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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_LOG_DEFAULT_COMPONENT ::mongo::logger::LogComponent::kSharding
#include "mongo/platform/basic.h"
#include "mongo/db/s/metadata_manager.h"
#include <memory>
#include "mongo/base/string_data.h"
#include "mongo/bson/simple_bsonobj_comparator.h"
#include "mongo/bson/util/builder.h"
#include "mongo/db/query/internal_plans.h"
#include "mongo/db/range_arithmetic.h"
#include "mongo/db/s/range_deletion_util.h"
#include "mongo/db/s/sharding_runtime_d_params_gen.h"
#include "mongo/logv2/log.h"
#include "mongo/s/grid.h"
#include "mongo/util/assert_util.h"
#include "mongo/util/fail_point.h"
#include "mongo/util/log.h"
#include "mongo/util/time_support.h"
namespace mongo {
namespace {
using TaskExecutor = executor::TaskExecutor;
using CallbackArgs = TaskExecutor::CallbackArgs;
} // namespace
class RangePreserver : public ScopedCollectionMetadata::Impl {
public:
// Must be called locked with the MetadataManager's _managerLock
RangePreserver(WithLock,
std::shared_ptr<MetadataManager> metadataManager,
std::shared_ptr<MetadataManager::CollectionMetadataTracker> metadataTracker)
: _metadataManager(std::move(metadataManager)),
_metadataTracker(std::move(metadataTracker)) {
++_metadataTracker->usageCounter;
}
~RangePreserver() {
stdx::lock_guard<Latch> managerLock(_metadataManager->_managerLock);
invariant(_metadataTracker->usageCounter != 0);
if (--_metadataTracker->usageCounter == 0) {
// MetadataManager doesn't care which usageCounter went to zero. It just retires all
// that are older than the oldest metadata still in use by queries (some start out at
// zero, some go to zero but can't be expired yet).
//
// Note that new instances of ScopedCollectionMetadata may get attached to
// _metadata.back(), so its usage count can increase from zero, unlike other reference
// counts.
_metadataManager->_retireExpiredMetadata(managerLock);
}
}
// This will only ever refer to the active metadata, so CollectionMetadata should never be
// boost::none
const CollectionMetadata& get() {
invariant(_metadataTracker->metadata);
return _metadataTracker->metadata.get();
}
private:
std::shared_ptr<MetadataManager> _metadataManager;
std::shared_ptr<MetadataManager::CollectionMetadataTracker> _metadataTracker;
};
MetadataManager::MetadataManager(ServiceContext* serviceContext,
NamespaceString nss,
std::shared_ptr<TaskExecutor> executor,
CollectionMetadata initialMetadata)
: _serviceContext(serviceContext),
_nss(std::move(nss)),
_collectionUuid(*initialMetadata.getChunkManager()->getUUID()),
_executor(std::move(executor)),
_receivingChunks(SimpleBSONObjComparator::kInstance.makeBSONObjIndexedMap<BSONObj>()) {
_metadata.emplace_back(std::make_shared<CollectionMetadataTracker>(std::move(initialMetadata)));
}
ScopedCollectionMetadata MetadataManager::getActiveMetadata(
const boost::optional<LogicalTime>& atClusterTime) {
stdx::lock_guard<Latch> lg(_managerLock);
auto activeMetadataTracker = _metadata.back();
const auto& activeMetadata = activeMetadataTracker->metadata;
// We don't keep routing history for unsharded collections, so if the collection is unsharded
// just return the active metadata
if (!atClusterTime || !activeMetadata->isSharded()) {
return ScopedCollectionMetadata(std::make_shared<RangePreserver>(
lg, shared_from_this(), std::move(activeMetadataTracker)));
}
auto chunkManager = activeMetadata->getChunkManager();
auto chunkManagerAtClusterTime = std::make_shared<ChunkManager>(
chunkManager->getRoutingHistory(), atClusterTime->asTimestamp());
class MetadataAtTimestamp : public ScopedCollectionMetadata::Impl {
