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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::kStorage
#include "mongo/platform/basic.h"
#include "mongo/db/index_builds_coordinator.h"
#include "mongo/db/catalog/collection_catalog.h"
#include "mongo/db/catalog/commit_quorum_options.h"
#include "mongo/db/catalog/database_holder.h"
#include "mongo/db/catalog/index_build_entry_gen.h"
#include "mongo/db/catalog/uncommitted_collections.h"
#include "mongo/db/catalog_raii.h"
#include "mongo/db/concurrency/locker.h"
#include "mongo/db/concurrency/replication_state_transition_lock_guard.h"
#include "mongo/db/concurrency/write_conflict_exception.h"
#include "mongo/db/curop.h"
#include "mongo/db/db_raii.h"
#include "mongo/db/dbhelpers.h"
#include "mongo/db/index/wildcard_key_generator.h"
#include "mongo/db/index_build_entry_helpers.h"
#include "mongo/db/op_observer.h"
#include "mongo/db/operation_context.h"
#include "mongo/db/repl/member_state.h"
#include "mongo/db/repl/replication_coordinator.h"
#include "mongo/db/repl/timestamp_block.h"
#include "mongo/db/s/collection_sharding_state.h"
#include "mongo/db/s/database_sharding_state.h"
#include "mongo/db/server_options.h"
#include "mongo/db/server_recovery.h"
#include "mongo/db/service_context.h"
#include "mongo/db/storage/durable_catalog.h"
#include "mongo/db/storage/encryption_hooks.h"
#include "mongo/db/storage/storage_util.h"
#include "mongo/db/storage/two_phase_index_build_knobs_gen.h"
#include "mongo/logv2/log.h"
#include "mongo/s/shard_key_pattern.h"
#include "mongo/util/assert_util.h"
#include "mongo/util/str.h"
#include <boost/filesystem/operations.hpp>
#include <boost/iterator/transform_iterator.hpp>
namespace mongo {
MONGO_FAIL_POINT_DEFINE(hangAfterIndexBuildFirstDrain);
MONGO_FAIL_POINT_DEFINE(hangAfterIndexBuildSecondDrain);
MONGO_FAIL_POINT_DEFINE(hangAfterIndexBuildDumpsInsertsFromBulk);
MONGO_FAIL_POINT_DEFINE(hangAfterInitializingIndexBuild);
MONGO_FAIL_POINT_DEFINE(hangBeforeCompletingAbort);
MONGO_FAIL_POINT_DEFINE(failIndexBuildOnCommit);
MONGO_FAIL_POINT_DEFINE(hangIndexBuildBeforeAbortCleanUp);
MONGO_FAIL_POINT_DEFINE(hangIndexBuildOnStepUp);
MONGO_FAIL_POINT_DEFINE(hangAfterSettingUpResumableIndexBuild);
MONGO_FAIL_POINT_DEFINE(hangIndexBuildBeforeCommit);
MONGO_FAIL_POINT_DEFINE(hangBeforeBuildingIndex);
MONGO_FAIL_POINT_DEFINE(hangIndexBuildBeforeWaitingUntilMajorityOpTime);
MONGO_FAIL_POINT_DEFINE(failSetUpResumeIndexBuild);
namespace {
constexpr StringData kCreateIndexesFieldName = "createIndexes"_sd;
constexpr StringData kCommitIndexBuildFieldName = "commitIndexBuild"_sd;
constexpr StringData kAbortIndexBuildFieldName = "abortIndexBuild"_sd;
constexpr StringData kIndexesFieldName = "indexes"_sd;
constexpr StringData kKeyFieldName = "key"_sd;
constexpr StringData kUniqueFieldName = "unique"_sd;
/**
* Checks if unique index specification is compatible with sharding configuration.
*/
void checkShardKeyRestrictions(OperationContext* opCtx,
const NamespaceString& nss,
const BSONObj& newIdxKey) {
UncommittedCollections::get(opCtx).invariantHasExclusiveAccessToCollection(opCtx, nss);
const auto collDesc = CollectionShardingState::get(opCtx, nss)->getCollectionDescription(opCtx);
if (!collDesc.isSharded())
return;
const ShardKeyPattern shardKeyPattern(collDesc.getKeyPattern());
uassert(ErrorCodes::CannotCreateIndex,
str::stream() << "cannot create unique index over " << newIdxKey
<< " with shard key pattern " << shardKeyPattern.toBSON(),
shardKeyPattern.isUniqueIndexCompatible(newIdxKey));
}
/**
* Returns true if we should build the indexes an empty collection using the IndexCatalog and
* bypass the index build registration.
*/
bool shouldBuildIndexesOnEmptyCollectionSinglePhased(OperationContext* opCtx,
const CollectionPtr& collection,
IndexBuildProtocol protocol) {
const auto& nss = collection->ns();
invariant(opCtx->lockState()->isCollectionLockedForMode(nss, MODE_X), str::stream() << nss);
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
// Check whether the replica set member's config has {buildIndexes:false} set, which means
// we are not allowed to build non-_id indexes on this server.
if (!replCoord->buildsIndexes()) {
return false;
}
// Secondaries should not bypass index build registration (and _runIndexBuild()) for two phase
// index builds because they need to report index build progress to the primary per commit
// quorum.
if (IndexBuildProtocol::kTwoPhase == protocol && replCoord->getSettings().usingReplSets() &&
!replCoord->canAcceptWritesFor(opCtx, nss)) {
return false;
}
// We use the fast count information, through Collection::numRecords(), to determine if the
// collection is empty. However, this information is either unavailable or inaccurate when the
// node is in certain replication states, such as recovery or rollback. In these cases, we
// have to build the index by scanning the collection.
auto memberState = replCoord->getMemberState();
if (memberState.rollback()) {
return false;
}
if (inReplicationRecovery(opCtx->getServiceContext())) {
return false;
}
// Now, it's fine to trust Collection::isEmpty().
// Fast counts are prone to both false positives and false negatives on unclean shutdowns. False
// negatives can cause to skip index building. And, false positives can cause mismatch in number
// of index entries among the nodes in the replica set. So, verify the collection is really
// empty by opening the WT cursor and reading the first document.
return collection->isEmpty(opCtx);
}
/**
* Removes the index build from the config.system.indexBuilds collection after the primary has
* written the commitIndexBuild or abortIndexBuild oplog entry.
*/
void removeIndexBuildEntryAfterCommitOrAbort(OperationContext* opCtx,
const NamespaceStringOrUUID& dbAndUUID,
const ReplIndexBuildState& replState) {
if (IndexBuildProtocol::kSinglePhase == replState.protocol) {
return;
}
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (!replCoord->canAcceptWritesFor(opCtx, dbAndUUID)) {
return;
}
auto status = indexbuildentryhelpers::removeIndexBuildEntry(opCtx, replState.buildUUID);
// If we fail to remove the document from config.system.indexBuilds, it is because the document
// or collection is missing. In any case, we do not need to fail the commit or abort operation.
// TODO(SERVER-47323): Do not ignore removeIndexBuildEntry() errors. Convert to fatal assertion.
if (!status.isOK()) {
LOGV2(4763501,
"Unable to remove index build from system collection. Ignoring error",
"buildUUID"_attr = replState.buildUUID,
"collectionUUID"_attr = replState.collectionUUID,
"error"_attr = status);
}
}
/**
* Replicates a commitIndexBuild oplog entry for two-phase builds, which signals downstream
* secondary nodes to commit the index build.
*/
void onCommitIndexBuild(OperationContext* opCtx,
const NamespaceString& nss,
std::shared_ptr<ReplIndexBuildState> replState) {
const auto& buildUUID = replState->buildUUID;
replState->commit(opCtx);
if (IndexBuildProtocol::kSinglePhase == replState->protocol) {
return;
}
invariant(IndexBuildProtocol::kTwoPhase == replState->protocol,
str::stream() << "onCommitIndexBuild: " << buildUUID);
invariant(opCtx->lockState()->isWriteLocked(),
str::stream() << "onCommitIndexBuild: " << buildUUID);
auto opObserver = opCtx->getServiceContext()->getOpObserver();
const auto& collUUID = replState->collectionUUID;
const auto& indexSpecs = replState->indexSpecs;
auto fromMigrate = false;
// Since two phase index builds are allowed to survive replication state transitions, we should
// check if the node is currently a primary before attempting to write to the oplog.
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (!replCoord->canAcceptWritesFor(opCtx, nss)) {
invariant(!opCtx->recoveryUnit()->getCommitTimestamp().isNull(),
str::stream() << "commitIndexBuild: " << buildUUID);
return;
}
opObserver->onCommitIndexBuild(opCtx, nss, collUUID, buildUUID, indexSpecs, fromMigrate);
}
/**
* Replicates an abortIndexBuild oplog entry for two-phase builds, which signals downstream
* secondary nodes to abort the index build.
*/
void onAbortIndexBuild(OperationContext* opCtx,
const NamespaceString& nss,
ReplIndexBuildState& replState,
const Status& cause) {
if (IndexBuildProtocol::kTwoPhase != replState.protocol) {
return;
}
invariant(opCtx->lockState()->isWriteLocked(), replState.buildUUID.toString());
auto opObserver = opCtx->getServiceContext()->getOpObserver();
auto collUUID = replState.collectionUUID;
auto fromMigrate = false;
opObserver->onAbortIndexBuild(
opCtx, nss, collUUID, replState.buildUUID, replState.indexSpecs, cause, fromMigrate);
}
/**
* We do not need synchronization with step up and step down. Dropping the RSTL is important because
* otherwise if we held the RSTL it would create deadlocks with prepared transactions on step up and
* step down. A deadlock could result if the index build was attempting to acquire a Collection S
* or X lock while a prepared transaction held a Collection IX lock, and a step down was waiting to
* acquire the RSTL in mode X.
*/
void unlockRSTL(OperationContext* opCtx) {
invariant(opCtx->lockState()->unlockRSTLforPrepare());
invariant(!opCtx->lockState()->isRSTLLocked());
}
/**
* Logs the index build failure error in a standard format.
*/
void logFailure(Status status,
const NamespaceString& nss,
std::shared_ptr<ReplIndexBuildState> replState) {
LOGV2(20649,
"Index build failed",
"buildUUID"_attr = replState->buildUUID,
"namespace"_attr = nss,
"uuid"_attr = replState->collectionUUID,
"error"_attr = status);
}
/**
* Iterates over index builds with the provided function.
*/
void forEachIndexBuild(
const std::vector<std::shared_ptr<ReplIndexBuildState>>& indexBuilds,
StringData context,
std::function<void(std::shared_ptr<ReplIndexBuildState> replState)> onIndexBuild) {
if (indexBuilds.empty()) {
return;
}
auto indexBuildLogger = [](const auto& indexBuild) {
BSONObjBuilder builder;
builder.append("buildUUID"_sd, indexBuild->buildUUID.toBSON());
builder.append("collectionUUID"_sd, indexBuild->collectionUUID.toBSON());
BSONArrayBuilder names;
for (const auto& indexName : indexBuild->indexNames) {
names.append(indexName);
}
builder.append("indexNames"_sd, names.arr());
builder.append("protocol"_sd,
indexBuild->protocol == IndexBuildProtocol::kTwoPhase ? "two phase"_sd
: "single phase"_sd);
return builder.obj();
};
auto begin = boost::make_transform_iterator(indexBuilds.begin(), indexBuildLogger);
auto end = boost::make_transform_iterator(indexBuilds.end(), indexBuildLogger);
LOGV2(20650,
"Active index builds",
"context"_attr = context,
"builds"_attr = logv2::seqLog(begin, end));
if (onIndexBuild) {
for (const auto& indexBuild : indexBuilds) {
onIndexBuild(indexBuild);
}
}
}
/**
* Updates currentOp for commitIndexBuild or abortIndexBuild.
*/
void updateCurOpForCommitOrAbort(OperationContext* opCtx, StringData fieldName, UUID buildUUID) {
BSONObjBuilder builder;
buildUUID.appendToBuilder(&builder, fieldName);
stdx::unique_lock<Client> lk(*opCtx->getClient());
auto curOp = CurOp::get(opCtx);
builder.appendElementsUnique(curOp->opDescription());
auto opDescObj = builder.obj();
curOp->setLogicalOp_inlock(LogicalOp::opCommand);
curOp->setOpDescription_inlock(opDescObj);
curOp->ensureStarted();
}
/**
* Fetches the latest oplog entry's optime. Bypasses the oplog visibility rules.
*/
repl::OpTime getLatestOplogOpTime(OperationContext* opCtx) {
// Reset the snapshot so that it is ensured to see the latest oplog entries.
opCtx->recoveryUnit()->abandonSnapshot();
// Helpers::getLast will bypass the oplog visibility rules by doing a backwards collection
// scan.
BSONObj oplogEntryBSON;
invariant(
Helpers::getLast(opCtx, NamespaceString::kRsOplogNamespace.ns().c_str(), oplogEntryBSON));
auto optime = repl::OpTime::parseFromOplogEntry(oplogEntryBSON);
invariant(optime.isOK(),
str::stream() << "Found an invalid oplog entry: " << oplogEntryBSON
<< ", error: " << optime.getStatus());
return optime.getValue();
}
/**
* Returns true if the index build is resumable.
*/
bool isIndexBuildResumable(OperationContext* opCtx,
const ReplIndexBuildState& replState,
const IndexBuildsCoordinator::IndexBuildOptions& indexBuildOptions) {
if (replState.protocol != IndexBuildProtocol::kTwoPhase) {
return false;
}
if (indexBuildOptions.applicationMode != IndexBuildsCoordinator::ApplicationMode::kNormal) {
return false;
}
// This check may be unnecessary due to current criteria for resumable index build support in
// storage engine.
if (!serverGlobalParams.enableMajorityReadConcern) {
return false;
}
// The last optime could be null if the node is in initial sync while building the index.
// This check may be redundant with the 'applicationMode' check and the replication requirement
// for two phase index builds.
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (replCoord->getReplicationMode() == repl::ReplicationCoordinator::modeNone) {
return false;
}
// When we are applying a startIndexBuild oplog entry during the oplog application phase of
// startup recovery, the last optime here derived from the local oplog may not be a valid
// optime to wait on for the majority commit point since the rest of the replica set may
// be on a different branch of history.
if (inReplicationRecovery(opCtx->getServiceContext())) {
LOGV2(5039100,
"Index build: in replication recovery. Not waiting for last optime before "
"interceptors to be majority committed",
"buildUUID"_attr = replState.buildUUID);
return false;
}
// TODO(SERVER-50479): Remove this check when resumable index builds work with ESE in GCM mode.
if (EncryptionHooks::get(opCtx->getServiceContext())->enabled()) {
return false;
}
if (!opCtx->getServiceContext()->getStorageEngine()->supportsResumableIndexBuilds()) {
return false;
}
// Only index builds with the default "all-voters" commit quorum running on voting nodes should
// be resumable. A node that cannot contribute to the commit quorum should not be waiting for
// the majority commit point when trying to commit the index build.
