std::unique_ptr<Message> LegacyReplyBuilder::done() { invariant(_state == State::kOutputDocs); BSONObj reply = uassertStatusOK(rpc::downconvertReplyMetadata(_commandReply, _metadata)); BufBuilder bufBuilder; bufBuilder.skip(sizeof(QueryResult::Value)); if (_allowAddingOutputDocs) { BSONObjBuilder topBuilder(bufBuilder); for (const auto& el : reply) { if (kCursorTag != el.fieldNameStringData()) { topBuilder.append(el); continue; } invariant(el.isABSONObj()); BSONObjBuilder curBuilder(topBuilder.subobjStart(kCursorTag)); for (const auto& insideEl : el.Obj()) { if (kFirstBatchTag != insideEl.fieldNameStringData()) { curBuilder.append(insideEl); continue; } invariant(insideEl.isABSONObj()); BSONArrayBuilder arrBuilder(curBuilder.subarrayStart(kFirstBatchTag)); for (const auto& doc : _outputDocs) { arrBuilder.append(doc); } arrBuilder.doneFast(); } curBuilder.doneFast(); } topBuilder.doneFast(); } else { reply.appendSelfToBufBuilder(bufBuilder); } auto msgHeaderSz = static_cast<std::size_t>(MsgData::MsgDataHeaderSize); invariant(static_cast<std::size_t>(bufBuilder.len()) + msgHeaderSz <= mongol::MaxMessageSizeBytes); QueryResult::View qr = bufBuilder.buf(); qr.setResultFlagsToOk(); qr.msgdata().setLen(bufBuilder.len()); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); _message->setData(qr.view2ptr(), true); bufBuilder.decouple(); _state = State::kDone; return std::move(_message); }
void generateLegacyQueryErrorResponse(const AssertionException* exception, const QueryMessage& queryMessage, CurOp* curop, Message* response) { curop->debug().exceptionInfo = exception->getInfo(); log(LogComponent::kQuery) << "assertion " << exception->toString() << " ns:" << queryMessage.ns << " query:" << (queryMessage.query.valid() ? queryMessage.query.toString() : "query object is corrupt"); if (queryMessage.ntoskip || queryMessage.ntoreturn) { log(LogComponent::kQuery) << " ntoskip:" << queryMessage.ntoskip << " ntoreturn:" << queryMessage.ntoreturn; } const SendStaleConfigException* scex = (exception->getCode() == ErrorCodes::SendStaleConfig) ? static_cast<const SendStaleConfigException*>(exception) : NULL; BSONObjBuilder err; exception->getInfo().append(err); if (scex) { err.append("ok", 0.0); err.append("ns", scex->getns()); scex->getVersionReceived().addToBSON(err, "vReceived"); scex->getVersionWanted().addToBSON(err, "vWanted"); } BSONObj errObj = err.done(); if (scex) { log(LogComponent::kQuery) << "stale version detected during query over " << queryMessage.ns << " : " << errObj; } BufBuilder bb; bb.skip(sizeof(QueryResult::Value)); bb.appendBuf((void*)errObj.objdata(), errObj.objsize()); // TODO: call replyToQuery() from here instead of this!!! see dbmessage.h QueryResult::View msgdata = bb.buf(); bb.decouple(); QueryResult::View qr = msgdata; qr.setResultFlags(ResultFlag_ErrSet); if (scex) qr.setResultFlags(qr.getResultFlags() | ResultFlag_ShardConfigStale); qr.msgdata().setLen(bb.len()); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); response->setData(msgdata.view2ptr(), true); }
void replyToQuery( int queryResultFlags, Message& response, const BSONObj& resultObj ) { BufBuilder bufBuilder; bufBuilder.skip( sizeof( QueryResult::Value )); bufBuilder.appendBuf( reinterpret_cast< void *>( const_cast< char* >( resultObj.objdata() )), resultObj.objsize() ); QueryResult::View queryResult = bufBuilder.buf(); bufBuilder.decouple(); queryResult.setResultFlags(queryResultFlags); queryResult.msgdata().setLen(bufBuilder.len()); queryResult.msgdata().setOperation( opReply ); queryResult.setCursorId(0); queryResult.setStartingFrom(0); queryResult.setNReturned(1); response.setData( queryResult.view2ptr(), true ); // transport will free }
Message LegacyReplyBuilder::done() { invariant(_state == State::kOutputDocs); QueryResult::View qr = _builder.buf(); qr.setResultFlagsToOk(); qr.msgdata().setLen(_builder.len()); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); _message.setData(qr.view2ptr(), true); _builder.decouple(); _state = State::kDone; return std::move(_message); }
void replyToQuery(int queryResultFlags, AbstractMessagingPort* p, Message& requestMsg, void *data, int size, int nReturned, int startingFrom, long long cursorId ) { BufBuilder b(32768); b.skip(sizeof(QueryResult::Value)); b.appendBuf(data, size); QueryResult::View qr = b.buf(); qr.setResultFlags(queryResultFlags); qr.msgdata().setLen(b.len()); qr.msgdata().setOperation(opReply); qr.setCursorId(cursorId); qr.setStartingFrom(startingFrom); qr.setNReturned(nReturned); b.decouple(); Message resp(qr.view2ptr(), true); p->reply(requestMsg, resp, requestMsg.header().getId()); }
void OpQueryReplyBuilder::putInMessage( Message* out, int queryResultFlags, int nReturned, int startingFrom, long long cursorId) { QueryResult::View qr = _buffer.buf(); qr.setResultFlags(queryResultFlags); qr.msgdata().setLen(_buffer.len()); qr.msgdata().setOperation(opReply); qr.setCursorId(cursorId); qr.setStartingFrom(startingFrom); qr.setNReturned(nReturned); out->setData(_buffer.release()); // transport will free }
Message LegacyReplyBuilder::done() { invariant(_haveCommandReply); QueryResult::View qr = _builder.buf(); if (_staleConfigError) { // For compatibility with legacy mongos, we need to set this result flag on StaleConfig qr.setResultFlags(ResultFlag_ErrSet | ResultFlag_ShardConfigStale); } else { qr.setResultFlagsToOk(); } qr.msgdata().setLen(_builder.len()); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); _message.setData(_builder.release()); return std::move(_message); }
