus().withContext(str::stream() << "failed to schedule work " << name
<< " at " << when.toString());
}
*handle = result.getValue();
return Status::OK();
}
void InitialSyncer::_cancelHandle_inlock(executor::TaskExecutor::CallbackHandle handle) {
if (!handle) {
return;
}
(*_attemptExec)->cancel(handle);
}
template <typename Component>
Status InitialSyncer::_startupComponent_inlock(Component& component) {
// It is necessary to check if shutdown or attempt cancelling happens before starting a
// component; otherwise the component may call a callback function in line which will
// cause a deadlock when the callback attempts to obtain the initial syncer mutex.
if (_isShuttingDown_inlock() || _attemptCanceled) {
component.reset();
if (_isShuttingDown_inlock()) {
return Status(ErrorCodes::CallbackCanceled,
"initial syncer shutdown while trying to call startup() on component");
} else {
return Status(
ErrorCodes::CallbackCanceled,
"initial sync attempt canceled while trying to call startup() on component");
}
}
auto status = component->startup();
if (!status.isOK()) {
component.reset();
}
return status;
}
template <typename Component>
void InitialSyncer::_shutdownComponent_inlock(Component& component) {
if (!component) {
return;
}
component->shutdown();
}
StatusWith<std::vector<OplogEntry>> InitialSyncer::_getNextApplierBatch_inlock() {
// If the fail-point is active, delay the apply batch by returning an empty batch so that
// _getNextApplierBatchCallback() will reschedule itself at a later time.
// See InitialSyncerInterface::Options::getApplierBatchCallbackRetryWait.
if (MONGO_unlikely(rsSyncApplyStop.shouldFail())) {
return std::vector<OplogEntry>();
}
// Obtain next batch of operations from OplogApplier.
auto opCtx = makeOpCtx();
OplogApplier::BatchLimits batchLimits;
batchLimits.bytes = replBatchLimitBytes.load();
batchLimits.ops = getBatchLimitOplogEntries();
// We want a batch boundary after the beginApplyingTimestamp, to make sure all oplog entries
// that are part of a transaction before that timestamp are written out before we start applying
// entries after them. This is because later entries may be commit or prepare and thus
// expect to read the partial entries from the oplog.
batchLimits.forceBatchBoundaryAfter = _initialSyncState->beginApplyingTimestamp;
return _oplogApplier->getNextApplierBatch(opCtx.get(), batchLimits);
}
StatusWith<HostAndPort> InitialSyncer::_chooseSyncSource_inlock() {
auto syncSource = _opts.syncSourceSelector->chooseNewSyncSource(_lastFetched);
if (syncSource.empty()) {
return Status{ErrorCodes::InvalidSyncSource,
str::stream() << "No valid sync source available. Our last fetched optime: "
<< _lastFetched.toString()};
}
return syncSource;
}
Status InitialSyncer::_enqueueDocuments(OplogFetcher::Documents::const_iterator begin,
OplogFetcher::Documents::const_iterator end,
const OplogFetcher::DocumentsInfo& info) {
if (info.toApplyDocumentCount == 0) {
return Status::OK();
}
if (_isShuttingDown()) {
return Status::OK();
}
invariant(_oplogBuffer);
// Wait for enough space.
_oplogApplier->waitForSpace(makeOpCtx().get(), info.toApplyDocumentBytes);
// Buffer docs for later application.
_oplogApplier->enqueue(makeOpCtx().get(), begin, end);
_lastFetched = info.lastDocument;
// TODO: updates metrics with "info".
return Status::OK();
}
std::string InitialSyncer::Stats::toString() const {
return toBSON().toString();
}
BSONObj InitialSyncer::Stats::toBSON() const {
BSONObjBuilder bob;
append(&bob);
return bob.obj();
}
void InitialSyncer::Stats::append(BSONObjBuilder* builder) const {
builder->appendNumber("failedInitialSyncAttempts",
static_cast<long long>(failedInitialSyncAttempts));
builder->appendNumber("maxFailedInitialSyncAttempts",
static_cast<long long>(maxFailedInitialSyncAttempts));
if (initialSyncStart != Date_t()) {
builder->appendDate("initialSyncStart", initialSyncStart);
auto elapsedDurationEnd = Date_t::now();
if (initialSyncEnd != Date_t()) {
builder->appendDate("initialSyncEnd", initialSyncEnd);
elapsedDurationEnd = initialSyncEnd;
}
long long elapsedMillis =
duration_cast<Milliseconds>(elapsedDurationEnd - initialSyncStart).count();
builder->appendNumber("totalInitialSyncElapsedMillis", elapsedMillis);
}
BSONArrayBuilder arrBuilder(builder->subarrayStart("initialSyncAttempts"));
for (unsigned int i = 0; i < initialSyncAttemptInfos.size(); ++i) {
arrBuilder.append(initialSyncAttemptInfos[i].toBSON());
}
arrBuilder.doneFast();
}
std::string InitialSyncer::InitialSyncAttemptInfo::toString() const {
return toBSON().toString();
}
BSONObj InitialSyncer::InitialSyncAttemptInfo::toBSON() const {
BSONObjBuilder bob;
append(&bob);
return bob.obj();
}
void InitialSyncer::InitialSyncAttemptInfo::append(BSONObjBuilder* builder) const {
builder->appendNumber("durationMillis", durationMillis);
builder->append("status", status.toString());
builder->append("syncSource", syncSource.toString());
if (rollBackId >= 0) {
builder->append("rollBackId", rollBackId);
}
builder->append("operationsRetried", operationsRetried);
builder->append("totalTimeUnreachableMillis", totalTimeUnreachableMillis);
}
bool InitialSyncer::OplogFetcherRestartDecisionInitialSyncer::shouldContinue(OplogFetcher* fetcher,
Status status) {
if (ErrorCodes::isRetriableError(status)) {
stdx::lock_guard<InitialSyncSharedData> lk(*_sharedData);
return _sharedData->shouldRetryOperation(lk, &_retryingOperation);
}
// A non-network error occured, so clear any network error and use the default restart
// strategy.
_retryingOperation = boost::none;
return _defaultDecision.shouldContinue(fetcher, status);
}
void InitialSyncer::OplogFetcherRestartDecisionInitialSyncer::fetchSuccessful(
OplogFetcher* fetcher) {
_retryingOperation = boost::none;
_defaultDecision.fetchSuccessful(fetcher);
}
} // namespace repl
} // namespace mongo
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