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/**
* Copyright (C) 2015 MongoDB Inc.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License, version 3,
* as published by the Free Software Foundation.
*
* 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
* GNU Affero General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
* 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 GNU Affero General 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/s/chunk_manager.h"
#include <iterator>
#include <map>
#include <set>
#include "mongo/bson/util/bson_extract.h"
#include "mongo/client/read_preference.h"
#include "mongo/client/remote_command_targeter.h"
#include "mongo/db/matcher/extensions_callback_noop.h"
#include "mongo/db/namespace_string.h"
#include "mongo/db/query/index_bounds_builder.h"
#include "mongo/db/query/query_planner.h"
#include "mongo/db/query/query_planner_common.h"
#include "mongo/rpc/get_status_from_command_result.h"
#include "mongo/s/balancer/balancer_configuration.h"
#include "mongo/s/catalog/catalog_cache.h"
#include "mongo/s/catalog/catalog_manager.h"
#include "mongo/s/catalog/type_collection.h"
#include "mongo/s/chunk.h"
#include "mongo/s/chunk_diff.h"
#include "mongo/s/client/shard_registry.h"
#include "mongo/s/config.h"
#include "mongo/s/grid.h"
#include "mongo/s/shard_util.h"
#include "mongo/util/log.h"
#include "mongo/util/timer.h"
namespace mongo {
using std::make_pair;
using std::map;
using std::max;
using std::pair;
using std::set;
using std::shared_ptr;
using std::string;
using std::unique_ptr;
using std::vector;
namespace {
/**
* This is an adapter so we can use config diffs - mongos and mongod do them slightly
* differently
*
* The mongos adapter here tracks all shards, and stores ranges by (max, Chunk) in the map.
*/
class CMConfigDiffTracker : public ConfigDiffTracker<shared_ptr<Chunk>> {
public:
CMConfigDiffTracker(ChunkManager* manager) : _manager(manager) {}
bool isTracked(const ChunkType& chunk) const final {
// Mongos tracks all shards
return true;
}
bool isMinKeyIndexed() const final {
return false;
}
pair<BSONObj, shared_ptr<Chunk>> rangeFor(OperationContext* txn,
const ChunkType& chunk) const final {
shared_ptr<Chunk> c(new Chunk(txn, _manager, chunk));
return make_pair(chunk.getMax(), c);
}
string shardFor(OperationContext* txn, const string& hostName) const final {
const auto shard = grid.shardRegistry()->getShard(txn, hostName);
return shard->getId();
}
private:
ChunkManager* const _manager;
};
bool allOfType(BSONType type, const BSONObj& o) {
BSONObjIterator it(o);
while (it.more()) {
if (it.next().type() != type) {
return false;
}
}
return true;
}
bool isChunkMapValid(const ChunkMap& chunkMap) {
#define ENSURE(x) \
do { \
if (!(x)) { \
log() << "ChunkManager::_isValid failed: " #x; \
return false; \
} \
} while (0)
if (chunkMap.empty()) {
return true;
}
// Check endpoints
ENSURE(allOfType(MinKey, chunkMap.begin()->second->getMin()));
ENSURE(allOfType(MaxKey, boost::prior(chunkMap.end())->second->getMax()));
// Make sure there are no gaps or overlaps
for (ChunkMap::const_iterator it = boost::next(chunkMap.begin()), end = chunkMap.end();
it != end;
++it) {
ChunkMap::const_iterator last = boost::prior(it);
if (!(it->second->getMin() == last->second->getMax())) {
log() << last->second->toString();
log() << it->second->toString();
log() << it->second->getMin();
log() << last->second->getMax();
}
ENSURE(it->second->getMin() == last->second->getMax());
}
return true;
#undef ENSURE
}
} // namespace
AtomicUInt32 ChunkManager::NextSequenceNumber(1U);
ChunkManager::ChunkManager(const string& ns, const ShardKeyPattern& pattern, bool unique)
: _ns(ns),
_keyPattern(pattern.getKeyPattern()),
_unique(unique),
_sequenceNumber(NextSequenceNumber.addAndFetch(1)) {}
ChunkManager::ChunkManager(const CollectionType& coll)
: _ns(coll.getNs().ns()),
_keyPattern(coll.getKeyPattern()),
_unique(coll.getUnique()),
_sequenceNumber(NextSequenceNumber.addAndFetch(1)) {
// coll does not have correct version. Use same initial version as _load and createFirstChunks.