LegacyReply::LegacyReply(const Message* message) : _message(std::move(message)) { invariant(message->operation() == opReply); QueryResult::View qr = _message->singleData().view2ptr(); // should be checked by caller. invariant(qr.msgdata().getNetworkOp() == opReply); uassert(ErrorCodes::BadValue, str::stream() << "Got legacy command reply with a bad cursorId field," << " expected a value of 0 but got " << qr.getCursorId(), qr.getCursorId() == 0); uassert(ErrorCodes::BadValue, str::stream() << "Got legacy command reply with a bad nReturned field," << " expected a value of 1 but got " << qr.getNReturned(), qr.getNReturned() == 1); uassert(ErrorCodes::BadValue, str::stream() << "Got legacy command reply with a bad startingFrom field," << " expected a value of 0 but got " << qr.getStartingFrom(), qr.getStartingFrom() == 0); std::tie(_commandReply, _metadata) = uassertStatusOK(rpc::upconvertReplyMetadata(BSONObj(qr.data()))); // Copy the bson array of documents from the message into // a contiguous area of memory owned by _docBuffer so // DocumentRange can be used to iterate over documents auto cursorElem = _commandReply[LegacyReplyBuilder::kCursorTag]; if (cursorElem.eoo()) return; BSONObj cursorObj = cursorElem.Obj(); auto firstBatchElem = cursorObj[LegacyReplyBuilder::kFirstBatchTag]; if (firstBatchElem.eoo()) return; for (BSONObjIterator it(firstBatchElem.Obj()); it.more(); it.next()) { invariant((*it).isABSONObj()); BSONObj doc = (*it).Obj(); doc.appendSelfToBufBuilder(_docBuffer); } const char* dataBegin = _docBuffer.buf(); const char* dataEnd = dataBegin + _docBuffer.len(); _outputDocs = DocumentRange(dataBegin, dataEnd); return; }
LegacyReply::LegacyReply(const Message* message) { invariant(message->operation() == opReply); QueryResult::View qr = message->singleData().view2ptr(); // should be checked by caller. invariant(qr.msgdata().getNetworkOp() == opReply); uassert(ErrorCodes::BadValue, str::stream() << "Got legacy command reply with a bad cursorId field," << " expected a value of 0 but got " << qr.getCursorId(), qr.getCursorId() == 0); uassert(ErrorCodes::BadValue, str::stream() << "Got legacy command reply with a bad nReturned field," << " expected a value of 1 but got " << qr.getNReturned(), qr.getNReturned() == 1); uassert(ErrorCodes::BadValue, str::stream() << "Got legacy command reply with a bad startingFrom field," << " expected a value of 0 but got " << qr.getStartingFrom(), qr.getStartingFrom() == 0); auto status = Validator<BSONObj>::validateLoad(qr.data(), qr.dataLen()); uassert(ErrorCodes::InvalidBSON, str::stream() << "Got legacy command reply with invalid BSON in the metadata field" << causedBy(status), status.isOK()); _commandReply = BSONObj(qr.data()); _commandReply.shareOwnershipWith(message->sharedBuffer()); if (_commandReply.firstElementFieldName() == "$err"_sd) { // Upconvert legacy errors. BSONObjBuilder bob; bob.appendAs(_commandReply.firstElement(), "errmsg"); bob.append("ok", 0.0); if (auto code = _commandReply["code"]) { bob.append(code); } _commandReply = bob.obj(); } return; }
std::string newRunQuery(OperationContext* txn, Message& m, QueryMessage& q, CurOp& curop, Message &result, bool fromDBDirectClient) { // Validate the namespace. const char *ns = q.ns; uassert(16332, "can't have an empty ns", ns[0]); const NamespaceString nsString(ns); uassert(16256, str::stream() << "Invalid ns [" << ns << "]", nsString.isValid()); // Set curop information. curop.debug().ns = ns; curop.debug().ntoreturn = q.ntoreturn; curop.debug().query = q.query; curop.setQuery(q.query); // If the query is really a command, run it. if (nsString.isCommand()) { int nToReturn = q.ntoreturn; uassert(16979, str::stream() << "bad numberToReturn (" << nToReturn << ") for $cmd type ns - can only be 1 or -1", nToReturn == 1 || nToReturn == -1); curop.markCommand(); BufBuilder bb; bb.skip(sizeof(QueryResult::Value)); BSONObjBuilder cmdResBuf; if (!runCommands(txn, ns, q.query, curop, bb, cmdResBuf, false, q.queryOptions)) { uasserted(13530, "bad or malformed command request?"); } curop.debug().iscommand = true; // TODO: Does this get overwritten/do we really need to set this twice? curop.debug().query = q.query; QueryResult::View qr = bb.buf(); bb.decouple(); qr.setResultFlagsToOk(); qr.msgdata().setLen(bb.len()); curop.debug().responseLength = bb.len(); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); result.setData(qr.view2ptr(), true); return ""; } const NamespaceString nss(q.ns); // Parse the qm into a CanonicalQuery. CanonicalQuery* cq; Status canonStatus = CanonicalQuery::canonicalize( q, &cq, WhereCallbackReal(txn, StringData(nss.db()))); if (!canonStatus.isOK()) { uasserted(17287, str::stream() << "Can't canonicalize query: " << canonStatus.toString()); } QLOG() << "Running query:\n" << cq->toString(); LOG(2) << "Running query: " << cq->toStringShort(); // Parse, canonicalize, plan, transcribe, and get a plan executor. PlanExecutor* rawExec = NULL; // We use this a lot below. const LiteParsedQuery& pq = cq->getParsed(); AutoGetCollectionForRead ctx(txn, nss); const int dbProfilingLevel = (ctx.getDb() != NULL) ? ctx.getDb()->getProfilingLevel() : serverGlobalParams.defaultProfile; Collection* collection = ctx.getCollection(); // We'll now try to get the query executor that will execute this query for us. There // are a few cases in which we know upfront which executor we should get and, therefore, // we shortcut the selection process here. // // (a) If the query is over a collection that doesn't exist, we use an EOFStage. // // (b) if the query is a replication's initial sync one, we use a specifically designed // stage that skips extents faster (see details in exec/oplogstart.h). // // Otherwise we go through the selection of which executor is most suited to the // query + run-time context at hand. Status status = Status::OK(); if (NULL != collection && pq.getOptions().oplogReplay) { // Takes