public:
MetadataAtTimestamp(CollectionMetadata metadata) : _metadata(std::move(metadata)) {}
const CollectionMetadata& get() override {
return _metadata;
}
private:
CollectionMetadata _metadata;
};
return ScopedCollectionMetadata(std::make_shared<MetadataAtTimestamp>(
CollectionMetadata(chunkManagerAtClusterTime, activeMetadata->shardId())));
}
size_t MetadataManager::numberOfMetadataSnapshots() const {
stdx::lock_guard<Latch> lg(_managerLock);
invariant(!_metadata.empty());
return _metadata.size() - 1;
}
int MetadataManager::numberOfEmptyMetadataSnapshots() const {
stdx::lock_guard<Latch> lg(_managerLock);
int emptyMetadataSnapshots = 0;
for (const auto& collMetadataTracker : _metadata) {
if (!collMetadataTracker->metadata)
emptyMetadataSnapshots++;
}
return emptyMetadataSnapshots;
}
void MetadataManager::setFilteringMetadata(CollectionMetadata remoteMetadata) {
stdx::lock_guard<Latch> lg(_managerLock);
invariant(!_metadata.empty());
// The active metadata should always be available (not boost::none)
invariant(_metadata.back()->metadata);
const auto& activeMetadata = _metadata.back()->metadata.get();
// We already have the same or newer version
if (activeMetadata.getCollVersion().epoch() == remoteMetadata.getCollVersion().epoch() &&
activeMetadata.getCollVersion() >= remoteMetadata.getCollVersion()) {
LOGV2_DEBUG(21984,
1,
"Ignoring update of active metadata {activeMetadata_Basic} with an older "
"{remoteMetadata_Basic}",
"activeMetadata_Basic"_attr = activeMetadata.toStringBasic(),
"remoteMetadata_Basic"_attr = remoteMetadata.toStringBasic());
return;
}
LOGV2(21985,
"Updating metadata for collection {nss_ns} from {activeMetadata_Basic} to "
"{remoteMetadata_Basic} due to version change",
"nss_ns"_attr = _nss.ns(),
"activeMetadata_Basic"_attr = activeMetadata.toStringBasic(),
"remoteMetadata_Basic"_attr = remoteMetadata.toStringBasic());
// Resolve any receiving chunks, which might have completed by now
for (auto it = _receivingChunks.begin(); it != _receivingChunks.end();) {
const ChunkRange receivingRange(it->first, it->second);
if (!remoteMetadata.rangeOverlapsChunk(receivingRange)) {
++it;
continue;
}
// The remote metadata contains a chunk we were earlier in the process of receiving, so we
// deem it successfully received
LOGV2_DEBUG(21986,
2,
"Verified chunk {receivingRange} for collection {nss_ns} has been migrated to "
"this shard earlier",
"receivingRange"_attr = redact(receivingRange.toString()),
"nss_ns"_attr = _nss.ns());
_receivingChunks.erase(it);
it = _receivingChunks.begin();
}
_setActiveMetadata(lg, std::move(remoteMetadata));
}
void MetadataManager::_setActiveMetadata(WithLock wl, CollectionMetadata newMetadata) {
_metadata.emplace_back(std::make_shared<CollectionMetadataTracker>(std::move(newMetadata)));
_retireExpiredMetadata(wl);
}
void MetadataManager::_retireExpiredMetadata(WithLock) {
// Remove entries with a usage count of 0 from the front of _metadata, which may schedule
// orphans for deletion. We cannot remove an entry from the middle of _metadata because a
// previous entry (whose usageCount is not 0) could have a query that is actually still
// accessing those documents.
while (_metadata.size() > 1 && !_metadata.front()->usageCounter) {
_metadata.pop_front();
}
// To avoid memory build up of ChunkManager objects, we can clear the CollectionMetadata object
// in an entry when its usageCount is 0 as long as it is not the last item in _metadata (which
// is the active metadata). If _metadata is empty, decrementing iter will be out of bounds, so
// we must check that the size is > 1 as well.