_version = ChunkVersion(0, 0, coll.getEpoch());
}
void ChunkManager::loadExistingRanges(OperationContext* txn, const ChunkManager* oldManager) {
int tries = 3;
while (tries--) {
ChunkMap chunkMap;
set<ShardId> shardIds;
ShardVersionMap shardVersions;
Timer t;
bool success = _load(txn, chunkMap, shardIds, &shardVersions, oldManager);
if (success) {
log() << "ChunkManager: time to load chunks for " << _ns << ": " << t.millis() << "ms"
<< " sequenceNumber: " << _sequenceNumber << " version: " << _version.toString()
<< " based on: "
<< (oldManager ? oldManager->getVersion().toString() : "(empty)");
// TODO: Merge into diff code above, so we validate in one place
if (isChunkMapValid(chunkMap)) {
_chunkMap.swap(chunkMap);
_shardIds.swap(shardIds);
_shardVersions.swap(shardVersions);
_chunkRangeMap = _constructRanges(_chunkMap);
return;
}
}
warning() << "ChunkManager loaded an invalid config for " << _ns << ", trying again";
sleepmillis(10 * (3 - tries));
}
// This will abort construction so we should never have a reference to an invalid config
msgasserted(13282,
str::stream() << "Couldn't load a valid config for " << _ns
<< " after 3 attempts. Please try again.");
}
bool ChunkManager::_load(OperationContext* txn,
ChunkMap& chunkMap,
set<ShardId>& shardIds,
ShardVersionMap* shardVersions,
const ChunkManager* oldManager) {
// Reset the max version, but not the epoch, when we aren't loading from the oldManager
_version = ChunkVersion(0, 0, _version.epoch());
// If we have a previous version of the ChunkManager to work from, use that info to reduce
// our config query
if (oldManager && oldManager->getVersion().isSet()) {
// Get the old max version
_version = oldManager->getVersion();
// Load a copy of the old versions
*shardVersions = oldManager->_shardVersions;
// Load a copy of the chunk map, replacing the chunk manager with our own
const ChunkMap& oldChunkMap = oldManager->getChunkMap();
// Could be v.expensive
// TODO: If chunks were immutable and didn't reference the manager, we could do more
// interesting things here
for (const auto& oldChunkMapEntry : oldChunkMap) {
shared_ptr<Chunk> oldC = oldChunkMapEntry.second;
shared_ptr<Chunk> newC(new Chunk(this,
oldC->getMin(),
oldC->getMax(),
oldC->getShardId(),
oldC->getLastmod(),
oldC->getBytesWritten()));
chunkMap.insert(make_pair(oldC->getMax(), newC));
}
LOG(2) << "loading chunk manager for collection " << _ns
<< " using old chunk manager w/ version " << _version.toString() << " and "
<< oldChunkMap.size() << " chunks";
}
// Attach a diff tracker for the versioned chunk data
CMConfigDiffTracker differ(this);
differ.attach(_ns, chunkMap, _version, *shardVersions);
// Diff tracker should *always* find at least one chunk if collection exists
// Get the diff query required
auto diffQuery = differ.configDiffQuery();
repl::OpTime opTime;
std::vector<ChunkType> chunks;
uassertStatusOK(grid.catalogManager(txn)->getChunks(
txn, diffQuery.query, diffQuery.sort, boost::none, &chunks, &opTime));
invariant(opTime >= _configOpTime);
_configOpTime = opTime;
int diffsApplied = differ.calculateConfigDiff(txn, chunks);
if (diffsApplied > 0) {
LOG(2) << "loaded " << diffsApplied << " chunks into new chunk manager for " << _ns
<< " with version " << _version;
// Add all existing shards we find to the shards set
for (ShardVersionMap::iterator it = shardVersions->begin(); it != shardVersions->end();) {
shared_ptr<Shard> shard = grid.shardRegistry()->getShard(txn, it->first);
if (shard) {
shardIds.insert(it->first);