ownership of 'cq'. status = getOplogStartHack(txn, collection, cq, &rawExec); } else { size_t options = QueryPlannerParams::DEFAULT; if (shardingState.needCollectionMetadata(pq.ns())) { options |= QueryPlannerParams::INCLUDE_SHARD_FILTER; } // Takes ownership of 'cq'. status = getExecutor(txn, collection, cq, PlanExecutor::YIELD_AUTO, &rawExec, options); } if (!status.isOK()) { // NOTE: Do not access cq as getExecutor has deleted it. uasserted(17007, "Unable to execute query: " + status.reason()); } verify(NULL != rawExec); auto_ptr<PlanExecutor> exec(rawExec); // If it's actually an explain, do the explain and return rather than falling through // to the normal query execution loop. if (pq.isExplain()) { BufBuilder bb; bb.skip(sizeof(QueryResult::Value)); BSONObjBuilder explainBob; Explain::explainStages(exec.get(), ExplainCommon::EXEC_ALL_PLANS, &explainBob); // Add the resulting object to the return buffer. BSONObj explainObj = explainBob.obj(); bb.appendBuf((void*)explainObj.objdata(), explainObj.objsize()); curop.debug().iscommand = true; // TODO: Does this get overwritten/do we really need to set this twice? curop.debug().query = q.query; // Set query result fields. QueryResult::View qr = bb.buf(); bb.decouple(); qr.setResultFlagsToOk(); qr.msgdata().setLen(bb.len()); curop.debug().responseLength = bb.len(); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); result.setData(qr.view2ptr(), true); return ""; } // We freak out later if this changes before we're done with the query. const ChunkVersion shardingVersionAtStart = shardingState.getVersion(cq->ns()); // Handle query option $maxTimeMS (not used with commands). curop.setMaxTimeMicros(static_cast<unsigned long long>(pq.getMaxTimeMS()) * 1000); txn->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. // uassert if we are not on a primary, and not a secondary with SlaveOk query parameter set. bool slaveOK = pq.getOptions().slaveOk || pq.hasReadPref(); status = repl::getGlobalReplicationCoordinator()->checkCanServeReadsFor( txn, NamespaceString(cq->ns()), slaveOK); uassertStatusOK(status); // If this exists, the collection is sharded. // If it doesn't exist, we can assume we're not sharded. // If we're sharded, we might encounter data that is not consistent with our sharding state. // We must ignore this data. CollectionMetadataPtr collMetadata; if (!shardingState.needCollectionMetadata(pq.ns())) { collMetadata = CollectionMetadataPtr(); } else { collMetadata = shardingState.getCollectionMetadata(pq.ns()); } // Run the query. // bb is used to hold query results // this buffer should contain either requested documents per query or // explain information, but not both BufBuilder bb(32768); bb.skip(sizeof(QueryResult::Value)); // How many results have we obtained from the executor? int numResults = 0; // If we're replaying the oplog, we save the last time that we read. OpTime slaveReadTill; // Do we save the PlanExecutor in a ClientCursor for getMore calls later? bool saveClientCursor = false; BSONObj obj; PlanExecutor::ExecState state; // uint64_t numMisplacedDocs = 0; // Get summary info about which plan the executor is using. curop.debug().planSummary = Explain::getPlanSummary(exec.get()); while (PlanExecutor::ADVANCED == (state = exec->getNext(&obj, NULL))) { // Add result to output buffer. bb.appendBuf((void*)obj.objdata(), obj.objsize()); // Count the result. ++numResults; // Possibly note slave's position in the oplog. if (pq.getOptions().oplogReplay) { BSONElement e = obj["ts"]; if (Date == e.type() || Timestamp == e.type()) { slaveReadTill = e._opTime(); } } // TODO: only one type of 2d search doesn't support this. We need a way to pull it out // of CanonicalQuery. :( const bool supportsGetMore = true; if (!supportsGetMore && (enough(pq, numResults) || bb.len() >= MaxBytesToReturnToClientAtOnce)) { break; } else if (enoughForFirstBatch(pq, numResults, bb.len())) { QLOG() << "Enough for first batch, wantMore=" << pq.wantMore() << " numToReturn=" << pq.getNumToReturn() << " numResults=" << numResults << endl; // If only one result requested assume it's a findOne() and don't save the cursor. if (pq.wantMore() && 1 != pq.getNumToReturn()) { QLOG() << " executor EOF=" << exec->isEOF() << endl; saveClientCursor = !exec->isEOF(); } break; } } // If we cache the executor later, we want to deregister it as it receives notifications // anyway by virtue of being cached. // // If we don't cache the executor later, we are deleting it, so it must be deregistered. // // So, no matter what, deregister the executor. exec->deregisterExec(); // Caller expects exceptions thrown in certain cases. if (PlanExecutor::EXEC_ERROR == state) { scoped_ptr<PlanStageStats> stats(exec->getStats()); error() << "Plan executor error, stats: " << Explain::statsToBSON(*stats); uasserted(17144, "Executor error: " + WorkingSetCommon::toStatusString(obj)); } // Why save a dead executor? if (PlanExecutor::DEAD == state) { saveClientCursor = false; } else if (pq.getOptions().tailable) { // If we're tailing a capped collection, we don't bother saving the cursor if the // collection is empty. Otherwise, the semantics of the tailable cursor is that the // client will keep trying to read from it. So we'll keep it around. if (collection && collection->numRecords(txn) != 0 && pq.getNumToReturn() != 1) { saveClientCursor = true; } } // TODO(greg): This will go away soon. if (!shardingState.getVersion(pq.ns()).isWriteCompatibleWith(shardingVersionAtStart)) { // if the version changed during the query we might be missing some data and its safe to // send this as mongos can resend at this point throw SendStaleConfigException(pq.ns(), "version changed during initial