// IndexBuildsOptions::commitQuorum will be set if we are primary. Otherwise, we have to check
// the config.system.indexBuilds collection.
if (indexBuildOptions.commitQuorum) {
if (CommitQuorumOptions::kVotingMembers != indexBuildOptions.commitQuorum->mode) {
return false;
}
} else {
// The commit quorum may be updated using the setIndexBuildCommitQuorum command, so we will
// rely on the deadline to unblock ourselves from the majority wait if the commit quorum is
// no longer "all-voters".
auto swCommitQuorum = indexbuildentryhelpers::getCommitQuorum(opCtx, replState.buildUUID);
if (!swCommitQuorum.isOK()) {
LOGV2(5044600,
"Index build: cannot read commit quorum from config db. "
"Index build will not be resumable.",
"buildUUID"_attr = replState.buildUUID,
"error"_attr = swCommitQuorum.getStatus());
return false;
}
auto commitQuorum = swCommitQuorum.getValue();
if (CommitQuorumOptions::kVotingMembers != commitQuorum.mode) {
return false;
}
}
// Ensure that this node is a voting member in the replica set config.
auto rsConfig = replCoord->getConfig();
auto hap = replCoord->getMyHostAndPort();
if (auto memberConfig = rsConfig.findMemberByHostAndPort(hap)) {
if (!memberConfig->isVoter()) {
return false;
}
} else {
// We cannot determine our member config, so skip the majority wait and leave this index
// build as non-resumable.
return false;
}
return true;
}
/**
* Returns the ReadSource to be used for a drain occurring before the commit quorum has been
* satisfied.
*/
RecoveryUnit::ReadSource getReadSourceForDrainBeforeCommitQuorum(
const ReplIndexBuildState& replState) {
return replState.isResumable() ? RecoveryUnit::ReadSource::kMajorityCommitted
: RecoveryUnit::ReadSource::kNoTimestamp;
}
} // namespace
const auto getIndexBuildsCoord =
ServiceContext::declareDecoration<std::unique_ptr<IndexBuildsCoordinator>>();
void IndexBuildsCoordinator::set(ServiceContext* serviceContext,
std::unique_ptr<IndexBuildsCoordinator> ibc) {
auto& indexBuildsCoordinator = getIndexBuildsCoord(serviceContext);
invariant(!indexBuildsCoordinator);
indexBuildsCoordinator = std::move(ibc);
}
IndexBuildsCoordinator* IndexBuildsCoordinator::get(ServiceContext* serviceContext) {
auto& indexBuildsCoordinator = getIndexBuildsCoord(serviceContext);
invariant(indexBuildsCoordinator);
return indexBuildsCoordinator.get();
}
IndexBuildsCoordinator* IndexBuildsCoordinator::get(OperationContext* OperationContext) {
return get(OperationContext->getServiceContext());
}
IndexBuildsCoordinator::~IndexBuildsCoordinator() {
invariant(_allIndexBuilds.empty());
}
std::vector<std::string> IndexBuildsCoordinator::extractIndexNames(
const std::vector<BSONObj>& specs) {
std::vector<std::string> indexNames;
for (const auto& spec : specs) {
std::string name = spec.getStringField(IndexDescriptor::kIndexNameFieldName);
invariant(!name.empty(),
str::stream() << "Bad spec passed into ReplIndexBuildState constructor, missing '"
<< IndexDescriptor::kIndexNameFieldName << "' field: " << spec);
indexNames.push_back(name);
}
return indexNames;
}
StatusWith<std::pair<long long, long long>> IndexBuildsCoordinator::rebuildIndexesForRecovery(
OperationContext* opCtx,
const NamespaceString& nss,
const std::vector<BSONObj>& specs,
const UUID& buildUUID,
RepairData repair) {
const auto protocol = IndexBuildProtocol::kSinglePhase;
auto status = _startIndexBuildForRecovery(opCtx, nss, specs, buildUUID, protocol);
if (!status.isOK()) {
return status;
}
CollectionWriter collection(opCtx, nss, CollectionCatalog::LifetimeMode::kInplace);
// Complete the index build.
return _runIndexRebuildForRecovery(opCtx, collection, buildUUID, repair);
}
Status IndexBuildsCoordinator::_startIndexBuildForRecovery(OperationContext* opCtx,
const NamespaceString& nss,
const std::vector<BSONObj>& specs,
const UUID& buildUUID,
IndexBuildProtocol protocol) {
invariant(opCtx->lockState()->isCollectionLockedForMode(nss, MODE_X));
std::vector<std::string> indexNames;
for (auto& spec : specs) {
std::string name = spec.getStringField(IndexDescriptor::kIndexNameFieldName);
if (name.empty()) {
return Status(ErrorCodes::CannotCreateIndex,
str::stream()
<< "Cannot create an index for a spec '" << spec
<< "' without a non-empty string value for the 'name' field");
}
indexNames.push_back(name);
}
CollectionWriter collection(opCtx, nss, CollectionCatalog::LifetimeMode::kInplace);
{
// These steps are combined into a single WUOW to ensure there are no commits without
// the indexes.
// 1) Drop all unfinished indexes.
// 2) Start, but do not complete the index build process.
WriteUnitOfWork wuow(opCtx);
auto indexCatalog = collection.getWritableCollection()->getIndexCatalog();
for (size_t i = 0; i < indexNames.size(); i++) {
bool includeUnfinished = false;
auto descriptor =
indexCatalog->findIndexByName(opCtx, indexNames[i], includeUnfinished);
if (descriptor) {
Status s = indexCatalog->dropIndex(opCtx, descriptor);
if (!s.isOK()) {
return s;
}
continue;
}
// If the index is not present in the catalog, then we are trying to drop an already
// aborted index. This may happen when rollback-via-refetch restarts an index build
// after an abort has been rolled back.
if (!DurableCatalog::get(opCtx)->isIndexPresent(
opCtx, collection->getCatalogId(), indexNames[i])) {
LOGV2(20652,
"The index for build {buildUUID} was not found while trying to drop the "
"index during recovery: {index}",
"An index was not found in the catalog while trying to drop the index during "
"recovery",
"buildUUID"_attr = buildUUID,
"index"_attr = indexNames[i]);
continue;
}
const auto durableBuildUUID = DurableCatalog::get(opCtx)->getIndexBuildUUID(
opCtx, collection->getCatalogId(), indexNames[i]);
// A build UUID is present if and only if we are rebuilding a two-phase build.
invariant((protocol == IndexBuildProtocol::kTwoPhase) ==
durableBuildUUID.is_initialized());
// When a buildUUID is present, it must match the build UUID parameter to this
// function.
invariant(!durableBuildUUID || *durableBuildUUID == buildUUID,
str::stream() << "durable build UUID: " << durableBuildUUID
<< "buildUUID: " << buildUUID);
// If the unfinished index is in the IndexCatalog, drop it through there, otherwise drop
// it from the DurableCatalog. Rollback-via-refetch does not clear any in-memory state,
// so we should do it manually here.
includeUnfinished = true;
descriptor = indexCatalog->findIndexByName(opCtx, indexNames[i], includeUnfinished);
if (descriptor) {
Status s = indexCatalog->dropUnfinishedIndex(opCtx, descriptor);
if (!s.isOK()) {
return s;
}
} else {
// There are no concurrent users of the index during startup recovery, so it is OK
// to pass in a nullptr for the index 'ident', promising that the index is not in
// use.
catalog::removeIndex(opCtx,
indexNames[i],
collection->getCatalogId(),
collection->uuid(),
collection->ns(),
nullptr /* ident */);
}
}
// We need to initialize the collection to rebuild the indexes. The collection may already
// be initialized when rebuilding indexes with rollback-via-refetch.
if (!collection->isInitialized()) {
collection.getWritableCollection()->init(opCtx);
}
auto dbName = nss.db().toString();
auto replIndexBuildState = std::make_shared<ReplIndexBuildState>(
buildUUID, collection->uuid(), dbName, specs, protocol);
Status status = [&]() {
stdx::unique_lock<Latch> lk(_mutex);
return _registerIndexBuild(lk, replIndexBuildState);
}();
if (!status.isOK()) {
return status;
}
IndexBuildsManager::SetupOptions options;
options.protocol = protocol;
status = _indexBuildsManager.setUpIndexBuild(
opCtx, collection, specs, buildUUID, MultiIndexBlock::kNoopOnInitFn, options);
if (!status.isOK()) {
// An index build failure during recovery is fatal.
logFailure(status, nss, replIndexBuildState);
fassertNoTrace(51086, status);
}
wuow.commit();
}
return Status::OK();
}
Status IndexBuildsCoordinator::_setUpResumeIndexBuild(OperationContext* opCtx,
std::string dbName,
CollectionUUID collectionUUID,
const std::vector<BSONObj>& specs,
const UUID& buildUUID,
const ResumeIndexInfo& resumeInfo) {
NamespaceStringOrUUID nssOrUuid{dbName, collectionUUID};
if (MONGO_unlikely(failSetUpResumeIndexBuild.shouldFail())) {
return {ErrorCodes::FailPointEnabled, "failSetUpResumeIndexBuild fail point is enabled"};
}
Lock::DBLock dbLock(opCtx, dbName, MODE_IX);
Lock::CollectionLock collLock(opCtx, nssOrUuid, MODE_X);
CollectionWriter collection(
opCtx, resumeInfo.getCollectionUUID(), CollectionCatalog::LifetimeMode::kInplace);
invariant(collection);
auto durableCatalog = DurableCatalog::get(opCtx);
for (auto spec : specs) {
std::string indexName = spec.getStringField(IndexDescriptor::kIndexNameFieldName);
if (indexName.empty()) {
return Status(ErrorCodes::CannotCreateIndex,
str::stream()
<< "Cannot create an index for a spec '" << spec
<< "' without a non-empty string value for the 'name' field");
}
// Check that the information in the durable catalog matches the resume info.
uassert(4841702,
"Index not found in durable catalog while attempting to resume index build",
durableCatalog->isIndexPresent(opCtx, collection->getCatalogId(), indexName));
const auto durableBuildUUID =
durableCatalog->getIndexBuildUUID(opCtx, collection->getCatalogId(), indexName);
uassert(ErrorCodes::IndexNotFound,
str::stream() << "Cannot resume index build with a buildUUID: " << buildUUID
<< " that did not match the buildUUID in the durable catalog: "
<< durableBuildUUID,
durableBuildUUID == buildUUID);
auto indexIdent =
durableCatalog->getIndexIdent(opCtx, collection->getCatalogId(), indexName);
uassert(
4841703,
str::stream() << "No index ident found on disk that matches the index build to resume: "
<< indexName,
indexIdent.size() > 0);
uassertStatusOK(durableCatalog->checkMetaDataForIndex(
opCtx, collection->getCatalogId(), indexName, spec));
}
if (!collection->isInitialized()) {
collection.getWritableCollection()->init(opCtx);
}
auto protocol = IndexBuildProtocol::kTwoPhase;
auto replIndexBuildState = std::make_shared<ReplIndexBuildState>(
buildUUID, collection->uuid(), dbName, specs, protocol);
Status status = [&]() {
stdx::unique_lock<Latch> lk(_mutex);
return _registerIndexBuild(lk, replIndexBuildState);
}();
if (!status.isOK()) {
return status;
}
IndexBuildsManager::SetupOptions options;
options.protocol = protocol;
status = _indexBuildsManager.setUpIndexBuild(
opCtx, collection, specs, buildUUID, MultiIndexBlock::kNoopOnInitFn, options, resumeInfo);
if (!status.isOK()) {
LOGV2(4841705,
"Failed to resume index build",
"buildUUID"_attr = buildUUID,
logAttrs(collection->ns()),
"collectionUUID"_attr = collectionUUID,
"error"_attr = status);
stdx::lock_guard<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replIndexBuildState);
}
return status;
}
void IndexBuildsCoordinator::waitForAllIndexBuildsToStopForShutdown(OperationContext* opCtx) {
stdx::unique_lock<Latch> lk(_mutex);
// All index builds should have been signaled to stop via the ServiceContext.
if (_allIndexBuilds.empty()) {
return;
}
auto indexBuildToUUID = [](const auto& indexBuild) { return indexBuild.first; };
auto begin = boost::make_transform_iterator(_allIndexBuilds.begin(), indexBuildToUUID);
auto end = boost::make_transform_iterator(_allIndexBuilds.end(), indexBuildToUUID);
LOGV2(4725201,
"Waiting until the following index builds are finished",
"indexBuilds"_attr = logv2::seqLog(begin, end));
// Wait for all the index builds to stop.
auto pred = [this]() { return _allIndexBuilds.empty(); };
_indexBuildsCondVar.wait(lk, pred);
}
std::vector<UUID> IndexBuildsCoordinator::abortCollectionIndexBuilds(
OperationContext* opCtx,
const NamespaceString collectionNss,
const UUID collectionUUID,
const std::string& reason) {
auto collIndexBuilds = [&]() -> std::vector<std::shared_ptr<ReplIndexBuildState>> {
stdx::unique_lock<Latch> lk(_mutex);
auto indexBuildFilter = [=](const auto& replState) {
return collectionUUID == replState.collectionUUID;
};
return _filterIndexBuilds_inlock(lk, indexBuildFilter);
}();
if (collIndexBuilds.empty()) {
return {};
}
LOGV2(23879,
"About to abort all index builders",
"namespace"_attr = collectionNss,
"uuid"_attr = collectionUUID,
"reason"_attr = reason);
std::vector<UUID> buildUUIDs;
for (auto replState : collIndexBuilds) {
if (abortIndexBuildByBuildUUID(
opCtx, replState->buildUUID, IndexBuildAction::kPrimaryAbort, reason)) {
buildUUIDs.push_back(replState->buildUUID);
}
}
return buildUUIDs;
}
void IndexBuildsCoordinator::_awaitNoBgOpInProgForDb(stdx::unique_lock<Latch>& lk,
OperationContext* opCtx,
StringData db) {
auto indexBuildFilter = [db](const auto& replState) { return db == replState.dbName; };
auto pred = [&, this]() {
auto dbIndexBuilds = _filterIndexBuilds_inlock(lk, indexBuildFilter);
return dbIndexBuilds.empty();
};
_indexBuildsCondVar.wait(lk, pred);
}
void IndexBuildsCoordinator::abortDatabaseIndexBuilds(OperationContext* opCtx,
StringData db,
const std::string& reason) {
LOGV2(4612302,
"About to abort all index builders running for collections in the given database",
"database"_attr = db,
"reason"_attr = reason);
auto builds = [&]() -> std::vector<std::shared_ptr<ReplIndexBuildState>> {
stdx::unique_lock<Latch> lk(_mutex);
auto indexBuildFilter = [=](const auto& replState) { return db == replState.dbName; };
return _filterIndexBuilds_inlock(lk, indexBuildFilter);
}();
for (auto replState : builds) {
if (!abortIndexBuildByBuildUUID(
opCtx, replState->buildUUID, IndexBuildAction::kPrimaryAbort, reason)) {
// The index build may already be in the midst of tearing down.