if (_metadata.size() > 1) {
auto iter = _metadata.begin();
while (iter != (--_metadata.end())) {
if ((*iter)->usageCounter == 0) {
(*iter)->metadata = boost::none;
}
++iter;
}
}
}
void MetadataManager::toBSONPending(BSONArrayBuilder& bb) const {
stdx::lock_guard<Latch> lg(_managerLock);
for (auto it = _receivingChunks.begin(); it != _receivingChunks.end(); ++it) {
BSONArrayBuilder pendingBB(bb.subarrayStart());
pendingBB.append(it->first);
pendingBB.append(it->second);
pendingBB.done();
}
}
void MetadataManager::append(BSONObjBuilder* builder) const {
stdx::lock_guard<Latch> lg(_managerLock);
BSONArrayBuilder arr(builder->subarrayStart("rangesToClean"));
for (auto const& [range, _] : _rangesScheduledForDeletion) {
BSONObjBuilder obj;
range.append(&obj);
arr.append(obj.done());
}
BSONArrayBuilder pcArr(builder->subarrayStart("pendingChunks"));
for (const auto& entry : _receivingChunks) {
BSONObjBuilder obj;
ChunkRange r = ChunkRange(entry.first, entry.second);
r.append(&obj);
pcArr.append(obj.done());
}
pcArr.done();
invariant(!_metadata.empty());
BSONArrayBuilder amrArr(builder->subarrayStart("activeMetadataRanges"));
for (const auto& entry : _metadata.back()->metadata->getChunks()) {
BSONObjBuilder obj;
ChunkRange r = ChunkRange(entry.first, entry.second);
r.append(&obj);
amrArr.append(obj.done());
}
amrArr.done();
}
SharedSemiFuture<void> MetadataManager::beginReceive(ChunkRange const& range) {
stdx::lock_guard<Latch> lg(_managerLock);
invariant(!_metadata.empty());
if (_overlapsInUseChunk(lg, range)) {
return Status{ErrorCodes::RangeOverlapConflict,
"Documents in target range may still be in use on the destination shard."};
}
_receivingChunks.emplace(range.getMin().getOwned(), range.getMax().getOwned());
LOGV2(21987,
"Scheduling deletion of any documents in {nss_ns} range {range} before migrating in a "
"chunk covering the range",
"nss_ns"_attr = _nss.ns(),
"range"_attr = redact(range.toString()));
return _submitRangeForDeletion(
lg, SemiFuture<void>::makeReady(), range, Seconds(orphanCleanupDelaySecs.load()));
}
void MetadataManager::forgetReceive(ChunkRange const& range) {
stdx::lock_guard<Latch> lg(_managerLock);
invariant(!_metadata.empty());
// This is potentially a partially received chunk, which needs to be cleaned up. We know none
// of these documents are in use, so they can go straight to the deletion queue.
LOGV2(21988,
"Abandoning in-migration of {nss_ns} range {range}; scheduling deletion of any documents "
"already copied",
"nss_ns"_attr = _nss.ns(),
"range"_attr = range);
invariant(!_overlapsInUseChunk(lg, range));
auto it = _receivingChunks.find(range.getMin());
invariant(it != _receivingChunks.end());
_receivingChunks.erase(it);
std::ignore = _submitRangeForDeletion(lg, SemiFuture<void>::makeReady(), range, Seconds(0));
}
SharedSemiFuture<void> MetadataManager::cleanUpRange(ChunkRange const& range,
bool shouldDelayBeforeDeletion) {
stdx::lock_guard<Latch> lg(_managerLock);
invariant(!_metadata.empty());
auto* const activeMetadata = _metadata.back().get();
auto* const overlapMetadata = _findNewestOverlappingMetadata(lg, range);
if (overlapMetadata == activeMetadata) {
return Status{ErrorCodes::RangeOverlapConflict,
str::stream() << "Requested deletion range overlaps a live shard chunk"};
}
if (rangeMapOverlaps(_receivingChunks, range.getMin(), range.getMax())) {
return Status{ErrorCodes::RangeOverlapConflict,
str::stream() << "Requested deletion range overlaps a chunk being"
" migrated in"};
}
auto delayForActiveQueriesOnSecondariesToComplete =
shouldDelayBeforeDeletion ? Seconds(orphanCleanupDelaySecs.load()) : Seconds(0);
if (overlapMetadata) {
LOGV2(21989,
"Deletion of {nss_ns} range {range} will be scheduled after all possibly dependent "
"queries finish",
"nss_ns"_attr = _nss.ns(),
"range"_attr = redact(range.toString()));
++overlapMetadata->numContingentRangeDeletionTasks;
// Schedule the range for deletion once the overlapping metadata object is destroyed
// (meaning no more queries can be using the range) and obtain a future which will be
// signaled when deletion is complete.
return _submitRangeForDeletion(lg,
overlapMetadata->onDestructionPromise.getFuture().semi(),
range,
delayForActiveQueriesOnSecondariesToComplete);
} else {
// No running queries can depend on this range, so queue it for deletion immediately.