query", shardingVersionAtStart, shardingState.getVersion(pq.ns())); } const logger::LogComponent queryLogComponent = logger::LogComponent::kQuery; const logger::LogSeverity logLevelOne = logger::LogSeverity::Debug(1); PlanSummaryStats summaryStats; Explain::getSummaryStats(exec.get(), &summaryStats); curop.debug().ntoskip = pq.getSkip(); curop.debug().nreturned = numResults; curop.debug().scanAndOrder = summaryStats.hasSortStage; curop.debug().nscanned = summaryStats.totalKeysExamined; curop.debug().nscannedObjects = summaryStats.totalDocsExamined; curop.debug().idhack = summaryStats.isIdhack; // Set debug information for consumption by the profiler. if (dbProfilingLevel > 0 || curop.elapsedMillis() > serverGlobalParams.slowMS || logger::globalLogDomain()->shouldLog(queryLogComponent, logLevelOne)) { // Get BSON stats. scoped_ptr<PlanStageStats> execStats(exec->getStats()); BSONObjBuilder statsBob; Explain::statsToBSON(*execStats, &statsBob); curop.debug().execStats.set(statsBob.obj()); // Replace exec stats with plan summary if stats cannot fit into CachedBSONObj. if (curop.debug().execStats.tooBig() && !curop.debug().planSummary.empty()) { BSONObjBuilder bob; bob.append("summary", curop.debug().planSummary.toString()); curop.debug().execStats.set(bob.done()); } } long long ccId = 0; if (saveClientCursor) { // We won't use the executor until it's getMore'd. exec->saveState(); // Allocate a new ClientCursor. We don't have to worry about leaking it as it's // inserted into a global map by its ctor. ClientCursor* cc = new ClientCursor(collection, exec.get(), cq->getParsed().getOptions().toInt(), cq->getParsed().getFilter()); ccId = cc->cursorid(); if (fromDBDirectClient) { cc->setUnownedRecoveryUnit(txn->recoveryUnit()); } else if (state == PlanExecutor::IS_EOF && pq.getOptions().tailable) { // Don't stash the RU for tailable cursors at EOF, let them get a new RU on their // next getMore. } else { // We stash away the RecoveryUnit in the ClientCursor. It's used for subsequent // getMore requests. The calling OpCtx gets a fresh RecoveryUnit. cc->setOwnedRecoveryUnit(txn->releaseRecoveryUnit()); StorageEngine* storageEngine = getGlobalEnvironment()->getGlobalStorageEngine(); txn->setRecoveryUnit(storageEngine->newRecoveryUnit(txn)); } QLOG() << "caching executor with cursorid " << ccId << " after returning " << numResults << " results" << endl; // ClientCursor takes ownership of executor. Release to make sure it's not deleted. exec.release(); // TODO document if (pq.getOptions().oplogReplay && !slaveReadTill.isNull()) { cc->slaveReadTill(slaveReadTill); } // TODO document if (pq.getOptions().exhaust) { curop.debug().exhaust = true; } // Set attributes for getMore. cc->setCollMetadata(collMetadata); cc->setPos(numResults); // If the query had a time limit, remaining time is "rolled over" to the cursor (for // use by future getmore ops). cc->setLeftoverMaxTimeMicros(curop.getRemainingMaxTimeMicros()); } else { QLOG() << "Not caching executor but returning " << numResults << " results.\n"; } // Add the results from the query into the output buffer. result.appendData(bb.buf(), bb.len()); bb.decouple(); // Fill out the output buffer's header. QueryResult::View qr = result.header().view2ptr(); qr.setCursorId(ccId); curop.debug().cursorid = (0 == ccId ? -1 : ccId); qr.setResultFlagsToOk(); qr.msgdata().setOperation(opReply); qr.setStartingFrom(0); qr.setNReturned(numResults); // curop.debug().exhaust is set above. return curop.debug().exhaust ? pq.ns() : ""; }
/** * Called by db/instance.cpp. This is the getMore entry point. * * pass - when QueryOption_AwaitData is in use, the caller will make repeated calls * when this method returns an empty result, incrementing pass on each call. * Thus, pass == 0 indicates this is the first "attempt" before any 'awaiting'. */ QueryResult::View newGetMore(OperationContext* txn, const char* ns, int ntoreturn, long long cursorid, CurOp& curop, int pass, bool& exhaust, bool* isCursorAuthorized, bool fromDBDirectClient) { // For testing, we may want to fail if we receive a getmore. if (MONGO_FAIL_POINT(failReceivedGetmore)) { invariant(0); } exhaust = false; // This is a read lock. const NamespaceString nss(ns); scoped_ptr<AutoGetCollectionForRead> ctx(new AutoGetCollectionForRead(txn, nss)); Collection* collection = ctx->getCollection(); uassert( 17356, "collection dropped between getMore calls", collection ); QLOG() << "Running getMore, cursorid: " << cursorid << endl; // This checks to make sure the operation is allowed on a replicated node. Since we are not // passing in a query object (necessary to check SlaveOK query option), the only state where // reads are allowed is PRIMARY (or master in master/slave). This function uasserts if // reads are not okay. Status status = repl::getGlobalReplicationCoordinator()->checkCanServeReadsFor( txn, nss, true); uassertStatusOK(status); // A pin performs a CC lookup and if there is a CC, increments the CC's pin value so it // doesn't time out. Also informs ClientCursor that there is somebody actively holding the // CC, so don't delete it. ClientCursorPin ccPin(collection, cursorid); ClientCursor* cc = ccPin.c(); // If we're not being called from DBDirectClient we want to associate the RecoveryUnit // used to create the execution machinery inside the cursor with our OperationContext. // If we throw or otherwise exit this method in a disorderly fashion, we must ensure // that further calls to getMore won't fail, and that the provided OperationContext // has a valid RecoveryUnit. As such, we use RAII to accomplish this. // // This must be destroyed before the ClientCursor is destroyed. std::auto_ptr<ScopedRecoveryUnitSwapper> ruSwapper; // These are set in the