LOGV2(5010502,
"Index build: failed to abort index build for database drop",
"buildUUID"_attr = replState->buildUUID,
"database"_attr = db,
"collectionUUID"_attr = replState->collectionUUID);
}
}
}
void IndexBuildsCoordinator::abortAllIndexBuildsForInitialSync(OperationContext* opCtx,
const std::string& reason) {
LOGV2(4833200, "About to abort all index builders running", "reason"_attr = reason);
auto builds = [&]() -> std::vector<std::shared_ptr<ReplIndexBuildState>> {
stdx::unique_lock<Latch> lk(_mutex);
auto indexBuildFilter = [](const auto& replState) { return true; };
return _filterIndexBuilds_inlock(lk, indexBuildFilter);
}();
for (auto replState : builds) {
if (!abortIndexBuildByBuildUUID(
opCtx, replState->buildUUID, IndexBuildAction::kInitialSyncAbort, reason)) {
// The index build may already be in the midst of tearing down.
LOGV2(5010503,
"Index build: failed to abort index build for initial sync",
"buildUUID"_attr = replState->buildUUID,
"database"_attr = replState->dbName,
"collectionUUID"_attr = replState->collectionUUID);
}
}
}
namespace {
NamespaceString getNsFromUUID(OperationContext* opCtx, const UUID& uuid) {
auto& catalog = CollectionCatalog::get(opCtx);
auto nss = catalog.lookupNSSByUUID(opCtx, uuid);
uassert(ErrorCodes::NamespaceNotFound, "No namespace with UUID " + uuid.toString(), nss);
return *nss;
}
} // namespace
void IndexBuildsCoordinator::applyStartIndexBuild(OperationContext* opCtx,
ApplicationMode applicationMode,
const IndexBuildOplogEntry& oplogEntry) {
const auto collUUID = oplogEntry.collUUID;
const auto nss = getNsFromUUID(opCtx, collUUID);
IndexBuildsCoordinator::IndexBuildOptions indexBuildOptions;
indexBuildOptions.applicationMode = applicationMode;
// If this is an initial syncing node, drop any conflicting ready index specs prior to
// proceeding with building them.
if (indexBuildOptions.applicationMode == ApplicationMode::kInitialSync) {
auto dbAndUUID = NamespaceStringOrUUID(nss.db().toString(), collUUID);
writeConflictRetry(opCtx, "IndexBuildsCoordinator::applyStartIndexBuild", nss.ns(), [&] {
WriteUnitOfWork wuow(opCtx);
AutoGetCollection coll(opCtx, dbAndUUID, MODE_X);
invariant(coll,
str::stream() << "Collection with UUID " << collUUID << " was dropped.");
IndexCatalog* indexCatalog = coll.getWritableCollection()->getIndexCatalog();
const bool includeUnfinished = false;
for (const auto& spec : oplogEntry.indexSpecs) {
std::string name = spec.getStringField(IndexDescriptor::kIndexNameFieldName);
uassert(ErrorCodes::BadValue,
str::stream() << "Index spec is missing the 'name' field " << spec,
!name.empty());
if (auto desc = indexCatalog->findIndexByName(opCtx, name, includeUnfinished)) {
uassertStatusOK(indexCatalog->dropIndex(opCtx, desc));
}
}
wuow.commit();
});
}
auto indexBuildsCoord = IndexBuildsCoordinator::get(opCtx);
uassertStatusOK(
indexBuildsCoord
->startIndexBuild(opCtx,
nss.db().toString(),
collUUID,
oplogEntry.indexSpecs,
oplogEntry.buildUUID,
/* This oplog entry is only replicated for two-phase index builds */
IndexBuildProtocol::kTwoPhase,
indexBuildOptions)
.getStatus());
}
void IndexBuildsCoordinator::applyCommitIndexBuild(OperationContext* opCtx,
const IndexBuildOplogEntry& oplogEntry) {
const auto collUUID = oplogEntry.collUUID;
const auto nss = getNsFromUUID(opCtx, collUUID);
const auto& buildUUID = oplogEntry.buildUUID;
updateCurOpForCommitOrAbort(opCtx, kCommitIndexBuildFieldName, buildUUID);
uassert(31417,
str::stream()
<< "No commit timestamp set while applying commitIndexBuild operation. Build UUID: "
<< buildUUID,
!opCtx->recoveryUnit()->getCommitTimestamp().isNull());
// There is a possibility that we cannot find an active index build with the given build UUID.
// This can be the case when the index already exists or was dropped on the sync source before
// the collection was cloned during initial sync. The oplog code will ignore the NoSuchKey
// error code.
//
// Case 1: Index already exists:
// +-----------------------------------------+--------------------------------+
// | Sync Target | Sync Source |
// +-----------------------------------------+--------------------------------+
// | | startIndexBuild 'x' at TS: 1. |
// | Start oplog fetcher at TS: 2. | |
// | | commitIndexBuild 'x' at TS: 2. |
// | Begin cloning the collection. | |
// | Index 'x' is listed as ready, build it. | |
// | Finish cloning the collection. | |
// | Start the oplog replay phase. | |
// | Apply commitIndexBuild 'x'. | |
// | --- Index build not found --- | |
// +-----------------------------------------+--------------------------------+
//
// Case 2: Sync source dropped the index:
// +--------------------------------+--------------------------------+
// | Sync Target | Sync Source |
// +--------------------------------+--------------------------------+
// | | startIndexBuild 'x' at TS: 1. |
// | Start oplog fetcher at TS: 2. | |
// | | commitIndexBuild 'x' at TS: 2. |
// | | dropIndex 'x' at TS: 3. |
// | Begin cloning the collection. | |
// | No user indexes to build. | |
// | Finish cloning the collection. | |
// | Start the oplog replay phase. | |
// | Apply commitIndexBuild 'x'. | |
// | --- Index build not found --- | |
// +--------------------------------+--------------------------------+
auto replState = uassertStatusOK(_getIndexBuild(buildUUID));
// Retry until we are able to put the index build in the kPrepareCommit state. None of the
// conditions for retrying are common or expected to be long-lived, so we believe this to be
// safe to poll at this frequency.
while (!_tryCommit(opCtx, replState)) {
opCtx->sleepFor(Milliseconds(100));
}
auto fut = replState->sharedPromise.getFuture();
auto waitStatus = fut.waitNoThrow(); // Result from waiting on future.
auto buildStatus = fut.getNoThrow().getStatus(); // Result from _runIndexBuildInner().
LOGV2(20654,
"Index build: joined after commit",
"buildUUID"_attr = buildUUID,
"waitResult"_attr = waitStatus,
"status"_attr = buildStatus);
// Throws if there was an error building the index.
fut.get();
}
bool IndexBuildsCoordinator::_tryCommit(OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState) {
return replState->tryCommit(opCtx);
}
void IndexBuildsCoordinator::applyAbortIndexBuild(OperationContext* opCtx,
const IndexBuildOplogEntry& oplogEntry) {
const auto collUUID = oplogEntry.collUUID;
const auto nss = getNsFromUUID(opCtx, collUUID);
const auto& buildUUID = oplogEntry.buildUUID;
updateCurOpForCommitOrAbort(opCtx, kCommitIndexBuildFieldName, buildUUID);
invariant(oplogEntry.cause);
uassert(31420,
str::stream()
<< "No commit timestamp set while applying abortIndexBuild operation. Build UUID: "
<< buildUUID,
!opCtx->recoveryUnit()->getCommitTimestamp().isNull());
std::string abortReason(str::stream()
<< "abortIndexBuild oplog entry encountered: " << *oplogEntry.cause);
if (!abortIndexBuildByBuildUUID(opCtx, buildUUID, IndexBuildAction::kOplogAbort, abortReason)) {
// The index build may already be in the midst of tearing down.
LOGV2(5010504,
"Index build: failed to abort index build while applying abortIndexBuild operation",
"buildUUID"_attr = buildUUID,
"namespace"_attr = nss,
"collectionUUID"_attr = collUUID,
"cause"_attr = *oplogEntry.cause);
}
}
boost::optional<UUID> IndexBuildsCoordinator::abortIndexBuildByIndexNames(
OperationContext* opCtx,
const UUID& collectionUUID,
const std::vector<std::string>& indexNames,
std::string reason) {
boost::optional<UUID> buildUUID;
auto indexBuilds = _getIndexBuilds();
auto onIndexBuild = [&](const std::shared_ptr<ReplIndexBuildState>& replState) {
if (replState->collectionUUID != collectionUUID) {
return;
}
bool matchedBuilder = std::is_permutation(indexNames.begin(),
indexNames.end(),
replState->indexNames.begin(),
replState->indexNames.end());
if (!matchedBuilder) {
return;
}
LOGV2(23880,
"About to abort index builder: {buildUUID} on collection: "
"{collectionUUID}. First index: {firstIndex}",
"About to abort index builder",
"buildUUID"_attr = replState->buildUUID,
"collectionUUID"_attr = collectionUUID,
"firstIndex"_attr = replState->indexNames.front());
if (abortIndexBuildByBuildUUID(
opCtx, replState->buildUUID, IndexBuildAction::kPrimaryAbort, reason)) {
buildUUID = replState->buildUUID;
}
};
forEachIndexBuild(
indexBuilds, "IndexBuildsCoordinator::abortIndexBuildByIndexNames"_sd, onIndexBuild);
return buildUUID;
}
bool IndexBuildsCoordinator::hasIndexBuilder(OperationContext* opCtx,
const UUID& collectionUUID,
const std::vector<std::string>& indexNames) const {
bool foundIndexBuilder = false;
boost::optional<UUID> buildUUID;
auto indexBuilds = _getIndexBuilds();
auto onIndexBuild = [&](const std::shared_ptr<ReplIndexBuildState>& replState) {
if (replState->collectionUUID != collectionUUID) {
return;
}
bool matchedBuilder = std::is_permutation(indexNames.begin(),
indexNames.end(),
replState->indexNames.begin(),
replState->indexNames.end());
if (!matchedBuilder) {
return;
}
foundIndexBuilder = true;
};
forEachIndexBuild(indexBuilds, "IndexBuildsCoordinator::hasIndexBuilder"_sd, onIndexBuild);
return foundIndexBuilder;
}
bool IndexBuildsCoordinator::abortIndexBuildByBuildUUID(OperationContext* opCtx,
const UUID& buildUUID,
IndexBuildAction signalAction,
std::string reason) {
std::shared_ptr<ReplIndexBuildState> replState;
bool retry = false;
while (true) {
// Retry until we are able to put the index build into the kAborted state. None of the
// conditions for retrying are common or expected to be long-lived, so we believe this to be
// safe to poll at this frequency.
if (retry) {
opCtx->sleepFor(Milliseconds(1000));
retry = false;
}
// It is possible to receive an abort for a non-existent index build. Abort should always
// succeed, so suppress the error.
auto replStateResult = _getIndexBuild(buildUUID);
if (!replStateResult.isOK()) {
LOGV2(20656,
"ignoring error while aborting index build {buildUUID}: {error}",
"Ignoring error while aborting index build",
"buildUUID"_attr = buildUUID,
"error"_attr = replStateResult.getStatus());
return false;
}
replState = replStateResult.getValue();
LOGV2(4656010, "Attempting to abort index build", "buildUUID"_attr = replState->buildUUID);
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
Lock::DBLock dbLock(opCtx, replState->dbName, MODE_IX);
if (IndexBuildProtocol::kSinglePhase == replState->protocol) {
// Unlock RSTL to avoid deadlocks with prepare conflicts and state transitions caused by
// taking a strong collection lock. See SERVER-42621.
unlockRSTL(opCtx);
}
Lock::CollectionLock collLock(opCtx, dbAndUUID, MODE_X);
// If we are using two-phase index builds and are no longer primary after receiving an
// abort, we cannot replicate an abortIndexBuild oplog entry. Continue holding the RSTL to
// check the replication state and to prevent any state transitions from happening while
// aborting the index build. Once an index build is put into kAborted, the index builder
// thread will be torn down, and an oplog entry must be replicated. Single-phase builds do
// not have this restriction and may be aborted after a stepDown. Initial syncing nodes need
// to be able to abort two phase index builds during the oplog replay phase.
if (IndexBuildProtocol::kTwoPhase == replState->protocol) {
// The DBLock helper takes the RSTL implicitly.
invariant(opCtx->lockState()->isRSTLLocked());
// Override the 'signalAction' as this is an initial syncing node.
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (replCoord->getMemberState().startup2()) {
LOGV2_DEBUG(4665902,
1,
"Overriding abort 'signalAction' for initial sync",
"from"_attr = signalAction,
"to"_attr = IndexBuildAction::kInitialSyncAbort);
signalAction = IndexBuildAction::kInitialSyncAbort;
}
if (IndexBuildAction::kPrimaryAbort == signalAction &&
!replCoord->canAcceptWritesFor(opCtx, dbAndUUID)) {
uassertStatusOK({ErrorCodes::NotWritablePrimary,
str::stream()
<< "Unable to abort index build because we are not primary: "
<< buildUUID});
}
}
auto tryAbortResult = replState->tryAbort(opCtx, signalAction, reason);
switch (tryAbortResult) {
case ReplIndexBuildState::TryAbortResult::kNotAborted:
return false;
case ReplIndexBuildState::TryAbortResult::kAlreadyAborted:
return true;
case ReplIndexBuildState::TryAbortResult::kRetry:
case ReplIndexBuildState::TryAbortResult::kContinueAbort:
break;
}
if (ReplIndexBuildState::TryAbortResult::kRetry == tryAbortResult) {
retry = true;
continue;
}
invariant(ReplIndexBuildState::TryAbortResult::kContinueAbort == tryAbortResult);
if (MONGO_unlikely(hangBeforeCompletingAbort.shouldFail())) {
LOGV2(4806200, "Hanging before completing index build abort");
hangBeforeCompletingAbort.pauseWhileSet();
}
// At this point we must continue aborting the index build.
try {
// We are holding the RSTL and an exclusive collection lock, so we will block stepdown
// and be targeted for being killed. In addition to writing to the catalog, we need to
// acquire an IX lock to write to the config.system.indexBuilds collection. Since
// we must perform these final writes, but we expect them not to block, we can safely,
// temporarily disable interrupts.