++it;
} else {
shardVersions->erase(it++);
}
}
_configOpTime = opTime;
return true;
} else if (diffsApplied == 0) {
// No chunks were found for the ns
warning() << "no chunks found when reloading " << _ns << ", previous version was "
<< _version;
// Set all our data to empty
chunkMap.clear();
shardVersions->clear();
_version = ChunkVersion(0, 0, OID());
_configOpTime = opTime;
return true;
} else { // diffsApplied < 0
bool allInconsistent = (differ.numValidDiffs() == 0);
if (allInconsistent) {
// All versions are different, this can be normal
warning() << "major change in chunk information found when reloading " << _ns
<< ", previous version was " << _version;
} else {
// Inconsistent load halfway through (due to yielding cursor during load)
// should be rare
warning() << "inconsistent chunks found when reloading " << _ns
<< ", previous version was " << _version << ", this should be rare";
}
// Set all our data to empty to be extra safe
chunkMap.clear();
shardVersions->clear();
_version = ChunkVersion(0, 0, OID());
return allInconsistent;
}
}
shared_ptr<ChunkManager> ChunkManager::reload(OperationContext* txn, bool force) const {
const NamespaceString nss(_ns);
auto config = uassertStatusOK(grid.catalogCache()->getDatabase(txn, nss.db().toString()));
return config->getChunkManagerIfExists(txn, getns(), force);
}
void ChunkManager::_printChunks() const {
for (ChunkMap::const_iterator it = _chunkMap.begin(), end = _chunkMap.end(); it != end; ++it) {
log() << *it->second;
}
}
void ChunkManager::calcInitSplitsAndShards(OperationContext* txn,
const ShardId& primaryShardId,
const vector<BSONObj>* initPoints,
const set<ShardId>* initShardIds,
vector<BSONObj>* splitPoints,
vector<ShardId>* shardIds) const {
invariant(_chunkMap.empty());
if (!initPoints || initPoints->empty()) {
// discover split points
const auto primaryShard = grid.shardRegistry()->getShard(txn, primaryShardId);
const NamespaceString nss{getns()};
auto result = uassertStatusOK(
primaryShard->runCommand(txn,
ReadPreferenceSetting{ReadPreference::PrimaryPreferred},
nss.db().toString(),
BSON("count" << nss.coll()),
Shard::RetryPolicy::kIdempotent));
long long numObjects = 0;
uassertStatusOK(result.commandStatus);
uassertStatusOK(bsonExtractIntegerField(result.response, "n", &numObjects));
if (numObjects > 0) {
*splitPoints = uassertStatusOK(shardutil::selectChunkSplitPoints(
txn,
primaryShardId,
NamespaceString(_ns),
_keyPattern,
_keyPattern.getKeyPattern().globalMin(),
_keyPattern.getKeyPattern().globalMax(),
Grid::get(txn)->getBalancerConfiguration()->getMaxChunkSizeBytes(),
0,
0));
}
// since docs already exists, must use primary shard
shardIds->push_back(primaryShardId);
} else {
// make sure points are unique and ordered
set<BSONObj> orderedPts;
for (unsigned i = 0; i < initPoints->size(); ++i) {
BSONObj pt = (*initPoints)[i];
orderedPts.insert(pt);
}
for (set<BSONObj>::iterator it = orderedPts.begin(); it != orderedPts.end(); ++it) {
splitPoints->push_back(*it);
}
if (!initShardIds || !initShardIds->size()) {
// If not specified, only use the primary shard (note that it's not safe for mongos
// to put initial chunks on other shards without the primary mongod knowing).
shardIds->push_back(primaryShardId);
} else {
std::copy(initShardIds->begin(), initShardIds->end(), std::back_inserter(*shardIds));
}
}
}
Status ChunkManager::createFirstChunks(OperationContext* txn,
const ShardId& primaryShardId,
const vector<BSONObj>* initPoints,
const set<ShardId>* initShardIds) {
// TODO distlock?