QueryResult msg we return. int resultFlags = ResultFlag_AwaitCapable; int numResults = 0; int startingResult = 0; const int InitialBufSize = 512 + sizeof(QueryResult::Value) + MaxBytesToReturnToClientAtOnce; BufBuilder bb(InitialBufSize); bb.skip(sizeof(QueryResult::Value)); if (NULL == cc) { cursorid = 0; resultFlags = ResultFlag_CursorNotFound; } else { // Quote: check for spoofing of the ns such that it does not match the one originally // there for the cursor uassert(17011, "auth error", str::equals(ns, cc->ns().c_str())); *isCursorAuthorized = true; // Restore the RecoveryUnit if we need to. if (fromDBDirectClient) { if (cc->hasRecoveryUnit()) invariant(txn->recoveryUnit() == cc->getUnownedRecoveryUnit()); } else { if (!cc->hasRecoveryUnit()) { // Start using a new RecoveryUnit cc->setOwnedRecoveryUnit( getGlobalEnvironment()->getGlobalStorageEngine()->newRecoveryUnit(txn)); } // Swap RecoveryUnit(s) between the ClientCursor and OperationContext. ruSwapper.reset(new ScopedRecoveryUnitSwapper(cc, txn)); } // Reset timeout timer on the cursor since the cursor is still in use. cc->setIdleTime(0); // TODO: fail point? // If the operation that spawned this cursor had a time limit set, apply leftover // time to this getmore. curop.setMaxTimeMicros(cc->getLeftoverMaxTimeMicros()); txn->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. if (0 == pass) { cc->updateSlaveLocation(txn, curop); } if (cc->isAggCursor) { // Agg cursors handle their own locking internally. ctx.reset(); // unlocks } CollectionMetadataPtr collMetadata = cc->getCollMetadata(); // If we're replaying the oplog, we save the last time that we read. OpTime slaveReadTill; // What number result are we starting at? Used to fill out the reply. startingResult = cc->pos(); // What gives us results. PlanExecutor* exec = cc->getExecutor(); const int queryOptions = cc->queryOptions(); // Get results out of the executor. exec->restoreState(txn); BSONObj obj; PlanExecutor::ExecState state; while (PlanExecutor::ADVANCED == (state = exec->getNext(&obj, NULL))) { // Add result to output buffer. bb.appendBuf((void*)obj.objdata(), obj.objsize()); // Count the result. ++numResults; // Possibly note slave's position in the oplog. if (queryOptions & QueryOption_OplogReplay) { BSONElement e = obj["ts"]; if (Date == e.type() || Timestamp == e.type()) { slaveReadTill = e._opTime(); } } if ((ntoreturn && numResults >= ntoreturn) || bb.len() > MaxBytesToReturnToClientAtOnce) { break; } } // We save the client cursor when there might be more results, and hence we may receive // another getmore. If we receive a EOF or an error, or 'exec' is dead, then we know // that we will not be producing more results. We indicate that the cursor is closed by // sending a cursorId of 0 back to the client. // // On the other hand, if we retrieve all results necessary for this batch, then // 'saveClientCursor' is true and we send a valid cursorId back to the client. In // this case, there may or may not actually be more results (for example, the next call // to getNext(...) might just return EOF). bool saveClientCursor = false; if (PlanExecutor::DEAD == state || PlanExecutor::EXEC_ERROR == state) { // Propagate this error to caller. if (PlanExecutor::EXEC_ERROR == state) { scoped_ptr<PlanStageStats> stats(exec->getStats()); error() << "Plan executor error, stats: " << Explain::statsToBSON(*stats); uasserted(17406, "getMore executor error: " + WorkingSetCommon::toStatusString(obj)); } // If we're dead there's no way to get more results. saveClientCursor = false; // In the old system tailable capped cursors would be killed off at the // cursorid level. If a tailable capped cursor is nuked the cursorid // would vanish. // // In the new system they die and are cleaned up later (or time out). // So this is where we get to remove the cursorid. if (0 == numResults) { resultFlags = ResultFlag_CursorNotFound; } } else if (PlanExecutor::IS_EOF == state) { // EOF is also end of the line unless it's tailable. saveClientCursor = queryOptions & QueryOption_CursorTailable; } else { verify(PlanExecutor::ADVANCED == state); saveClientCursor = true; } if (!saveClientCursor) { ruSwapper.reset(); ccPin.deleteUnderlying(); // cc is now invalid, as is the executor cursorid = 0; cc = NULL; QLOG() << "getMore NOT saving client cursor, ended with state " << PlanExecutor::statestr(state) << endl; } else { // Continue caching the ClientCursor. cc->incPos(numResults); exec->saveState(); QLOG() << "getMore saving client cursor ended with state " << PlanExecutor::statestr(state) << endl; if (PlanExecutor::IS_EOF == state && (queryOptions & QueryOption_CursorTailable)) { if (!fromDBDirectClient) { // Don't stash the RU. Get a new one on the next getMore. ruSwapper.reset(); delete cc->releaseOwnedRecoveryUnit(); } if ((queryOptions & QueryOption_AwaitData) && (numResults == 0) && (pass < 1000)) { // Bubble up to the AwaitData handling code in receivedGetMore which will // try again. return NULL; } } // Possibly note slave's position in the oplog. if ((queryOptions & QueryOption_OplogReplay) && !slaveReadTill.isNull()) { cc->slaveReadTill(slaveReadTill); } exhaust = (queryOptions & QueryOption_Exhaust); // If the getmore had a time limit, remaining time is "rolled over" back to the // cursor (for use by future getmore ops). cc->setLeftoverMaxTimeMicros( curop.getRemainingMaxTimeMicros() ); } } QueryResult::View qr = bb.buf(); qr.msgdata().setLen(bb.len()); qr.msgdata().setOperation(opReply); qr.setResultFlags(resultFlags); qr.setCursorId(cursorid); qr.setStartingFrom(startingResult); qr.setNReturned(numResults); bb.decouple(); QLOG() << "getMore returned " << numResults << " results\n"; return qr; }