UninterruptibleLockGuard noInterrupt(opCtx->lockState());
_completeAbort(opCtx, replState, signalAction, {ErrorCodes::IndexBuildAborted, reason});
} catch (const DBException& e) {
LOGV2_FATAL(
4656011,
"Failed to abort index build after partially tearing-down index build state",
"buildUUID"_attr = replState->buildUUID,
"error"_attr = e);
}
// Wait for the builder thread to receive the signal before unregistering. Don't release the
// Collection lock until this happens, guaranteeing the thread has stopped making progress
// and has exited.
auto fut = replState->sharedPromise.getFuture();
auto waitStatus = fut.waitNoThrow(); // Result from waiting on future.
auto buildStatus = fut.getNoThrow().getStatus(); // Result from _runIndexBuildInner().
LOGV2(20655,
"Index build: joined after abort",
"buildUUID"_attr = buildUUID,
"waitResult"_attr = waitStatus,
"status"_attr = buildStatus);
if (IndexBuildAction::kRollbackAbort == signalAction) {
// Index builds interrupted for rollback may be resumed during recovery. We wait for the
// builder thread to complete before persisting the in-memory state that will be used
// to resume the index build.
// No locks are required when aborting due to rollback. This performs no storage engine
// writes, only cleans up the remaining in-memory state.
CollectionWriter coll(opCtx, replState->collectionUUID);
_indexBuildsManager.abortIndexBuildWithoutCleanup(
opCtx, coll.get(), replState->buildUUID, replState->isResumable());
}
{
// Unregister last once we guarantee all other state has been cleaned up.
stdx::unique_lock<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replState);
}
break;
}
return true;
}
void IndexBuildsCoordinator::_completeAbort(OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
IndexBuildAction signalAction,
Status reason) {
CollectionWriter coll(opCtx, replState->collectionUUID);
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
auto nss = coll->ns();
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
switch (signalAction) {
// Replicates an abortIndexBuild oplog entry and deletes the index from the durable catalog.
case IndexBuildAction::kPrimaryAbort: {
// Single-phase builds are aborted on step-down, so it's possible to no longer be
// primary after we process an abort. We must continue with the abort, but since
// single-phase builds do not replicate abort oplog entries, this write will use a ghost
// timestamp.
bool isPrimaryOrSinglePhase = replState->protocol == IndexBuildProtocol::kSinglePhase ||
replCoord->canAcceptWritesFor(opCtx, nss);
invariant(isPrimaryOrSinglePhase,
str::stream() << "singlePhase: "
<< (IndexBuildProtocol::kSinglePhase == replState->protocol));
auto onCleanUpFn = [&] { onAbortIndexBuild(opCtx, coll->ns(), *replState, reason); };
_indexBuildsManager.abortIndexBuild(opCtx, coll, replState->buildUUID, onCleanUpFn);
removeIndexBuildEntryAfterCommitOrAbort(opCtx, dbAndUUID, *replState);
break;
}
// Deletes the index from the durable catalog.
case IndexBuildAction::kInitialSyncAbort: {
invariant(replState->protocol == IndexBuildProtocol::kTwoPhase);
invariant(replCoord->getMemberState().startup2());
bool isMaster = replCoord->canAcceptWritesFor(opCtx, nss);
invariant(!isMaster, str::stream() << "Index build: " << replState->buildUUID);
auto abortReason = replState->getAbortReason();
LOGV2(4665903,
"Aborting index build during initial sync",
"buildUUID"_attr = replState->buildUUID,
"abortReason"_attr = abortReason,
"collectionUUID"_attr = replState->collectionUUID);
_indexBuildsManager.abortIndexBuild(
opCtx, coll, replState->buildUUID, MultiIndexBlock::kNoopOnCleanUpFn);
break;
}
// Deletes the index from the durable catalog.
case IndexBuildAction::kOplogAbort: {
invariant(IndexBuildProtocol::kTwoPhase == replState->protocol);
replState->onOplogAbort(opCtx, nss);
_indexBuildsManager.abortIndexBuild(
opCtx, coll, replState->buildUUID, MultiIndexBlock::kNoopOnCleanUpFn);
break;
}
case IndexBuildAction::kRollbackAbort: {
invariant(replState->protocol == IndexBuildProtocol::kTwoPhase);
invariant(replCoord->getMemberState().rollback());
// Defer cleanup until builder thread is joined.
break;
}
case IndexBuildAction::kNoAction:
case IndexBuildAction::kCommitQuorumSatisfied:
case IndexBuildAction::kOplogCommit:
case IndexBuildAction::kSinglePhaseCommit:
MONGO_UNREACHABLE;
}
LOGV2(465611, "Cleaned up index build after abort. ", "buildUUID"_attr = replState->buildUUID);
}
void IndexBuildsCoordinator::_completeSelfAbort(OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
Status reason) {
_completeAbort(opCtx, replState, IndexBuildAction::kPrimaryAbort, reason);
replState->abortSelf(opCtx);
{
stdx::unique_lock<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replState);
}
}
void IndexBuildsCoordinator::_completeAbortForShutdown(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
const CollectionPtr& collection) {
// Leave it as-if kill -9 happened. Startup recovery will restart the index build.
_indexBuildsManager.abortIndexBuildWithoutCleanup(
opCtx, collection, replState->buildUUID, replState->isResumable());
replState->abortForShutdown(opCtx);
{
// This allows the builder thread to exit.
stdx::unique_lock<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replState);
}
}
std::size_t IndexBuildsCoordinator::getActiveIndexBuildCount(OperationContext* opCtx) {
auto indexBuilds = _getIndexBuilds();
// We use forEachIndexBuild() to log basic details on the current index builds and don't intend
// to modify any of the index builds, hence the no-op.
forEachIndexBuild(indexBuilds, "IndexBuildsCoordinator::getActiveIndexBuildCount"_sd, nullptr);
return indexBuilds.size();
}
void IndexBuildsCoordinator::onStepUp(OperationContext* opCtx) {
if (MONGO_unlikely(hangIndexBuildOnStepUp.shouldFail())) {
LOGV2(4753600, "Hanging due to hangIndexBuildOnStepUp fail point");
hangIndexBuildOnStepUp.pauseWhileSet();
}
LOGV2(20657, "IndexBuildsCoordinator::onStepUp - this node is stepping up to primary");
// This would create an empty table even for FCV 4.2 to handle case where a primary node started
// with FCV 4.2, and then upgraded FCV 4.4.
indexbuildentryhelpers::ensureIndexBuildEntriesNamespaceExists(opCtx);
auto indexBuilds = _getIndexBuilds();
auto onIndexBuild = [this, opCtx](const std::shared_ptr<ReplIndexBuildState>& replState) {
if (IndexBuildProtocol::kTwoPhase != replState->protocol) {
return;
}
if (!_signalIfCommitQuorumNotEnabled(opCtx, replState)) {
// This reads from system.indexBuilds collection to see if commit quorum got satisfied.
try {
_signalIfCommitQuorumIsSatisfied(opCtx, replState);
} catch (DBException& ex) {
fassert(31440, ex.toStatus());
}
}
};
forEachIndexBuild(indexBuilds, "IndexBuildsCoordinator::onStepUp"_sd, onIndexBuild);
}
IndexBuilds IndexBuildsCoordinator::stopIndexBuildsForRollback(OperationContext* opCtx) {
LOGV2(20658, "Stopping index builds before rollback");
IndexBuilds buildsStopped;
auto indexBuilds = _getIndexBuilds();
auto onIndexBuild = [&](const std::shared_ptr<ReplIndexBuildState>& replState) {
if (IndexBuildProtocol::kSinglePhase == replState->protocol) {
LOGV2(20659,
"Not stopping single phase index build",
"buildUUID"_attr = replState->buildUUID);
return;
}
// This will unblock the index build and allow it to complete without cleaning up.
// Subsequently, the rollback algorithm can decide how to undo the index build depending on
// the state of the oplog. Signals the kRollbackAbort and then waits for the thread to join.
const std::string reason = "rollback";
if (!abortIndexBuildByBuildUUID(
opCtx, replState->buildUUID, IndexBuildAction::kRollbackAbort, reason)) {
// The index build may already be in the midst of tearing down.
// Leave this index build out of 'buildsStopped'.
LOGV2(5010505,
"Index build: failed to abort index build before rollback",
"buildUUID"_attr = replState->buildUUID,
"database"_attr = replState->dbName,
"collectionUUID"_attr = replState->collectionUUID);
return;
}
IndexBuildDetails aborted{replState->collectionUUID};
// Record the index builds aborted due to rollback. This allows any rollback algorithm
// to efficiently restart all unfinished index builds without having to scan all indexes
// in all collections.
for (auto spec : replState->indexSpecs) {
aborted.indexSpecs.emplace_back(spec.getOwned());
}
buildsStopped.insert({replState->buildUUID, aborted});
};
forEachIndexBuild(
indexBuilds, "IndexBuildsCoordinator::stopIndexBuildsForRollback"_sd, onIndexBuild);
return buildsStopped;
}
void IndexBuildsCoordinator::restartIndexBuildsForRecovery(
OperationContext* opCtx,
const IndexBuilds& buildsToRestart,
const std::vector<ResumeIndexInfo>& buildsToResume) {
stdx::unordered_set<UUID, UUID::Hash> successfullyResumed;
for (const auto& resumeInfo : buildsToResume) {
auto buildUUID = resumeInfo.getBuildUUID();
auto collUUID = resumeInfo.getCollectionUUID();
boost::optional<NamespaceString> nss =
CollectionCatalog::get(opCtx).lookupNSSByUUID(opCtx, resumeInfo.getCollectionUUID());
invariant(nss);
std::vector<BSONObj> indexSpecs;
indexSpecs.reserve(resumeInfo.getIndexes().size());
for (const auto& index : resumeInfo.getIndexes()) {
indexSpecs.push_back(index.getSpec());
}
LOGV2(4841700,
"Index build: resuming",
logAttrs(nss.get()),
"collectionUUID"_attr = collUUID,
"buildUUID"_attr = buildUUID,
"specs"_attr = indexSpecs,
"phase"_attr = IndexBuildPhase_serializer(resumeInfo.getPhase()),
"details"_attr = resumeInfo.toBSON());
try {
// This spawns a new thread and returns immediately. These index builds will resume and
// wait for a commit or abort to be replicated.
MONGO_COMPILER_VARIABLE_UNUSED auto fut = uassertStatusOK(resumeIndexBuild(
opCtx, nss->db().toString(), collUUID, indexSpecs, buildUUID, resumeInfo));
successfullyResumed.insert(buildUUID);
} catch (const DBException& e) {
LOGV2(4841701,
"Failed to resume index build, restarting instead",
"buildUUID"_attr = buildUUID,
"error"_attr = e);
// Clean up the persisted Sorter data since resuming failed.
for (const auto& index : resumeInfo.getIndexes()) {
if (!index.getFileName()) {
continue;
}
LOGV2(5043100,
"Removing resumable index build temp file",
"file"_attr = index.getFileName(),
"buildUUID"_attr = buildUUID);
boost::system::error_code ec;
boost::filesystem::remove(
storageGlobalParams.dbpath + "/_tmp/" + index.getFileName()->toString(), ec);
if (ec) {
LOGV2(5043101,
"Failed to remove resumable index build temp file",
"file"_attr = index.getFileName(),
"buildUUID"_attr = buildUUID,
"error"_attr = ec.message());
}
}
}
}
for (auto& [buildUUID, build] : buildsToRestart) {
// Don't restart an index build that was already resumed.
if (successfullyResumed.contains(buildUUID)) {
continue;
}
boost::optional<NamespaceString> nss =
CollectionCatalog::get(opCtx).lookupNSSByUUID(opCtx, build.collUUID);
invariant(nss);
LOGV2(20660,
"Index build: restarting",
logAttrs(nss.get()),
"collectionUUID"_attr = build.collUUID,
"buildUUID"_attr = buildUUID);
IndexBuildsCoordinator::IndexBuildOptions indexBuildOptions;
// Indicate that the initialization should not generate oplog entries or timestamps for the
// first catalog write, and that the original durable catalog entries should be dropped and
// replaced.
indexBuildOptions.applicationMode = ApplicationMode::kStartupRepair;
// This spawns a new thread and returns immediately. These index builds will start and wait
// for a commit or abort to be replicated.