LOGV2(21990,
"Scheduling deletion of {nss_ns} range {range}",
"nss_ns"_attr = _nss.ns(),
"range"_attr = redact(range.toString()));
return _submitRangeForDeletion(
lg, SemiFuture<void>::makeReady(), range, delayForActiveQueriesOnSecondariesToComplete);
}
}
size_t MetadataManager::numberOfRangesToCleanStillInUse() const {
stdx::lock_guard<Latch> lg(_managerLock);
size_t count = 0;
for (auto& tracker : _metadata) {
count += tracker->numContingentRangeDeletionTasks;
}
return count;
}
size_t MetadataManager::numberOfRangesToClean() const {
auto rangesToCleanInUse = numberOfRangesToCleanStillInUse();
stdx::lock_guard<Latch> lg(_managerLock);
return _rangesScheduledForDeletion.size() - rangesToCleanInUse;
}
boost::optional<SharedSemiFuture<void>> MetadataManager::trackOrphanedDataCleanup(
ChunkRange const& range) const {
stdx::lock_guard<Latch> lg(_managerLock);
for (const auto& [orphanRange, deletionComplete] : _rangesScheduledForDeletion) {
if (orphanRange.overlapWith(range)) {
return deletionComplete;
}
}
return boost::none;
}
auto MetadataManager::_findNewestOverlappingMetadata(WithLock, ChunkRange const& range)
-> CollectionMetadataTracker* {
invariant(!_metadata.empty());
auto it = _metadata.rbegin();
if ((*it)->metadata && (*it)->metadata->rangeOverlapsChunk(range)) {
return (*it).get();
}
++it;
for (; it != _metadata.rend(); ++it) {
auto& tracker = *it;
if (tracker->usageCounter && tracker->metadata &&
tracker->metadata->rangeOverlapsChunk(range)) {
return tracker.get();
}
}
return nullptr;
}
bool MetadataManager::_overlapsInUseChunk(WithLock lk, ChunkRange const& range) {
auto* cm = _findNewestOverlappingMetadata(lk, range);
return (cm != nullptr);
}
boost::optional<ChunkRange> MetadataManager::getNextOrphanRange(BSONObj const& from) const {
stdx::lock_guard<Latch> lg(_managerLock);
invariant(!_metadata.empty());
return _metadata.back()->metadata->getNextOrphanRange(_receivingChunks, from);
}
SharedSemiFuture<void> MetadataManager::_submitRangeForDeletion(
const WithLock&,
SemiFuture<void> waitForActiveQueriesToComplete,
const ChunkRange& range,
Seconds delayForActiveQueriesOnSecondariesToComplete) {
int maxToDelete = rangeDeleterBatchSize.load();
if (maxToDelete <= 0) {
maxToDelete = std::max(int(internalQueryExecYieldIterations.load()), 1);
}
auto cleanupComplete =
removeDocumentsInRange(_executor,
std::move(waitForActiveQueriesToComplete),
_nss,
*_metadata.back()->metadata->getChunkManager()->getUUID(),
_metadata.back()->metadata->getKeyPattern().getOwned(),
range,
maxToDelete,
delayForActiveQueriesOnSecondariesToComplete,
Milliseconds(rangeDeleterBatchDelayMS.load()));
_rangesScheduledForDeletion.emplace_front(range, cleanupComplete);
// Attach a continuation so that once the range has been deleted, we will remove the deletion
// from the _rangesScheduledForDeletion. std::list iterators are never invalidated, which
// allows us to save the iterator pointing to the newly added element for use later when
// deleting it.
cleanupComplete.thenRunOn(_executor).getAsync(
[self = shared_from_this(), it = _rangesScheduledForDeletion.begin()](Status s) {
stdx::lock_guard<Latch> lg(self->_managerLock);
self->_rangesScheduledForDeletion.erase(it);
});
return cleanupComplete;
}
} // namespace mongo
|