// TODO: Race condition if we shard the collection and insert data while we split across
// the non-primary shard.
vector<BSONObj> splitPoints;
vector<ShardId> shardIds;
calcInitSplitsAndShards(txn, primaryShardId, initPoints, initShardIds, &splitPoints, &shardIds);
// this is the first chunk; start the versioning from scratch
ChunkVersion version(1, 0, OID::gen());
log() << "going to create " << splitPoints.size() + 1 << " chunk(s) for: " << _ns
<< " using new epoch " << version.epoch();
for (unsigned i = 0; i <= splitPoints.size(); i++) {
BSONObj min = i == 0 ? _keyPattern.getKeyPattern().globalMin() : splitPoints[i - 1];
BSONObj max =
i < splitPoints.size() ? splitPoints[i] : _keyPattern.getKeyPattern().globalMax();
ChunkType chunk;
chunk.setNS(_ns);
chunk.setMin(min);
chunk.setMax(max);
chunk.setShard(shardIds[i % shardIds.size()]);
chunk.setVersion(version);
Status status = grid.catalogManager(txn)
->insertConfigDocument(txn, ChunkType::ConfigNS, chunk.toBSON());
if (!status.isOK()) {
const string errMsg = str::stream()
<< "Creating first chunks failed: " << status.reason();
error() << errMsg;
return Status(status.code(), errMsg);
}
version.incMinor();
}
_version = ChunkVersion(0, 0, version.epoch());
return Status::OK();
}
shared_ptr<Chunk> ChunkManager::findIntersectingChunk(OperationContext* txn,
const BSONObj& shardKey) const {
{
BSONObj chunkMin;
shared_ptr<Chunk> chunk;
{
ChunkMap::const_iterator it = _chunkMap.upper_bound(shardKey);
if (it != _chunkMap.end()) {
chunkMin = it->first;
chunk = it->second;
}
}
if (chunk) {
if (chunk->containsKey(shardKey)) {
return chunk;
}
log() << chunkMin;
log() << *chunk;
log() << shardKey;
reload(txn);
msgasserted(13141, "Chunk map pointed to incorrect chunk");
}
}
msgasserted(8070,
str::stream() << "couldn't find a chunk intersecting: " << shardKey
<< " for ns: " << _ns << " at version: " << _version.toString()
<< ", number of chunks: " << _chunkMap.size());
}
void ChunkManager::getShardIdsForQuery(OperationContext* txn,
const BSONObj& query,
set<ShardId>* shardIds) const {
auto lpq = stdx::make_unique<LiteParsedQuery>(NamespaceString(_ns));
lpq->setFilter(query);
auto statusWithCQ = CanonicalQuery::canonicalize(txn, std::move(lpq), ExtensionsCallbackNoop());
uassertStatusOK(statusWithCQ.getStatus());
unique_ptr<CanonicalQuery> cq = std::move(statusWithCQ.getValue());
// Query validation
if (QueryPlannerCommon::hasNode(cq->root(), MatchExpression::GEO_NEAR)) {
uasserted(13501, "use geoNear command rather than $near query");
}
// Fast path for targeting equalities on the shard key.
auto shardKeyToFind = _keyPattern.extractShardKeyFromQuery(*cq);
if (shardKeyToFind.isOK() && !shardKeyToFind.getValue().isEmpty()) {
auto chunk = findIntersectingChunk(txn, shardKeyToFind.getValue());
shardIds->insert(chunk->getShardId());
return;
}
// Transforms query into bounds for each field in the shard key
// for example :
// Key { a: 1, b: 1 },
// Query { a : { $gte : 1, $lt : 2 },
// b : { $gte : 3, $lt : 4 } }
// => Bounds { a : [1, 2), b : [3, 4) }
IndexBounds bounds = getIndexBoundsForQuery(_keyPattern.toBSON(), *cq);
// Transforms bounds for each shard key field into full shard key ranges
// for example :
// Key { a : 1, b : 1 }
// Bounds { a : [1, 2), b : [3, 4) }
// => Ranges { a : 1, b : 3 } => { a : 2, b : 4 }
BoundList ranges = _keyPattern.flattenBounds(bounds);
for (BoundList::const_iterator it = ranges.begin(); it != ranges.end(); ++it) {
getShardIdsForRange(*shardIds, it->first /*min*/, it->second /*max*/);
// once we know we need to visit all shards no need to keep looping
if (shardIds->size() == _shardIds.size())
break;
}
// SERVER-4914 Some clients of getShardIdsForQuery() assume at least one shard will be returned.