MONGO_COMPILER_VARIABLE_UNUSED auto fut =
uassertStatusOK(startIndexBuild(opCtx,
nss->db().toString(),
build.collUUID,
build.indexSpecs,
buildUUID,
IndexBuildProtocol::kTwoPhase,
indexBuildOptions));
}
}
int IndexBuildsCoordinator::numInProgForDb(StringData db) const {
stdx::unique_lock<Latch> lk(_mutex);
auto indexBuildFilter = [db](const auto& replState) { return db == replState.dbName; };
auto dbIndexBuilds = _filterIndexBuilds_inlock(lk, indexBuildFilter);
return int(dbIndexBuilds.size());
}
bool IndexBuildsCoordinator::inProgForCollection(const UUID& collectionUUID,
IndexBuildProtocol protocol) const {
stdx::unique_lock<Latch> lk(_mutex);
auto indexBuildFilter = [=](const auto& replState) {
return collectionUUID == replState.collectionUUID && protocol == replState.protocol;
};
auto indexBuilds = _filterIndexBuilds_inlock(lk, indexBuildFilter);
return !indexBuilds.empty();
}
bool IndexBuildsCoordinator::inProgForCollection(const UUID& collectionUUID) const {
stdx::unique_lock<Latch> lk(_mutex);
auto indexBuilds = _filterIndexBuilds_inlock(
lk, [=](const auto& replState) { return collectionUUID == replState.collectionUUID; });
return !indexBuilds.empty();
}
bool IndexBuildsCoordinator::inProgForDb(StringData db) const {
return numInProgForDb(db) > 0;
}
void IndexBuildsCoordinator::assertNoIndexBuildInProgress() const {
stdx::unique_lock<Latch> lk(_mutex);
uassert(ErrorCodes::BackgroundOperationInProgressForDatabase,
str::stream() << "cannot perform operation: there are currently "
<< _allIndexBuilds.size() << " index builds running.",
_allIndexBuilds.size() == 0);
}
void IndexBuildsCoordinator::assertNoIndexBuildInProgForCollection(
const UUID& collectionUUID) const {
uassert(ErrorCodes::BackgroundOperationInProgressForNamespace,
str::stream() << "cannot perform operation: an index build is currently running for "
"collection with UUID: "
<< collectionUUID,
!inProgForCollection(collectionUUID));
}
void IndexBuildsCoordinator::assertNoBgOpInProgForDb(StringData db) const {
uassert(ErrorCodes::BackgroundOperationInProgressForDatabase,
str::stream() << "cannot perform operation: an index build is currently running for "
"database "
<< db,
!inProgForDb(db));
}
void IndexBuildsCoordinator::awaitIndexBuildFinished(OperationContext* opCtx,
const UUID& buildUUID) {
stdx::unique_lock<Latch> lk(_mutex);
auto pred = [&, this]() { return _allIndexBuilds.end() == _allIndexBuilds.find(buildUUID); };
_indexBuildsCondVar.wait(lk, pred);
}
void IndexBuildsCoordinator::awaitNoIndexBuildInProgressForCollection(OperationContext* opCtx,
const UUID& collectionUUID,
IndexBuildProtocol protocol) {
stdx::unique_lock<Latch> lk(_mutex);
auto noIndexBuildsPred = [&, this]() {
auto indexBuilds = _filterIndexBuilds_inlock(lk, [&](const auto& replState) {
return collectionUUID == replState.collectionUUID && protocol == replState.protocol;
});
return indexBuilds.empty();
};
opCtx->waitForConditionOrInterrupt(_indexBuildsCondVar, lk, noIndexBuildsPred);
}
void IndexBuildsCoordinator::awaitNoIndexBuildInProgressForCollection(OperationContext* opCtx,
const UUID& collectionUUID) {
stdx::unique_lock<Latch> lk(_mutex);
auto pred = [&, this]() {
auto indexBuilds = _filterIndexBuilds_inlock(
lk, [&](const auto& replState) { return collectionUUID == replState.collectionUUID; });
return indexBuilds.empty();
};
_indexBuildsCondVar.wait(lk, pred);
}
void IndexBuildsCoordinator::awaitNoBgOpInProgForDb(OperationContext* opCtx, StringData db) {
stdx::unique_lock<Latch> lk(_mutex);
_awaitNoBgOpInProgForDb(lk, opCtx, db);
}
void IndexBuildsCoordinator::waitUntilAnIndexBuildFinishes(OperationContext* opCtx) {
stdx::unique_lock<Latch> lk(_mutex);
if (_allIndexBuilds.empty()) {
return;
}
const auto generation = _indexBuildsCompletedGen;
opCtx->waitForConditionOrInterrupt(
_indexBuildsCondVar, lk, [&] { return _indexBuildsCompletedGen != generation; });
}
void IndexBuildsCoordinator::createIndex(OperationContext* opCtx,
UUID collectionUUID,
const BSONObj& spec,
IndexBuildsManager::IndexConstraints indexConstraints,
bool fromMigrate) {
CollectionWriter collection(opCtx, collectionUUID);
invariant(collection,
str::stream() << "IndexBuildsCoordinator::createIndexes: " << collectionUUID);
auto nss = collection->ns();
invariant(opCtx->lockState()->isCollectionLockedForMode(nss, MODE_X),
str::stream() << "IndexBuildsCoordinator::createIndexes: " << collectionUUID);
auto buildUUID = UUID::gen();
// Rest of this function can throw, so ensure the build cleanup occurs.
ON_BLOCK_EXIT([&] { _indexBuildsManager.unregisterIndexBuild(buildUUID); });
try {
auto onInitFn = MultiIndexBlock::makeTimestampedIndexOnInitFn(opCtx, collection.get());
IndexBuildsManager::SetupOptions options;
options.indexConstraints = indexConstraints;
uassertStatusOK(_indexBuildsManager.setUpIndexBuild(
opCtx, collection, {spec}, buildUUID, onInitFn, options));
} catch (DBException& ex) {
const auto& status = ex.toStatus();
if (status == ErrorCodes::IndexAlreadyExists ||
((status == ErrorCodes::IndexOptionsConflict ||
status == ErrorCodes::IndexKeySpecsConflict) &&
IndexBuildsManager::IndexConstraints::kRelax == indexConstraints)) {
LOGV2_DEBUG(4718200,
1,
"Ignoring indexing error",
"error"_attr = redact(status),
"namespace"_attr = nss,
"collectionUUID"_attr = collectionUUID,
"spec"_attr = spec);
return;
}
throw;
}
auto abortOnExit = makeGuard([&] {
_indexBuildsManager.abortIndexBuild(
opCtx, collection, buildUUID, MultiIndexBlock::kNoopOnCleanUpFn);
});
uassertStatusOK(_indexBuildsManager.startBuildingIndex(opCtx, collection.get(), buildUUID));
// Retry indexing records that failed key generation, but only if we are primary. Secondaries
// rely on the primary's decision to commit as assurance that it has checked all key generation
// errors on its behalf.
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (replCoord->canAcceptWritesFor(opCtx, nss)) {
uassertStatusOK(
_indexBuildsManager.retrySkippedRecords(opCtx, buildUUID, collection.get()));
}
uassertStatusOK(
_indexBuildsManager.checkIndexConstraintViolations(opCtx, collection.get(), buildUUID));
auto opObserver = opCtx->getServiceContext()->getOpObserver();
auto onCreateEachFn = [&](const BSONObj& spec) {
opObserver->onCreateIndex(opCtx, collection->ns(), collectionUUID, spec, fromMigrate);
};
auto onCommitFn = MultiIndexBlock::kNoopOnCommitFn;
uassertStatusOK(_indexBuildsManager.commitIndexBuild(
opCtx, collection, nss, buildUUID, onCreateEachFn, onCommitFn));
abortOnExit.dismiss();
}
void IndexBuildsCoordinator::createIndexesOnEmptyCollection(OperationContext* opCtx,
CollectionWriter& collection,
const std::vector<BSONObj>& specs,
bool fromMigrate) {
auto collectionUUID = collection->uuid();
invariant(collection, str::stream() << collectionUUID);
invariant(collection->isEmpty(opCtx), str::stream() << collectionUUID);
invariant(!specs.empty(), str::stream() << collectionUUID);
auto nss = collection->ns();
UncommittedCollections::get(opCtx).invariantHasExclusiveAccessToCollection(opCtx,
collection->ns());
auto opObserver = opCtx->getServiceContext()->getOpObserver();
auto indexCatalog = collection.getWritableCollection()->getIndexCatalog();
// Always run single phase index build for empty collection. And, will be coordinated using
// createIndexes oplog entry.
for (const auto& spec : specs) {
// Each index will be added to the mdb catalog using the preceding createIndexes
// timestamp.
opObserver->onCreateIndex(opCtx, nss, collectionUUID, spec, fromMigrate);
uassertStatusOK(indexCatalog->createIndexOnEmptyCollection(opCtx, spec));
}
}
void IndexBuildsCoordinator::sleepIndexBuilds_forTestOnly(bool sleep) {
stdx::unique_lock<Latch> lk(_mutex);
_sleepForTest = sleep;
}
void IndexBuildsCoordinator::verifyNoIndexBuilds_forTestOnly() {
stdx::unique_lock<Latch> lk(_mutex);
invariant(_allIndexBuilds.empty());
}
// static
void IndexBuildsCoordinator::updateCurOpOpDescription(OperationContext* opCtx,
const NamespaceString& nss,
const std::vector<BSONObj>& indexSpecs) {
BSONObjBuilder builder;
// If the collection namespace is provided, add a 'createIndexes' field with the collection name
// to allow tests to identify this op as an index build.
if (!nss.isEmpty()) {
builder.append(kCreateIndexesFieldName, nss.coll());
}
// If index specs are provided, add them under the 'indexes' field.
if (!indexSpecs.empty()) {
BSONArrayBuilder indexesBuilder;
for (const auto& spec : indexSpecs) {
indexesBuilder.append(spec);
}
builder.append(kIndexesFieldName, indexesBuilder.arr());
}
stdx::unique_lock<Client> lk(*opCtx->getClient());
auto curOp = CurOp::get(opCtx);
builder.appendElementsUnique(curOp->opDescription());
auto opDescObj = builder.obj();
curOp->setLogicalOp_inlock(LogicalOp::opCommand);
curOp->setOpDescription_inlock(opDescObj);
curOp->setNS_inlock(nss.ns());
curOp->ensureStarted();
}
Status IndexBuildsCoordinator::_registerIndexBuild(
WithLock lk, std::shared_ptr<ReplIndexBuildState> replIndexBuildState) {
// Check whether any indexes are already being built with the same index name(s). (Duplicate
// specs will be discovered by the index builder.)
auto pred = [&](const auto& replState) {
return replIndexBuildState->collectionUUID == replState.collectionUUID;
};
auto collIndexBuilds = _filterIndexBuilds_inlock(lk, pred);
for (auto existingIndexBuild : collIndexBuilds) {
for (const auto& name : replIndexBuildState->indexNames) {
if (existingIndexBuild->indexNames.end() !=
std::find(existingIndexBuild->indexNames.begin(),
existingIndexBuild->indexNames.end(),
name)) {
return existingIndexBuild->onConflictWithNewIndexBuild(*replIndexBuildState, name);
}
}
}
invariant(_allIndexBuilds.emplace(replIndexBuildState->buildUUID, replIndexBuildState).second);
_indexBuildsCondVar.notify_all();
return Status::OK();
}
void IndexBuildsCoordinator::_unregisterIndexBuild(
WithLock lk, std::shared_ptr<ReplIndexBuildState> replIndexBuildState) {
invariant(_allIndexBuilds.erase(replIndexBuildState->buildUUID));
LOGV2_DEBUG(4656004,
1,
"Index build: Unregistering",
"buildUUID"_attr = replIndexBuildState->buildUUID);
_indexBuildsManager.unregisterIndexBuild(replIndexBuildState->buildUUID);
_indexBuildsCompletedGen++;
_indexBuildsCondVar.notify_all();
}
Status IndexBuildsCoordinator::_setUpIndexBuildForTwoPhaseRecovery(
OperationContext* opCtx,
StringData dbName,
CollectionUUID collectionUUID,
const std::vector<BSONObj>& specs,
const UUID& buildUUID) {
NamespaceStringOrUUID nssOrUuid{dbName.toString(), collectionUUID};
// Don't use the AutoGet helpers because they require an open database, which may not be the
// case when an index builds is restarted during recovery.
Lock::DBLock dbLock(opCtx, dbName, MODE_IX);
Lock::CollectionLock collLock(opCtx, nssOrUuid, MODE_X);
auto collection = CollectionCatalog::get(opCtx).lookupCollectionByUUID(opCtx, collectionUUID);
invariant(collection);
const auto& nss = collection->ns();
const auto protocol = IndexBuildProtocol::kTwoPhase;
return _startIndexBuildForRecovery(opCtx, nss, specs, buildUUID, protocol);
}
StatusWith<boost::optional<SharedSemiFuture<ReplIndexBuildState::IndexCatalogStats>>>
IndexBuildsCoordinator::_filterSpecsAndRegisterBuild(OperationContext* opCtx,
StringData dbName,
CollectionUUID collectionUUID,
const std::vector<BSONObj>& specs,
const UUID& buildUUID,
IndexBuildProtocol protocol) {
// AutoGetCollection throws an exception if it is unable to look up the collection by UUID.
NamespaceStringOrUUID nssOrUuid{dbName.toString(), collectionUUID};
AutoGetCollection autoColl(opCtx, nssOrUuid, MODE_X);
CollectionWriter collection(autoColl);
// Disallow index builds on drop-pending namespaces (system.drop.*) if we are primary.
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (replCoord->getSettings().usingReplSets() &&
replCoord->canAcceptWritesFor(opCtx, nssOrUuid)) {
uassert(ErrorCodes::NamespaceNotFound,
str::stream() << "drop-pending collection: " << collection.get()->ns(),
!collection.get()->ns().isDropPendingNamespace());
}
// This check is for optimization purposes only as since this lock is released after this,
// and is acquired again when we build the index in _setUpIndexBuild.
CollectionShardingState::get(opCtx, collection.get()->ns())->checkShardVersionOrThrow(opCtx);
// Lock from when we ascertain what indexes to build through to when the build is registered
// on the Coordinator and persistedly set up in the catalog. This serializes setting up an
// index build so that no attempts are made to register the same build twice.
stdx::unique_lock<Latch> lk(_mutex);
std::vector<BSONObj> filteredSpecs;
try {
filteredSpecs =
prepareSpecListForCreate(opCtx, collection.get(), collection.get()->ns(), specs);
} catch (const DBException& ex) {
return ex.toStatus();
}
if (filteredSpecs.size() == 0) {
// The requested index (specs) are already built or are being built. Return success
// early (this is v4.0 behavior compatible).
ReplIndexBuildState::IndexCatalogStats indexCatalogStats;
int numIndexes = getNumIndexesTotal(opCtx, collection.get());
indexCatalogStats.numIndexesBefore = numIndexes;
indexCatalogStats.numIndexesAfter = numIndexes;
return SharedSemiFuture(indexCatalogStats);
}
// Bypass the thread pool if we are building indexes on an empty collection.
if (shouldBuildIndexesOnEmptyCollectionSinglePhased(opCtx, collection.get(), protocol)) {
ReplIndexBuildState::IndexCatalogStats indexCatalogStats;
indexCatalogStats.numIndexesBefore = getNumIndexesTotal(opCtx, collection.get());
try {
// Replicate this index build using the old-style createIndexes oplog entry to avoid
// timestamping issues that would result from this empty collection optimization on a
// secondary. If we tried to generate two phase index build startIndexBuild and
// commitIndexBuild oplog entries, this optimization will fail to accurately timestamp
// the catalog update when it uses the timestamp from the startIndexBuild, rather than
// the commitIndexBuild, oplog entry.
writeConflictRetry(opCtx,
"IndexBuildsCoordinator::_filterSpecsAndRegisterBuild",
collection.get()->ns().ns(),
[&] {
WriteUnitOfWork wuow(opCtx);
createIndexesOnEmptyCollection(
opCtx, collection, filteredSpecs, false);
wuow.commit();
});
} catch (DBException& ex) {
ex.addContext(str::stream() << "index build on empty collection failed: " << buildUUID);
return ex.toStatus();
}
indexCatalogStats.numIndexesAfter = getNumIndexesTotal(opCtx, collection.get());
return SharedSemiFuture(indexCatalogStats);
}
auto replIndexBuildState = std::make_shared<ReplIndexBuildState>(
buildUUID, collectionUUID, dbName.toString(), filteredSpecs, protocol);
replIndexBuildState->stats.numIndexesBefore = getNumIndexesTotal(opCtx, collection.get());
auto status = _registerIndexBuild(lk, replIndexBuildState);
if (!status.isOK()) {
return status;
}
// The index has been registered on the Coordinator in an unstarted state. Return an
// uninitialized Future so that the caller can set up the index build by calling
// _setUpIndexBuild(). The completion of the index build will be communicated via a Future
// obtained from 'replIndexBuildState->sharedPromise'.
return boost::none;
}
IndexBuildsCoordinator::PostSetupAction IndexBuildsCoordinator::_setUpIndexBuildInner(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
Timestamp startTimestamp,
const IndexBuildOptions& indexBuildOptions) {
const NamespaceStringOrUUID nssOrUuid{replState->dbName, replState->collectionUUID};
AutoGetCollection coll(opCtx, nssOrUuid, MODE_X);
CollectionWriter collection(coll);
CollectionShardingState::get(opCtx, collection->ns())->checkShardVersionOrThrow(opCtx);
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
const bool replSetAndNotPrimary = replCoord->getSettings().usingReplSets() &&
!replCoord->canAcceptWritesFor(opCtx, collection->ns());
// We will not have a start timestamp if we are newly a secondary (i.e. we started as
// primary but there was a stepdown). We will be unable to timestamp the initial catalog write,
// so we must fail the index build. During initial sync, there is no commit timestamp set.
if (replSetAndNotPrimary &&
indexBuildOptions.applicationMode != ApplicationMode::kInitialSync) {
uassert(ErrorCodes::NotWritablePrimary,
str::stream() << "Replication state changed while setting up the index build: "
<< replState->buildUUID,
!startTimestamp.isNull());
}
MultiIndexBlock::OnInitFn onInitFn;
if (IndexBuildProtocol::kTwoPhase == replState->protocol) {
// Change the startIndexBuild Oplog entry.