std::string runQuery(OperationContext* txn, QueryMessage& q, const NamespaceString& nss, CurOp& curop, Message &result) { // Validate the namespace. uassert(16256, str::stream() << "Invalid ns [" << nss.ns() << "]", nss.isValid()); invariant(!nss.isCommand()); // Set curop information. beginQueryOp(nss, q.query, q.ntoreturn, q.ntoskip, &curop); // Parse the qm into a CanonicalQuery. std::auto_ptr<CanonicalQuery> cq; { CanonicalQuery* cqRaw; Status canonStatus = CanonicalQuery::canonicalize(q, &cqRaw, WhereCallbackReal(txn, nss.db())); if (!canonStatus.isOK()) { uasserted(17287, str::stream() << "Can't canonicalize query: " << canonStatus.toString()); } cq.reset(cqRaw); } invariant(cq.get()); LOG(5) << "Running query:\n" << cq->toString(); LOG(2) << "Running query: " << cq->toStringShort(); // Parse, canonicalize, plan, transcribe, and get a plan executor. AutoGetCollectionForRead ctx(txn, nss); Collection* collection = ctx.getCollection(); const int dbProfilingLevel = ctx.getDb() ? ctx.getDb()->getProfilingLevel() : serverGlobalParams.defaultProfile; // We have a parsed query. Time to get the execution plan for it. std::unique_ptr<PlanExecutor> exec; { PlanExecutor* rawExec; Status execStatus = getExecutorFind(txn, collection, nss, cq.release(), PlanExecutor::YIELD_AUTO, &rawExec); uassertStatusOK(execStatus); exec.reset(rawExec); } const LiteParsedQuery& pq = exec->getCanonicalQuery()->getParsed(); // If it's actually an explain, do the explain and return rather than falling through // to the normal query execution loop. if (pq.isExplain()) { BufBuilder bb; bb.skip(sizeof(QueryResult::Value)); BSONObjBuilder explainBob; Explain::explainStages(exec.get(), ExplainCommon::EXEC_ALL_PLANS, &explainBob); // Add the resulting object to the return buffer. BSONObj explainObj = explainBob.obj(); bb.appendBuf((void*)explainObj.objdata(), explainObj.objsize()); // TODO: Does this get overwritten/do we really need to set this twice? curop.debug().query = q.query; // Set query result fields. QueryResult::View qr = bb.buf(); bb.decouple(); qr.setResultFlagsToOk(); qr.msgdata().setLen(bb.len()); curop.debug().responseLength = bb.len(); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); result.setData(qr.view2ptr(), true); return ""; } // We freak out later if this changes before we're done with the query. const ChunkVersion shardingVersionAtStart = shardingState.getVersion(nss.ns()); // Handle query option $maxTimeMS (not used with commands). curop.setMaxTimeMicros(static_cast<unsigned long long>(pq.getMaxTimeMS()) * 1000); txn->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. // uassert if we are not on a primary, and not a secondary with SlaveOk query parameter set. bool slaveOK = pq.isSlaveOk() || pq.hasReadPref(); Status serveReadsStatus = repl::getGlobalReplicationCoordinator()->checkCanServeReadsFor( txn, nss, slaveOK); uassertStatusOK(serveReadsStatus); // Run the query. // bb is used to hold query results // this buffer should contain either requested documents per query or // explain information, but not both BufBuilder bb(32768); bb.skip(sizeof(QueryResult::Value)); // How many results have we obtained from the executor? int numResults = 0; // If we're replaying the oplog, we save the last time that we read. Timestamp slaveReadTill; BSONObj obj; PlanExecutor::ExecState state; // uint64_t numMisplacedDocs = 0; // Get summary info about which plan the executor is using. curop.debug().planSummary = Explain::getPlanSummary(exec.get()); while (PlanExecutor::ADVANCED == (state = exec->getNext(&obj, NULL))) { // Add result to output buffer. bb.appendBuf((void*)obj.objdata(), obj.objsize()); // Count the result. ++numResults; // Possibly note slave's position in the oplog. if (pq.isOplogReplay()) { BSONElement e = obj["ts"]; if (Date == e.type() || bsonTimestamp == e.type()) { slaveReadTill = e.timestamp(); } } if (enoughForFirstBatch(pq, numResults, bb.len())) { LOG(5) << "Enough for first batch, wantMore=" << pq.wantMore() << " numToReturn=" << pq.getNumToReturn() << " numResults=" << numResults << endl; break; } } // If we cache the executor later, we want to deregister it as it receives notifications // anyway by virtue of being cached. // // If we don't cache the executor later, we are deleting it, so it must be deregistered. // // So, no matter what, deregister the executor. exec->deregisterExec(); // Caller expects exceptions thrown in certain cases. if (PlanExecutor::FAILURE == state) { scoped_ptr<PlanStageStats> stats(exec->getStats()); error() << "Plan executor error, stats: " << Explain::statsToBSON(*stats); uasserted(17144, "Executor error: " + WorkingSetCommon::toStatusString(obj)); } // TODO: Currently, chunk ranges are kept around until all ClientCursors created while the // chunk belonged on this node are gone. Separating chunk lifetime management from // ClientCursor should allow this check to go away. if (!shardingState.getVersion(nss.ns()).isWriteCompatibleWith(shardingVersionAtStart)) { // if the version changed during the query we might be missing some data and its safe to // send this as mongos can resend at this point throw SendStaleConfigException(nss.ns(), "version changed during initial query", shardingVersionAtStart, shardingState.getVersion(nss.ns())); } // Fill out curop based on query results. If we have a cursorid, we will fill out curop with // this cursorid later. long long ccId = 0; if (shouldSaveCursor(txn, collection, state, exec.get())) { // We won't use the executor until it's getMore'd. exec->saveState(); // Allocate a new ClientCursor. We don't have to worry about leaking it as it's // inserted into a global map by its ctor. ClientCursor* cc = new