// For now, we satisfy that assumption by adding a shard with no matches rather than returning
// an empty set of shards.
if (shardIds->empty()) {
shardIds->insert(_chunkRangeMap.begin()->second.getShardId());
}
}
void ChunkManager::getShardIdsForRange(set<ShardId>& shardIds,
const BSONObj& min,
const BSONObj& max) const {
auto it = _chunkRangeMap.upper_bound(min);
auto end = _chunkRangeMap.upper_bound(max);
// The chunk range map must always cover the entire key space
invariant(it != _chunkRangeMap.end());
// We need to include the last chunk
if (end != _chunkRangeMap.cend()) {
++end;
}
for (; it != end; ++it) {
shardIds.insert(it->second.getShardId());
// No need to iterate through the rest of the ranges, because we already know we need to use
// all shards.
if (shardIds.size() == _shardIds.size()) {
break;
}
}
}
void ChunkManager::getAllShardIds(set<ShardId>* all) const {
dassert(all);
all->insert(_shardIds.begin(), _shardIds.end());
}
IndexBounds ChunkManager::getIndexBoundsForQuery(const BSONObj& key,
const CanonicalQuery& canonicalQuery) {
// TODO: special-casing TEXT here is no longer necessary. The work to remove this special case
// is being tracked at SERVER-21511.
if (QueryPlannerCommon::hasNode(canonicalQuery.root(), MatchExpression::TEXT)) {
IndexBounds bounds;
IndexBoundsBuilder::allValuesBounds(key, &bounds); // [minKey, maxKey]
return bounds;
}
// Consider shard key as an index
string accessMethod = IndexNames::findPluginName(key);
dassert(accessMethod == IndexNames::BTREE || accessMethod == IndexNames::HASHED);
// Use query framework to generate index bounds
QueryPlannerParams plannerParams;
// Must use "shard key" index
plannerParams.options = QueryPlannerParams::NO_TABLE_SCAN;
IndexEntry indexEntry(key,
accessMethod,
false /* multiKey */,
MultikeyPaths{},
false /* sparse */,
false /* unique */,
"shardkey",
NULL /* filterExpr */,
BSONObj(),
NULL /* collator */);
plannerParams.indices.push_back(indexEntry);
OwnedPointerVector<QuerySolution> solutions;
Status status = QueryPlanner::plan(canonicalQuery, plannerParams, &solutions.mutableVector());
uassert(status.code(), status.reason(), status.isOK());
IndexBounds bounds;
for (vector<QuerySolution*>::const_iterator it = solutions.begin();
bounds.size() == 0 && it != solutions.end();
it++) {
// Try next solution if we failed to generate index bounds, i.e. bounds.size() == 0
bounds = collapseQuerySolution((*it)->root.get());
}
if (bounds.size() == 0) {
// We cannot plan the query without collection scan, so target to all shards.
IndexBoundsBuilder::allValuesBounds(key, &bounds); // [minKey, maxKey]
}
return bounds;
}
IndexBounds ChunkManager::collapseQuerySolution(const QuerySolutionNode* node) {
if (node->children.size() == 0) {
invariant(node->getType() == STAGE_IXSCAN);
const IndexScanNode* ixNode = static_cast<const IndexScanNode*>(node);
return ixNode->bounds;
}
if (node->children.size() == 1) {
// e.g. FETCH -> IXSCAN
return collapseQuerySolution(node->children.front());
}
// children.size() > 1, assert it's OR / SORT_MERGE.
if (node->getType() != STAGE_OR && node->getType() != STAGE_SORT_MERGE) {
// Unexpected node. We should never reach here.
error() << "could not generate index bounds on query solution tree: " << node->toString();
dassert(false); // We'd like to know this error in testing.