// Two-phase index builds write a different oplog entry than the default behavior which
// writes a no-op just to generate an optime.
onInitFn = [&](std::vector<BSONObj>& specs) {
if (!(replCoord->getSettings().usingReplSets() &&
replCoord->canAcceptWritesFor(opCtx, collection->ns()))) {
// Not primary.
return Status::OK();
}
// Two phase index builds should have commit quorum set.
invariant(indexBuildOptions.commitQuorum,
str::stream()
<< "Commit quorum required for two phase index build, buildUUID: "
<< replState->buildUUID
<< " collectionUUID: " << replState->collectionUUID);
// Persist the commit quorum value in the config.system.indexBuilds collection.
IndexBuildEntry indexBuildEntry(replState->buildUUID,
replState->collectionUUID,
indexBuildOptions.commitQuorum.get(),
replState->indexNames);
uassertStatusOK(indexbuildentryhelpers::addIndexBuildEntry(opCtx, indexBuildEntry));
opCtx->getServiceContext()->getOpObserver()->onStartIndexBuild(
opCtx,
collection->ns(),
replState->collectionUUID,
replState->buildUUID,
replState->indexSpecs,
false /* fromMigrate */);
return Status::OK();
};
} else {
onInitFn = MultiIndexBlock::makeTimestampedIndexOnInitFn(opCtx, collection.get());
}
IndexBuildsManager::SetupOptions options;
options.indexConstraints =
repl::ReplicationCoordinator::get(opCtx)->shouldRelaxIndexConstraints(opCtx,
collection->ns())
? IndexBuildsManager::IndexConstraints::kRelax
: IndexBuildsManager::IndexConstraints::kEnforce;
options.protocol = replState->protocol;
try {
if (!replSetAndNotPrimary) {
// On standalones and primaries, call setUpIndexBuild(), which makes the initial catalog
// write. On primaries, this replicates the startIndexBuild oplog entry.
uassertStatusOK(_indexBuildsManager.setUpIndexBuild(
opCtx, collection, replState->indexSpecs, replState->buildUUID, onInitFn, options));
} else {
// If we are starting the index build as a secondary, we must suppress calls to write
// our initial oplog entry in setUpIndexBuild().
repl::UnreplicatedWritesBlock uwb(opCtx);
boost::optional<TimestampBlock> tsBlock;
if (indexBuildOptions.applicationMode != ApplicationMode::kInitialSync) {
// Use the provided timestamp to write the initial catalog entry. Initial sync does
// not set a commit timestamp.
invariant(!startTimestamp.isNull());
tsBlock.emplace(opCtx, startTimestamp);
}
uassertStatusOK(_indexBuildsManager.setUpIndexBuild(
opCtx, collection, replState->indexSpecs, replState->buildUUID, onInitFn, options));
}
} catch (DBException& ex) {
_indexBuildsManager.abortIndexBuild(
opCtx, collection, replState->buildUUID, MultiIndexBlock::kNoopOnCleanUpFn);
const auto& status = ex.toStatus();
if (status == ErrorCodes::IndexAlreadyExists ||
((status == ErrorCodes::IndexOptionsConflict ||
status == ErrorCodes::IndexKeySpecsConflict) &&
options.indexConstraints == IndexBuildsManager::IndexConstraints::kRelax)) {
LOGV2_DEBUG(20662,
1,
"Ignoring indexing error: {error}",
"Ignoring indexing error",
"error"_attr = redact(status));
return PostSetupAction::kCompleteIndexBuildEarly;
}
throw;
}
if (isIndexBuildResumable(opCtx, *replState, indexBuildOptions)) {
// We should only set this value if this is a hybrid index build.
invariant(_indexBuildsManager.isBackgroundBuilding(replState->buildUUID));
// After the interceptors are set, get the latest optime in the oplog that could have
// contained a write to this collection. We need to be holding the collection lock in X mode
// so that we ensure that there are not any uncommitted transactions on this collection.
replState->setLastOpTimeBeforeInterceptors(getLatestOplogOpTime(opCtx));
}
return PostSetupAction::kContinueIndexBuild;
}
Status IndexBuildsCoordinator::_setUpIndexBuild(OperationContext* opCtx,
const UUID& buildUUID,
Timestamp startTimestamp,
const IndexBuildOptions& indexBuildOptions) {
auto replState = invariant(_getIndexBuild(buildUUID));
auto postSetupAction = PostSetupAction::kContinueIndexBuild;
try {
postSetupAction =
_setUpIndexBuildInner(opCtx, replState, startTimestamp, indexBuildOptions);
} catch (const DBException& ex) {
stdx::unique_lock<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replState);
return ex.toStatus();
}
// The indexes are in the durable catalog in an unfinished state. Return an OK status so
// that the caller can continue building the indexes by calling _runIndexBuild().
if (PostSetupAction::kContinueIndexBuild == postSetupAction) {
return Status::OK();
}
// Unregister the index build before setting the promise, so callers do not see the build again.
{
stdx::unique_lock<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replState);
}
// The requested index (specs) are already built or are being built. Return success
// early (this is v4.0 behavior compatible).
invariant(PostSetupAction::kCompleteIndexBuildEarly == postSetupAction,
str::stream() << "failed to set up index build " << buildUUID
<< " with start timestamp " << startTimestamp.toString());
ReplIndexBuildState::IndexCatalogStats indexCatalogStats;
int numIndexes = replState->stats.numIndexesBefore;
indexCatalogStats.numIndexesBefore = numIndexes;
indexCatalogStats.numIndexesAfter = numIndexes;
replState->sharedPromise.emplaceValue(indexCatalogStats);
return Status::OK();
}
void IndexBuildsCoordinator::_runIndexBuild(
OperationContext* opCtx,
const UUID& buildUUID,
const IndexBuildOptions& indexBuildOptions,
const boost::optional<ResumeIndexInfo>& resumeInfo) noexcept {
{
stdx::unique_lock<Latch> lk(_mutex);
while (_sleepForTest) {
lk.unlock();
sleepmillis(100);
lk.lock();
}
}
// If the index build does not exist, do not continue building the index. This may happen if an
// ignorable indexing error occurred during setup. The promise will have been fulfilled, but the
// build has already been unregistered.
auto swReplState = _getIndexBuild(buildUUID);
if (swReplState.getStatus() == ErrorCodes::NoSuchKey) {
return;
}
auto replState = invariant(swReplState);
// Set index build state to in-progress and save OperationContext's opId.
replState->start(opCtx);
// Add build UUID to lock manager diagnostic output.
auto locker = opCtx->lockState();
auto oldLockerDebugInfo = locker->getDebugInfo();
{
str::stream ss;
ss << "index build: " << replState->buildUUID;
if (!oldLockerDebugInfo.empty()) {
ss << "; " << oldLockerDebugInfo;
}
locker->setDebugInfo(ss);
}
auto status = [&]() {
try {
_runIndexBuildInner(opCtx, replState, indexBuildOptions, resumeInfo);
} catch (const DBException& ex) {
return ex.toStatus();
}
return Status::OK();
}();
locker->setDebugInfo(oldLockerDebugInfo);
// Ensure the index build is unregistered from the Coordinator and the Promise is set with
// the build's result so that callers are notified of the outcome.
if (status.isOK()) {
stdx::unique_lock<Latch> lk(_mutex);
// Unregister first so that when we fulfill the future, the build is not observed as active.
_unregisterIndexBuild(lk, replState);
replState->sharedPromise.emplaceValue(replState->stats);
return;
}
// During a failure, unregistering is handled by either the caller or the current thread,
// depending on where the error originated. Signal to any waiters that an error occurred.
replState->sharedPromise.setError(status);
}
namespace {
template <typename Func>
void runOnAlternateContext(OperationContext* opCtx, std::string name, Func func) {
auto newClient = opCtx->getServiceContext()->makeClient(name);
AlternativeClientRegion acr(newClient);
const auto newCtx = cc().makeOperationContext();
func(newCtx.get());
}
} // namespace
void IndexBuildsCoordinator::_cleanUpSinglePhaseAfterFailure(
OperationContext* opCtx,
const CollectionPtr& collection,
std::shared_ptr<ReplIndexBuildState> replState,
const IndexBuildOptions& indexBuildOptions,
const Status& status) {
if (status.isA<ErrorCategory::ShutdownError>()) {
_completeAbortForShutdown(opCtx, replState, collection);
return;
}
// The index builder thread can abort on its own if it is interrupted by a user killop. This
// would prevent us from taking locks. Use a new OperationContext to abort the index build.
runOnAlternateContext(
opCtx, "self-abort", [this, replState, status](OperationContext* abortCtx) {
ShouldNotConflictWithSecondaryBatchApplicationBlock noConflict(abortCtx->lockState());
Lock::DBLock dbLock(abortCtx, replState->dbName, MODE_IX);
// Unlock RSTL to avoid deadlocks with prepare conflicts and state transitions caused by
// taking a strong collection lock. See SERVER-42621.
unlockRSTL(abortCtx);
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
Lock::CollectionLock collLock(abortCtx, dbAndUUID, MODE_X);
_completeSelfAbort(abortCtx, replState, status);
});
}
void IndexBuildsCoordinator::_cleanUpTwoPhaseAfterFailure(
OperationContext* opCtx,
const CollectionPtr& collection,
std::shared_ptr<ReplIndexBuildState> replState,
const IndexBuildOptions& indexBuildOptions,
const Status& status) {
if (status.isA<ErrorCategory::ShutdownError>()) {
_completeAbortForShutdown(opCtx, replState, collection);
return;
}
// The index builder thread can abort on its own if it is interrupted by a user killop. This
// would prevent us from taking locks. Use a new OperationContext to abort the index build.
runOnAlternateContext(
opCtx, "self-abort", [this, replState, status](OperationContext* abortCtx) {
ShouldNotConflictWithSecondaryBatchApplicationBlock noConflict(abortCtx->lockState());
// Take RSTL (implicitly by DBLock) to observe and prevent replication state from
// changing.
Lock::DBLock dbLock(abortCtx, replState->dbName, MODE_IX);
// Index builds may not fail on secondaries. If a primary replicated an abortIndexBuild
// oplog entry, then this index build would have received an IndexBuildAborted error
// code.
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
auto replCoord = repl::ReplicationCoordinator::get(abortCtx);
if (replCoord->getSettings().usingReplSets() &&
!replCoord->canAcceptWritesFor(abortCtx, dbAndUUID)) {
fassert(51101,
status.withContext(str::stream() << "Index build: " << replState->buildUUID
<< "; Database: " << replState->dbName));
}
Lock::CollectionLock collLock(abortCtx, dbAndUUID, MODE_X);
_completeSelfAbort(abortCtx, replState, status);
});
}
void IndexBuildsCoordinator::_runIndexBuildInner(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
const IndexBuildOptions& indexBuildOptions,
const boost::optional<ResumeIndexInfo>& resumeInfo) {
// This Status stays unchanged unless we catch an exception in the following try-catch block.
auto status = Status::OK();
try {
while (MONGO_unlikely(hangAfterInitializingIndexBuild.shouldFail())) {
hangAfterInitializingIndexBuild.pauseWhileSet(opCtx);
}
if (resumeInfo) {
_resumeIndexBuildFromPhase(opCtx, replState, indexBuildOptions, resumeInfo.get());
} else {
_buildIndex(opCtx, replState, indexBuildOptions);
}
} catch (const DBException& ex) {
status = ex.toStatus();
}
if (status.isOK()) {
return;
}
{
// If the index build has already been cleaned-up because it encountered an error at
// commit-time, there is no work to do. This is the most routine case, since index
// constraint checking happens at commit-time for index builds.
if (replState->isAborted()) {
uassertStatusOK(status);
}
}
// We do not hold a collection lock here, but we are protected against the collection being
// dropped while the index build is still registered for the collection -- until abortIndexBuild
// is called. The collection can be renamed, but it is OK for the name to be stale just for
// logging purposes.
auto collectionSharedPtr = CollectionCatalog::get(opCtx).lookupCollectionByUUIDForRead(
opCtx, replState->collectionUUID);
CollectionPtr collection(collectionSharedPtr.get(), CollectionPtr::NoYieldTag{});
invariant(collection,
str::stream() << "Collection with UUID " << replState->collectionUUID
<< " should exist because an index build is in progress: "
<< replState->buildUUID);
NamespaceString nss = collection->ns();
logFailure(status, nss, replState);
// If we received an external abort, the caller should have already set our state to kAborted.
invariant(status.code() != ErrorCodes::IndexBuildAborted);
if (MONGO_unlikely(hangIndexBuildBeforeAbortCleanUp.shouldFail())) {
LOGV2(4753601, "Hanging due to hangIndexBuildBeforeAbortCleanUp fail point");
hangIndexBuildBeforeAbortCleanUp.pauseWhileSet();
}
// Index builds only check index constraints when committing. If an error occurs at that point,
// then the build is cleaned up while still holding the appropriate locks. The only errors that
// we cannot anticipate are user interrupts and shutdown errors.
invariant(status.isA<ErrorCategory::Interruption>() ||
status.isA<ErrorCategory::ShutdownError>(),
str::stream() << "Unexpected error code during index build cleanup: " << status);
if (IndexBuildProtocol::kSinglePhase == replState->protocol) {
_cleanUpSinglePhaseAfterFailure(opCtx, collection, replState, indexBuildOptions, status);
} else {
invariant(IndexBuildProtocol::kTwoPhase == replState->protocol,
str::stream() << replState->buildUUID);
_cleanUpTwoPhaseAfterFailure(opCtx, collection, replState, indexBuildOptions, status);
}
// Any error that escapes at this point is not fatal and can be handled by the caller.