// Bail out with all shards in production, since this isn't a fatal error.
return IndexBounds();
}
IndexBounds bounds;
for (vector<QuerySolutionNode*>::const_iterator it = node->children.begin();
it != node->children.end();
it++) {
// The first branch under OR
if (it == node->children.begin()) {
invariant(bounds.size() == 0);
bounds = collapseQuerySolution(*it);
if (bounds.size() == 0) { // Got unexpected node in query solution tree
return IndexBounds();
}
continue;
}
IndexBounds childBounds = collapseQuerySolution(*it);
if (childBounds.size() == 0) { // Got unexpected node in query solution tree
return IndexBounds();
}
invariant(childBounds.size() == bounds.size());
for (size_t i = 0; i < bounds.size(); i++) {
bounds.fields[i].intervals.insert(bounds.fields[i].intervals.end(),
childBounds.fields[i].intervals.begin(),
childBounds.fields[i].intervals.end());
}
}
for (size_t i = 0; i < bounds.size(); i++) {
IndexBoundsBuilder::unionize(&bounds.fields[i]);
}
return bounds;
}
bool ChunkManager::compatibleWith(const ChunkManager& other, const string& shardName) const {
// Return true if the shard version is the same in the two chunk managers
// TODO: This doesn't need to be so strong, just major vs
return other.getVersion(shardName).equals(getVersion(shardName));
}
ChunkVersion ChunkManager::getVersion(const std::string& shardName) const {
ShardVersionMap::const_iterator i = _shardVersions.find(shardName);
if (i == _shardVersions.end()) {
// Shards without explicitly tracked shard versions (meaning they have
// no chunks) always have a version of (0, 0, epoch). Note this is
// *different* from the dropped chunk version of (0, 0, OID(000...)).
// See s/chunk_version.h.
return ChunkVersion(0, 0, _version.epoch());
}
return i->second;
}
ChunkVersion ChunkManager::getVersion() const {
return _version;
}
string ChunkManager::toString() const {
StringBuilder sb;
sb << "ChunkManager: " << _ns << " key:" << _keyPattern.toString() << '\n';
for (ChunkMap::const_iterator i = _chunkMap.begin(); i != _chunkMap.end(); ++i) {
sb << "\t" << i->second->toString() << '\n';
}
return sb.str();
}
ChunkManager::ChunkRangeMap ChunkManager::_constructRanges(const ChunkMap& chunkMap) {
ChunkRangeMap chunkRangeMap;
if (chunkMap.empty()) {
return chunkRangeMap;
}
ChunkMap::const_iterator current = chunkMap.cbegin();
while (current != chunkMap.cend()) {
const auto rangeFirst = current;
current = std::find_if(current,
chunkMap.cend(),
[&rangeFirst](const ChunkMap::value_type& chunkMapEntry) {
return chunkMapEntry.second->getShardId() !=
rangeFirst->second->getShardId();
});
const auto rangeLast = std::prev(current);
const BSONObj rangeMin = rangeFirst->second->getMin();
const BSONObj rangeMax = rangeLast->second->getMax();
auto insertResult = chunkRangeMap.insert(std::make_pair(
rangeMax, ShardAndChunkRange(rangeMin, rangeMax, rangeFirst->second->getShardId())));
invariant(insertResult.second);
if (insertResult.first != chunkRangeMap.begin()) {
// Make sure there are no gaps in the ranges
insertResult.first--;
invariant(insertResult.first->first == rangeMin);
}
}
invariant(!chunkRangeMap.empty());
invariant(allOfType(MinKey, chunkRangeMap.begin()->second.getMin()));
invariant(allOfType(MaxKey, chunkRangeMap.rbegin()->first));
return chunkRangeMap;
}
uint64_t ChunkManager::getCurrentDesiredChunkSize() const {
// split faster in early chunks helps spread out an initial load better
const uint64_t minChunkSize = 1 << 20; // 1 MBytes
uint64_t splitThreshold = grid.getBalancerConfiguration()->getMaxChunkSizeBytes();
int nc = numChunks();
if (nc <= 1) {
return 1024;
} else if (nc < 3) {
return minChunkSize / 2;
} else if (nc < 10) {
splitThreshold = max(splitThreshold / 4, minChunkSize);
} else if (nc < 20) {
splitThreshold = max(splitThreshold / 2, minChunkSize);
}
return splitThreshold;
}
repl::OpTime ChunkManager::getConfigOpTime() const {
return _configOpTime;
}
} // namespace mongo
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