uassertStatusOK(status);
}
void IndexBuildsCoordinator::_resumeIndexBuildFromPhase(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
const IndexBuildOptions& indexBuildOptions,
const ResumeIndexInfo& resumeInfo) {
if (MONGO_unlikely(hangAfterSettingUpResumableIndexBuild.shouldFail())) {
LOGV2(4841704,
"Hanging index build due to failpoint 'hangAfterSettingUpResumableIndexBuild'");
hangAfterSettingUpResumableIndexBuild.pauseWhileSet();
}
if (resumeInfo.getPhase() == IndexBuildPhaseEnum::kInitialized ||
resumeInfo.getPhase() == IndexBuildPhaseEnum::kCollectionScan) {
_scanCollectionAndInsertSortedKeysIntoIndex(
opCtx,
replState,
resumeInfo.getCollectionScanPosition()
? boost::make_optional<RecordId>(RecordId(*resumeInfo.getCollectionScanPosition()))
: boost::none);
} else if (resumeInfo.getPhase() == IndexBuildPhaseEnum::kBulkLoad) {
_insertSortedKeysIntoIndexForResume(opCtx, replState);
}
_insertKeysFromSideTablesWithoutBlockingWrites(opCtx, replState);
_signalPrimaryForCommitReadiness(opCtx, replState);
_insertKeysFromSideTablesBlockingWrites(opCtx, replState, indexBuildOptions);
_waitForNextIndexBuildActionAndCommit(opCtx, replState, indexBuildOptions);
}
void IndexBuildsCoordinator::_awaitLastOpTimeBeforeInterceptorsMajorityCommitted(
OperationContext* opCtx, std::shared_ptr<ReplIndexBuildState> replState) {
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
// The index build is not resumable if the node is in initial sync while building the index.
if (!replState->isResumable()) {
return;
}
auto timeoutMillis = gResumableIndexBuildMajorityOpTimeTimeoutMillis;
if (timeoutMillis == 0) {
// Disable resumable index build.
replState->clearLastOpTimeBeforeInterceptors();
return;
}
Milliseconds timeout;
Date_t deadline;
if (timeoutMillis > 0) {
timeout = Milliseconds(timeoutMillis);
deadline = opCtx->getServiceContext()->getFastClockSource()->now() + timeout;
} else {
// Wait indefinitely for majority commit point.
// Setting 'deadline' to Date_t::max() achieves the same effect as boost::none in
// ReplicationCoordinatorImpl::waitUntilMajorityOpTime(). Additionally, providing a
// 'deadline' of Date_t::max() is given special treatment in
// OperationContext::waitForConditionOrInterruptNoAssertUntil().
timeout = Milliseconds::max();
deadline = Date_t::max();
}
auto lastOpTimeBeforeInterceptors = replState->getLastOpTimeBeforeInterceptors();
LOGV2(4847600,
"Index build: waiting for last optime before interceptors to be majority committed",
"buildUUID"_attr = replState->buildUUID,
"deadline"_attr = deadline,
"timeout"_attr = timeout,
"lastOpTime"_attr = lastOpTimeBeforeInterceptors);
hangIndexBuildBeforeWaitingUntilMajorityOpTime.executeIf(
[opCtx, buildUUID = replState->buildUUID](const BSONObj& data) {
LOGV2(
4940901,
"Hanging index build before waiting for the last optime before interceptors to be "
"majority committed due to hangIndexBuildBeforeWaitingUntilMajorityOpTime "
"failpoint",
"buildUUID"_attr = buildUUID);
hangIndexBuildBeforeWaitingUntilMajorityOpTime.pauseWhileSet(opCtx);
},
[buildUUID = replState->buildUUID](const BSONObj& data) {
auto buildUUIDs = data.getObjectField("buildUUIDs");
return std::any_of(buildUUIDs.begin(), buildUUIDs.end(), [buildUUID](const auto& elem) {
return UUID::parse(elem.String()) == buildUUID;
});
});
auto status = replCoord->waitUntilMajorityOpTime(opCtx, lastOpTimeBeforeInterceptors, deadline);
if (!status.isOK()) {
replState->clearLastOpTimeBeforeInterceptors();
LOGV2(5053900,
"Index build: timed out waiting for the last optime before interceptors to be "
"majority committed. Continuing as a non-resumable index build.",
"buildUUID"_attr = replState->buildUUID,
"deadline"_attr = deadline,
"timeout"_attr = timeout,
"lastOpTime"_attr = lastOpTimeBeforeInterceptors,
"waitStatus"_attr = status);
return;
}
// Since we waited for all the writes before the interceptors were established to be majority
// committed, if we read at the majority commit point for the collection scan, then none of the
// documents put into the sorter can be rolled back.
opCtx->recoveryUnit()->setTimestampReadSource(RecoveryUnit::ReadSource::kMajorityCommitted);
}
void IndexBuildsCoordinator::_buildIndex(OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
const IndexBuildOptions& indexBuildOptions) {
if (MONGO_unlikely(hangBeforeBuildingIndex.shouldFail())) {
LOGV2(4940900,
"Hanging before building index due to hangBeforeBuildingIndex failpoint",
"buildUUID"_attr = replState->buildUUID);
hangBeforeBuildingIndex.pauseWhileSet();
}
// Read without a timestamp. When we commit, we block writes which guarantees all writes are
// visible.
invariant(RecoveryUnit::ReadSource::kNoTimestamp ==
opCtx->recoveryUnit()->getTimestampReadSource());
// The collection scan might read with a kMajorityCommitted read source, but will restore
// kNoTimestamp afterwards.
_scanCollectionAndInsertSortedKeysIntoIndex(opCtx, replState);
_insertKeysFromSideTablesWithoutBlockingWrites(opCtx, replState);
_signalPrimaryForCommitReadiness(opCtx, replState);
_insertKeysFromSideTablesBlockingWrites(opCtx, replState, indexBuildOptions);
_waitForNextIndexBuildActionAndCommit(opCtx, replState, indexBuildOptions);
}
/*
* First phase is doing a collection scan and inserting keys into sorter.
* Second phase is extracting the sorted keys and writing them into the new index table.
*/
void IndexBuildsCoordinator::_scanCollectionAndInsertSortedKeysIntoIndex(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
boost::optional<RecordId> resumeAfterRecordId) {
// Collection scan and insert into index.
{
auto scopeGuard = makeGuard([&] {
opCtx->recoveryUnit()->setTimestampReadSource(RecoveryUnit::ReadSource::kNoTimestamp);
});
// Wait for the last optime before the interceptors are established to be majority committed
// while we aren't holding any locks. This will set the read source to be kMajorityCommitted
// if it waited.
_awaitLastOpTimeBeforeInterceptorsMajorityCommitted(opCtx, replState);
Lock::DBLock autoDb(opCtx, replState->dbName, MODE_IX);
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
Lock::CollectionLock collLock(opCtx, dbAndUUID, MODE_IX);
auto collection = _setUpForScanCollectionAndInsertSortedKeysIntoIndex(opCtx, replState);
uassertStatusOK(_indexBuildsManager.startBuildingIndex(
opCtx, collection, replState->buildUUID, resumeAfterRecordId));
}
if (MONGO_unlikely(hangAfterIndexBuildDumpsInsertsFromBulk.shouldFail())) {
LOGV2(20665, "Hanging after dumping inserts from bulk builder");
hangAfterIndexBuildDumpsInsertsFromBulk.pauseWhileSet();
}
}
void IndexBuildsCoordinator::_insertSortedKeysIntoIndexForResume(
OperationContext* opCtx, std::shared_ptr<ReplIndexBuildState> replState) {
{
Lock::DBLock autoDb(opCtx, replState->dbName, MODE_IX);
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
Lock::CollectionLock collLock(opCtx, dbAndUUID, MODE_IX);
auto collection = _setUpForScanCollectionAndInsertSortedKeysIntoIndex(opCtx, replState);
uassertStatusOK(_indexBuildsManager.resumeBuildingIndexFromBulkLoadPhase(
opCtx, collection, replState->buildUUID));
}
if (MONGO_unlikely(hangAfterIndexBuildDumpsInsertsFromBulk.shouldFail())) {
LOGV2(4940800, "Hanging after dumping inserts from bulk builder");
hangAfterIndexBuildDumpsInsertsFromBulk.pauseWhileSet();
}
}
CollectionPtr IndexBuildsCoordinator::_setUpForScanCollectionAndInsertSortedKeysIntoIndex(
OperationContext* opCtx, std::shared_ptr<ReplIndexBuildState> replState) {
// Rebuilding system indexes during startup using the IndexBuildsCoordinator is done by all
// storage engines if they're missing.
invariant(_indexBuildsManager.isBackgroundBuilding(replState->buildUUID));
auto collection =
CollectionCatalog::get(opCtx).lookupCollectionByUUID(opCtx, replState->collectionUUID);
invariant(collection);
// Set up the thread's currentOp information to display createIndexes cmd information.
updateCurOpOpDescription(opCtx, collection->ns(), replState->indexSpecs);
// Index builds can safely ignore prepare conflicts and perform writes. On secondaries,
// prepare operations wait for index builds to complete.
opCtx->recoveryUnit()->setPrepareConflictBehavior(
PrepareConflictBehavior::kIgnoreConflictsAllowWrites);
return collection;
}
/*
* Third phase is catching up on all the writes that occurred during the first two phases.
*/
void IndexBuildsCoordinator::_insertKeysFromSideTablesWithoutBlockingWrites(
OperationContext* opCtx, std::shared_ptr<ReplIndexBuildState> replState) {
// Perform the first drain while holding an intent lock.
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
{
Lock::DBLock autoDb(opCtx, replState->dbName, MODE_IX);
Lock::CollectionLock collLock(opCtx, dbAndUUID, MODE_IX);
uassertStatusOK(_indexBuildsManager.drainBackgroundWrites(
opCtx,
replState->buildUUID,
getReadSourceForDrainBeforeCommitQuorum(*replState),
IndexBuildInterceptor::DrainYieldPolicy::kYield));
}
if (MONGO_unlikely(hangAfterIndexBuildFirstDrain.shouldFail())) {
LOGV2(20666,
"Hanging after index build first drain",
"buildUUID"_attr = replState->buildUUID);
hangAfterIndexBuildFirstDrain.pauseWhileSet(opCtx);
}
}
void IndexBuildsCoordinator::_insertKeysFromSideTablesBlockingWrites(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
const IndexBuildOptions& indexBuildOptions) {
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
// Perform the second drain while stopping writes on the collection.
{
Lock::DBLock autoDb(opCtx, replState->dbName, MODE_IX);
// Unlock RSTL to avoid deadlocks with prepare conflicts and state transitions. See
// SERVER-42621.
unlockRSTL(opCtx);
Lock::CollectionLock collLock(opCtx, dbAndUUID, MODE_S);
uassertStatusOK(_indexBuildsManager.drainBackgroundWrites(
opCtx,
replState->buildUUID,
getReadSourceForDrainBeforeCommitQuorum(*replState),
IndexBuildInterceptor::DrainYieldPolicy::kNoYield));
}
if (MONGO_unlikely(hangAfterIndexBuildSecondDrain.shouldFail())) {
LOGV2(20667, "Hanging after index build second drain");
hangAfterIndexBuildSecondDrain.pauseWhileSet();
}
}
/**
* Continue the third phase of catching up on all remaining writes that occurred and then commit.
* Accepts a commit timestamp for the index (null if not available).
*/
IndexBuildsCoordinator::CommitResult IndexBuildsCoordinator::_insertKeysFromSideTablesAndCommit(
OperationContext* opCtx,
std::shared_ptr<ReplIndexBuildState> replState,
IndexBuildAction action,
const IndexBuildOptions& indexBuildOptions,
const Timestamp& commitIndexBuildTimestamp) {
if (MONGO_unlikely(hangIndexBuildBeforeCommit.shouldFail())) {
LOGV2(4841706, "Hanging before committing index build");
hangIndexBuildBeforeCommit.pauseWhileSet();
}
Lock::DBLock autoDb(opCtx, replState->dbName, MODE_IX);
// Unlock RSTL to avoid deadlocks with prepare conflicts and state transitions caused by waiting
// for a a strong collection lock. See SERVER-42621.
unlockRSTL(opCtx);
// Need to return the collection lock back to exclusive mode to complete the index build.
const NamespaceStringOrUUID dbAndUUID(replState->dbName, replState->collectionUUID);
Lock::CollectionLock collLock(opCtx, dbAndUUID, MODE_X);
// If we can't acquire the RSTL within a given time period, there is an active state transition
// and we should release our locks and try again. We would otherwise introduce a deadlock with
// step-up by holding the Collection lock in exclusive mode. After it has enqueued its RSTL X
// lock, step-up tries to reacquire the Collection locks for prepared transactions, which will
// conflict with the X lock we currently hold.
repl::ReplicationStateTransitionLockGuard rstl(
opCtx, MODE_IX, repl::ReplicationStateTransitionLockGuard::EnqueueOnly());
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
try {
// Since this thread is not killable by state transitions, this deadline is effectively the
// longest period of time we can block a step-up. State transitions are infrequent, but
// need to happen quickly. It should be okay to set this to a low value because the RSTL is
// rarely contended, and if this times out, we will retry and reacquire the RSTL again
// without a deadline at the beginning of this function.
auto deadline = Date_t::now() + Milliseconds(10);
rstl.waitForLockUntil(deadline);
} catch (const ExceptionFor<ErrorCodes::LockTimeout>&) {
return CommitResult::kLockTimeout;
}
// If we are no longer primary after receiving a commit quorum, we must restart and wait for a
// new signal from a new primary because we cannot commit. Note that two-phase index builds can
// retry because a new signal should be received. Single-phase builds will be unable to commit
// and will self-abort.
bool isMaster = replCoord->canAcceptWritesFor(opCtx, dbAndUUID) &&
!replCoord->getSettings().shouldRecoverFromOplogAsStandalone();
if (!isMaster && IndexBuildAction::kCommitQuorumSatisfied == action) {
return CommitResult::kNoLongerPrimary;
}
if (IndexBuildAction::kOplogCommit == action) {
replState->onOplogCommit(isMaster);
}
// The collection object should always exist while an index build is registered.
CollectionWriter collection(opCtx, replState->collectionUUID);
invariant(collection,
str::stream() << "Collection not found after relocking. Index build: "
<< replState->buildUUID
<< ", collection UUID: " << replState->collectionUUID);
// Perform the third and final drain after releasing a shared lock and reacquiring an exclusive
// lock on the collection.
uassertStatusOK(_indexBuildsManager.drainBackgroundWrites(
opCtx,
replState->buildUUID,
RecoveryUnit::ReadSource::kNoTimestamp,
IndexBuildInterceptor::DrainYieldPolicy::kNoYield));
try {
failIndexBuildOnCommit.execute(
[](const BSONObj&) { uasserted(4698903, "index build aborted due to failpoint"); });
{
auto dss = DatabaseShardingState::get(opCtx, replState->dbName);
auto dssLock = DatabaseShardingState::DSSLock::lockShared(opCtx, dss);
dss->checkDbVersion(opCtx, dssLock);
}
// If we are no longer primary and a single phase index build started as primary attempts to
// commit, trigger a self-abort.
if (!isMaster && IndexBuildAction::kSinglePhaseCommit == action) {
uassertStatusOK(
{ErrorCodes::NotWritablePrimary,
str::stream() << "Unable to commit index build because we are no longer primary: "
<< replState->buildUUID});
}
// Retry indexing records that failed key generation, but only if we are primary.
// Secondaries rely on the primary's decision to commit as assurance that it has checked all
// key generation errors on its behalf.
if (isMaster) {
uassertStatusOK(_indexBuildsManager.retrySkippedRecords(
opCtx, replState->buildUUID, collection.get()));
}
// Duplicate key constraint checking phase. Duplicate key errors are tracked for
// single-phase builds on primaries and two-phase builds in all replication states.
// Single-phase builds on secondaries don't track duplicates so this call is a no-op. This
// can be called for two-phase builds in all replication states except during initial sync
// when this node is not guaranteed to be consistent.
bool twoPhaseAndNotInitialSyncing = IndexBuildProtocol::kTwoPhase == replState->protocol &&
!replCoord->getMemberState().startup2();
if (IndexBuildProtocol::kSinglePhase == replState->protocol ||
twoPhaseAndNotInitialSyncing) {
uassertStatusOK(_indexBuildsManager.checkIndexConstraintViolations(
opCtx, collection.get(), replState->buildUUID));
}
} catch (const ExceptionForCat<ErrorCategory::ShutdownError>& e) {
logFailure(e.toStatus(), collection->ns(), replState);
_completeAbortForShutdown(opCtx, replState, collection.get());
throw;
} catch (const DBException& e) {
auto status = e.toStatus();
logFailure(status, collection->ns(), replState);
// It is illegal to abort the index build at this point. Note that Interruption exceptions
// are allowed because we cannot control them as they bypass the routine abort machinery.
invariant(e.code() != ErrorCodes::IndexBuildAborted);
// Index build commit may not fail on secondaries because it implies diverenge with data on
// the primary. The only exception is single-phase builds started on primaries, which may
// fail after a state transition. In this case, we have not replicated anything to
// roll-back. With two-phase index builds, if a primary replicated an abortIndexBuild oplog
// entry, then this index build should have been interrupted before committing with an
// IndexBuildAborted error code.
const bool twoPhaseAndNotPrimary =
IndexBuildProtocol::kTwoPhase == replState->protocol && !isMaster;
if (twoPhaseAndNotPrimary) {
LOGV2_FATAL(4698902,
"Index build failed while not primary",
"buildUUID"_attr = replState->buildUUID,
"collectionUUID"_attr = replState->collectionUUID,
"db"_attr = replState->dbName,
"error"_attr = status);
}
// This index build failed due to an indexing error in normal circumstances. Abort while
// still holding the RSTL and collection locks.
_completeSelfAbort(opCtx, replState, status);
throw;
}
// If two phase index builds is enabled, index build will be coordinated using
// startIndexBuild and commitIndexBuild oplog entries.
auto onCommitFn = [&] { onCommitIndexBuild(opCtx, collection->ns(), replState); };
auto onCreateEachFn = [&](const BSONObj& spec) {
if (IndexBuildProtocol::kTwoPhase == replState->protocol) {
return;
}
auto opObserver = opCtx->getServiceContext()->getOpObserver();
auto fromMigrate = false;
opObserver->onCreateIndex(
opCtx, collection->ns(), replState->collectionUUID, spec, fromMigrate);
};
// Commit index build.
TimestampBlock tsBlock(opCtx, commitIndexBuildTimestamp);
uassertStatusOK(_indexBuildsManager.commitIndexBuild(
opCtx, collection, collection->ns(), replState->buildUUID, onCreateEachFn, onCommitFn));
removeIndexBuildEntryAfterCommitOrAbort(opCtx, dbAndUUID, *replState);
replState->stats.numIndexesAfter = getNumIndexesTotal(opCtx, collection.get());
LOGV2(20663,
"Index build: completed successfully",
"buildUUID"_attr = replState->buildUUID,
"namespace"_attr = collection->ns(),
"uuid"_attr = replState->collectionUUID,
"indexesBuilt"_attr = replState->indexSpecs.size(),
"numIndexesBefore"_attr = replState->stats.numIndexesBefore,
"numIndexesAfter"_attr = replState->stats.numIndexesAfter);
return CommitResult::kSuccess;
}
StatusWith<std::pair<long long, long long>> IndexBuildsCoordinator::_runIndexRebuildForRecovery(
OperationContext* opCtx,
CollectionWriter& collection,
const UUID& buildUUID,
RepairData repair) noexcept {
invariant(opCtx->lockState()->isCollectionLockedForMode(collection->ns(), MODE_X));
auto replState = invariant(_getIndexBuild(buildUUID));
// We rely on 'collection' for any collection information because no databases are open during
// recovery.
NamespaceString nss = collection->ns();
invariant(!nss.isEmpty());
auto status = Status::OK();
long long numRecords = 0;
long long dataSize = 0;
ReplIndexBuildState::IndexCatalogStats indexCatalogStats;
indexCatalogStats.numIndexesBefore = getNumIndexesTotal(opCtx, collection.get());
try {
LOGV2(20673,
"Index builds manager starting: {buildUUID}: {namespace}",
"Index builds manager starting",
"buildUUID"_attr = buildUUID,
logAttrs(nss));
std::tie(numRecords, dataSize) =
uassertStatusOK(_indexBuildsManager.startBuildingIndexForRecovery(
opCtx, collection.get(), buildUUID, repair));
// Since we are holding an exclusive collection lock to stop new writes, do not yield locks
// while draining.
uassertStatusOK(_indexBuildsManager.drainBackgroundWrites(
opCtx,
replState->buildUUID,
RecoveryUnit::ReadSource::kNoTimestamp,
IndexBuildInterceptor::DrainYieldPolicy::kNoYield));
uassertStatusOK(_indexBuildsManager.checkIndexConstraintViolations(
opCtx, collection.get(), replState->buildUUID));
// Commit the index build.
uassertStatusOK(_indexBuildsManager.commitIndexBuild(opCtx,
collection,
nss,
buildUUID,
MultiIndexBlock::kNoopOnCreateEachFn,
MultiIndexBlock::kNoopOnCommitFn));
indexCatalogStats.numIndexesAfter = getNumIndexesTotal(opCtx, collection.get());
LOGV2(20674,
"Index builds manager completed successfully: {buildUUID}: {namespace}. Index specs "
"requested: {indexSpecsRequested}. Indexes in catalog before build: "
"{numIndexesBefore}. Indexes in catalog after build: {numIndexesAfter}",
"Index builds manager completed successfully",
"buildUUID"_attr = buildUUID,
logAttrs(nss),
"indexSpecsRequested"_attr = replState->indexSpecs.size(),
"numIndexesBefore"_attr = indexCatalogStats.numIndexesBefore,
"numIndexesAfter"_attr = indexCatalogStats.numIndexesAfter);
} catch (const DBException& ex) {
status = ex.toStatus();
invariant(status != ErrorCodes::IndexAlreadyExists);
LOGV2(20675,
"Index builds manager failed: {buildUUID}: {namespace}: {error}",
"Index builds manager failed",
"buildUUID"_attr = buildUUID,
logAttrs(nss),
"error"_attr = status);
}
// Index build is registered in manager regardless of IndexBuildsManager::setUpIndexBuild()
// result.
if (!status.isOK()) {
// An index build failure during recovery is fatal.
logFailure(status, nss, replState);
fassertNoTrace(51076, status);
}
// 'numIndexesBefore' was before we cleared any unfinished indexes, so it must be the same
// as 'numIndexesAfter', since we're going to be building any unfinished indexes too.
invariant(indexCatalogStats.numIndexesBefore == indexCatalogStats.numIndexesAfter);
{
stdx::unique_lock<Latch> lk(_mutex);
_unregisterIndexBuild(lk, replState);
}
if (status.isOK()) {
return std::make_pair(numRecords, dataSize);
}
return status;
}
StatusWith<std::shared_ptr<ReplIndexBuildState>> IndexBuildsCoordinator::_getIndexBuild(
const UUID& buildUUID) const {
stdx::unique_lock<Latch> lk(_mutex);
auto it = _allIndexBuilds.find(buildUUID);
if (it == _allIndexBuilds.end()) {
return {ErrorCodes::NoSuchKey, str::stream() << "No index build with UUID: " << buildUUID};
}
return it->second;
}
std::vector<std::shared_ptr<ReplIndexBuildState>> IndexBuildsCoordinator::_getIndexBuilds() const {
stdx::unique_lock<Latch> lk(_mutex);
auto filter = [](const auto& replState) { return true; };
return _filterIndexBuilds_inlock(lk, filter);
}
std::vector<std::shared_ptr<ReplIndexBuildState>> IndexBuildsCoordinator::_filterIndexBuilds_inlock(
WithLock lk, IndexBuildFilterFn indexBuildFilter) const {
std::vector<std::shared_ptr<ReplIndexBuildState>> indexBuilds;
for (auto pair : _allIndexBuilds) {
auto replState = pair.second;
if (!indexBuildFilter(*replState)) {
continue;
}
indexBuilds.push_back(replState);
}
return indexBuilds;
}
int IndexBuildsCoordinator::getNumIndexesTotal(OperationContext* opCtx,
const CollectionPtr& collection) {
invariant(collection);
const auto& nss = collection->ns();
invariant(opCtx->lockState()->isLocked(),
str::stream() << "Unable to get index count because collection was not locked"
<< nss);
auto indexCatalog = collection->getIndexCatalog();
invariant(indexCatalog, str::stream() << "Collection is missing index catalog: " << nss);
return indexCatalog->numIndexesTotal(opCtx);
}
std::vector<BSONObj> IndexBuildsCoordinator::prepareSpecListForCreate(
OperationContext* opCtx,
const CollectionPtr& collection,
const NamespaceString& nss,
const std::vector<BSONObj>& indexSpecs) {
UncommittedCollections::get(opCtx).invariantHasExclusiveAccessToCollection(opCtx,
collection->ns());
invariant(collection);
// During secondary oplog application, the index specs have already been normalized in the
// oplog entries read from the primary. We should not be modifying the specs any further.
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (replCoord->getSettings().usingReplSets() && !replCoord->canAcceptWritesFor(opCtx, nss)) {
return indexSpecs;
}
// Normalize the specs' collations, wildcard projections, and partial filters as applicable.
auto normalSpecs = normalizeIndexSpecs(opCtx, collection, indexSpecs);
// Remove any index specifications which already exist in the catalog.
auto indexCatalog = collection->getIndexCatalog();
auto resultSpecs =
indexCatalog->removeExistingIndexes(opCtx, normalSpecs, true /*removeIndexBuildsToo*/);
// Verify that each spec is compatible with the collection's sharding state.
for (const BSONObj& spec : resultSpecs) {
if (spec[kUniqueFieldName].trueValue()) {
checkShardKeyRestrictions(opCtx, nss, spec[kKeyFieldName].Obj());
}
}
return resultSpecs;
}
std::vector<BSONObj> IndexBuildsCoordinator::normalizeIndexSpecs(
OperationContext* opCtx,
const CollectionPtr& collection,
const std::vector<BSONObj>& indexSpecs) {
// This helper function may be called before the collection is created, when we are attempting
// to check whether the candidate index collides with any existing indexes. If 'collection' is
// nullptr, skip normalization. Since the collection does not exist there cannot be a conflict,
// and we will normalize once the candidate spec is submitted to the IndexBuildsCoordinator.
if (!collection) {
return indexSpecs;
}
// Add collection-default collation where needed and normalize the collation in each index spec.
auto normalSpecs =
uassertStatusOK(collection->addCollationDefaultsToIndexSpecsForCreate(opCtx, indexSpecs));
// If the index spec has a partialFilterExpression, we normalize it by parsing to an optimized,
// sorted MatchExpression tree, re-serialize it to BSON, and add it back into the index spec.
const auto expCtx = make_intrusive<ExpressionContext>(opCtx, nullptr, collection->ns());
std::transform(normalSpecs.begin(), normalSpecs.end(), normalSpecs.begin(), [&](auto& spec) {
const auto kPartialFilterName = IndexDescriptor::kPartialFilterExprFieldName;
auto partialFilterExpr = spec.getObjectField(kPartialFilterName);
if (partialFilterExpr.isEmpty()) {
return spec;
}
// Parse, optimize and sort the MatchExpression to reduce it to its normalized form.
// Serialize the normalized filter back into the index spec before returning.
auto partialFilter = MatchExpressionParser::parseAndNormalize(partialFilterExpr, expCtx);
return spec.addField(BSON(kPartialFilterName << partialFilter->serialize()).firstElement());
});
// If any of the specs describe wildcard indexes, normalize the wildcard projections if present.
// This will change all specs of the form {"a.b.c": 1} to normalized form {a: {b: {c : 1}}}.
std::transform(normalSpecs.begin(), normalSpecs.end(), normalSpecs.begin(), [](auto& spec) {
const auto kProjectionName = IndexDescriptor::kPathProjectionFieldName;
const auto pathProjectionSpec = spec.getObjectField(kProjectionName);
static const auto kWildcardKeyPattern = BSON("$**" << 1);
if (pathProjectionSpec.isEmpty()) {
return spec;
}
auto wildcardProjection =
WildcardKeyGenerator::createProjectionExecutor(kWildcardKeyPattern, pathProjectionSpec);
auto normalizedProjection =
wildcardProjection.exec()->serializeTransformation(boost::none).toBson();
return spec.addField(BSON(kProjectionName << normalizedProjection).firstElement());
});
return normalSpecs;
}
bool IndexBuildsCoordinator::supportsResumableIndexBuilds() const {
auto serviceContext = getGlobalServiceContext();
invariant(serviceContext);
auto storageEngine = serviceContext->getStorageEngine();
invariant(storageEngine);
return storageEngine->supportsResumableIndexBuilds();
}
} // namespace mongo
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