ClientCursor(collection->getCursorManager(), exec.release(), nss.ns(), pq.getOptions(), pq.getFilter()); ccId = cc->cursorid(); if (txn->getClient()->isInDirectClient()) { cc->setUnownedRecoveryUnit(txn->recoveryUnit()); } else if (state == PlanExecutor::IS_EOF && pq.isTailable()) { // Don't stash the RU for tailable cursors at EOF, let them get a new RU on their // next getMore. } else { // We stash away the RecoveryUnit in the ClientCursor. It's used for subsequent // getMore requests. The calling OpCtx gets a fresh RecoveryUnit. txn->recoveryUnit()->abandonSnapshot(); cc->setOwnedRecoveryUnit(txn->releaseRecoveryUnit()); StorageEngine* storageEngine = getGlobalServiceContext()->getGlobalStorageEngine(); invariant(txn->setRecoveryUnit(storageEngine->newRecoveryUnit(), OperationContext::kNotInUnitOfWork) == OperationContext::kNotInUnitOfWork); } LOG(5) << "caching executor with cursorid " << ccId << " after returning " << numResults << " results" << endl; // TODO document if (pq.isOplogReplay() && !slaveReadTill.isNull()) { cc->slaveReadTill(slaveReadTill); } // TODO document if (pq.isExhaust()) { curop.debug().exhaust = true; } cc->setPos(numResults); // If the query had a time limit, remaining time is "rolled over" to the cursor (for // use by future getmore ops). cc->setLeftoverMaxTimeMicros(curop.getRemainingMaxTimeMicros()); endQueryOp(cc->getExecutor(), dbProfilingLevel, numResults, ccId, &curop); } else { LOG(5) << "Not caching executor but returning " << numResults << " results.\n"; endQueryOp(exec.get(), dbProfilingLevel, numResults, ccId, &curop); } // Add the results from the query into the output buffer. result.appendData(bb.buf(), bb.len()); bb.decouple(); // Fill out the output buffer's header. QueryResult::View qr = result.header().view2ptr(); qr.setCursorId(ccId); qr.setResultFlagsToOk(); qr.msgdata().setOperation(opReply); qr.setStartingFrom(0); qr.setNReturned(numResults); // curop.debug().exhaust is set above. return curop.debug().exhaust ? nss.ns() : ""; }
/** * Called by db/instance.cpp. This is the getMore entry point. * * pass - when QueryOption_AwaitData is in use, the caller will make repeated calls * when this method returns an empty result, incrementing pass on each call. * Thus, pass == 0 indicates this is the first "attempt" before any 'awaiting'. */ QueryResult::View getMore(OperationContext* txn, const char* ns, int ntoreturn, long long cursorid, CurOp& curop, int pass, bool& exhaust, bool* isCursorAuthorized) { // For testing, we may want to fail if we receive a getmore. if (MONGO_FAIL_POINT(failReceivedGetmore)) { invariant(0); } exhaust = false; const NamespaceString nss(ns); // Depending on the type of cursor being operated on, we hold locks for the whole getMore, // or none of the getMore, or part of the getMore. The three cases in detail: // // 1) Normal cursor: we lock with "ctx" and hold it for the whole getMore. // 2) Cursor owned by global cursor manager: we don't lock anything. These cursors don't // own any collection state. // 3) Agg cursor: we lock with "ctx", then release, then relock with "unpinDBLock" and // "unpinCollLock". This is because agg cursors handle locking internally (hence the // release), but the pin and unpin of the cursor must occur under the collection lock. // We don't use our AutoGetCollectionForRead "ctx" to relock, because // AutoGetCollectionForRead checks the sharding version (and we want the relock for the // unpin to succeed even if the sharding version has changed). // // Note that we declare our locks before our ClientCursorPin, in order to ensure that the // pin's destructor is called before the lock destructors (so that the unpin occurs under // the lock). boost::scoped_ptr<AutoGetCollectionForRead> ctx; boost::scoped_ptr<Lock::DBLock> unpinDBLock; boost::scoped_ptr<Lock::CollectionLock> unpinCollLock; CursorManager* cursorManager; CursorManager* globalCursorManager = CursorManager::getGlobalCursorManager(); if (globalCursorManager->ownsCursorId(cursorid)) { cursorManager = globalCursorManager; } else { ctx.reset(new AutoGetCollectionForRead(txn, nss)); Collection* collection = ctx->getCollection(); uassert( 17356, "collection dropped between getMore calls", collection ); cursorManager = collection->getCursorManager(); } LOG(5) << "Running getMore, cursorid: " << cursorid << endl; // This checks to make sure the operation is allowed on a replicated node. Since we are not // passing in a query object (necessary to check SlaveOK query option), the only state where // reads are allowed is PRIMARY (or master in master/slave). This function uasserts if // reads are not okay. Status status = repl::getGlobalReplicationCoordinator()->checkCanServeReadsFor( txn, nss, true); uassertStatusOK(status); // A pin performs a CC lookup and if there is a CC, increments the CC's pin value so it // doesn't time out. Also informs ClientCursor that there is somebody actively holding the // CC, so don't delete it. ClientCursorPin ccPin(cursorManager, cursorid); ClientCursor* cc = ccPin.c(); // If we're not being called from DBDirectClient we want to associate the RecoveryUnit // used to create the execution machinery inside the cursor with our OperationContext. // If we throw or otherwise exit this method in a disorderly fashion, we must ensure // that further calls to getMore won't fail, and that the provided OperationContext // has a valid RecoveryUnit. As such, we use RAII to accomplish this. // // This must be destroyed before the ClientCursor is destroyed. std::auto_ptr<ScopedRecoveryUnitSwapper> ruSwapper; // These are set in the QueryResult msg we return. int resultFlags = ResultFlag_AwaitCapable; int numResults = 0; int startingResult = 0; const int InitialBufSize = 512 + sizeof(QueryResult::Value) + MaxBytesToReturnToClientAtOnce; BufBuilder bb(InitialBufSize); bb.skip(sizeof(QueryResult::Value)); if (NULL == cc) { cursorid = 0; resultFlags = ResultFlag_CursorNotFound; } else { // Check for spoofing of the ns such that it does not match the one originally // there for the cursor. uassert(ErrorCodes::Unauthorized, str::stream() << "Requested getMore on namespace " << ns << ", but cursor " << cursorid << " belongs to namespace " << cc->ns(), ns == cc->ns()); *isCursorAuthorized = true; // Restore the RecoveryUnit if we need to. if (txn->getClient()->isInDirectClient()) { if (cc->hasRecoveryUnit()) invariant(txn->recoveryUnit() == cc->getUnownedRecoveryUnit()); } else { if (!cc->hasRecoveryUnit()) { // Start using a new RecoveryUnit cc->setOwnedRecoveryUnit( getGlobalServiceContext()->getGlobalStorageEngine()->newRecoveryUnit()); } // Swap RecoveryUnit(s) between the ClientCursor and OperationContext. ruSwapper.reset(new ScopedRecoveryUnitSwapper(cc, txn)); } // Reset timeout timer on the cursor since the cursor is still in use. cc->setIdleTime(0); // If the operation that spawned this cursor had a time limit set, apply leftover // time to this getmore. curop.setMaxTimeMicros(cc->getLeftoverMaxTimeMicros()); txn->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. if (0 == pass) { cc->updateSlaveLocation(txn); } if (cc->isAggCursor()) { // Agg cursors handle their own locking internally. ctx.reset(); // unlocks } // If we're replaying the oplog, we save the last time that we read. Timestamp slaveReadTill; // What number result are we starting at? Used to fill out the reply. startingResult = cc->pos(); // What gives us results. PlanExecutor* exec = cc->getExecutor(); const int queryOptions = cc->queryOptions(); // Get results out of the executor. exec->restoreState(txn); BSONObj obj; PlanExecutor::ExecState state; while (PlanExecutor::ADVANCED == (state = exec->getNext(&obj, NULL))) { // Add result to output buffer. bb.appendBuf((void*)obj.objdata(), obj.objsize()); // Count the result. ++numResults; // Possibly note slave's position in the oplog. if (queryOptions & QueryOption_OplogReplay) { BSONElement e = obj["ts"]; if (Date == e.type() || bsonTimestamp == e.type()) { slaveReadTill = e.timestamp(); } } if (enoughForGetMore(ntoreturn, numResults, bb.len())) { break; } } if (PlanExecutor::DEAD == state || PlanExecutor::FAILURE == state) { // Propagate this error to caller. if (PlanExecutor::FAILURE == state) { scoped_ptr<PlanStageStats> stats(exec->getStats()); error() << "Plan executor error, stats: " << Explain::statsToBSON(*stats); uasserted(17406, "getMore executor error: " + WorkingSetCommon::toStatusString(obj)); } // In the old system tailable capped cursors would be killed off at the // cursorid level. If a tailable capped cursor is nuked the cursorid // would vanish. // // In the new system they die and are cleaned up later (or time out). // So this is where we get to remove the cursorid. if (0 == numResults) { resultFlags = ResultFlag_CursorNotFound; } } const bool shouldSaveCursor = shouldSaveCursorGetMore(state, exec, isCursorTailable(cc)); // In order to deregister a cursor, we need to be holding the DB + collection lock and // if the cursor is aggregation, we release these locks. if (cc->isAggCursor()) { invariant(NULL == ctx.get()); unpinDBLock.reset(new Lock::DBLock(txn->lockState(), nss.db(), MODE_IS)); unpinCollLock.reset(new Lock::CollectionLock(txn->lockState(), nss.ns(), MODE_IS)); } // Our two possible ClientCursorPin cleanup paths are: // 1) If the cursor is not going to be saved, we call deleteUnderlying() on the pin. // 2) If the cursor is going to be saved, we simply let the pin go out of scope. In // this case, the pin's destructor will be invoked, which will call release() on the // pin. Because our ClientCursorPin is declared after our lock is declared, this // will happen under the lock. if (!shouldSaveCursor) { ruSwapper.reset(); ccPin.deleteUnderlying(); // cc is now invalid, as is the executor cursorid = 0; cc = NULL; curop.debug().cursorExhausted = true; LOG(5) << "getMore NOT saving client cursor, ended with state " << PlanExecutor::statestr(state) << endl; } else { // Continue caching the ClientCursor. cc->incPos(numResults); exec->saveState(); LOG(5) << "getMore saving client cursor ended with state " << PlanExecutor::statestr(state) << endl; if (PlanExecutor::IS_EOF == state && (queryOptions & QueryOption_CursorTailable)) { if (!txn->getClient()->isInDirectClient()) { // Don't stash the RU. Get a new one on the next getMore. ruSwapper->dismiss(); } if ((queryOptions & QueryOption_AwaitData) && (numResults == 0) && (pass < 1000)) { // Bubble up to the AwaitData handling code in receivedGetMore which will // try again. return NULL; } } // Possibly note slave's position in the oplog. if ((queryOptions & QueryOption_OplogReplay) && !slaveReadTill.isNull()) { cc->slaveReadTill(slaveReadTill); } exhaust = (queryOptions & QueryOption_Exhaust); // If the getmore had a time limit, remaining time is "rolled over" back to the // cursor (for use by future getmore ops). cc->setLeftoverMaxTimeMicros( curop.getRemainingMaxTimeMicros() ); } } QueryResult::View qr = bb.buf(); qr.msgdata().setLen(bb.len()); qr.msgdata().setOperation(opReply); qr.setResultFlags(resultFlags); qr.setCursorId(cursorid); qr.setStartingFrom(startingResult); qr.setNReturned(numResults); bb.decouple(); LOG(5) << "getMore returned " << numResults << " results\n"; return qr; }
/** * Called by db/instance.cpp. This is the getMore entry point. */ QueryResult::View getMore(OperationContext* txn, const char* ns, int ntoreturn, long long cursorid, bool* exhaust, bool* isCursorAuthorized) { invariant(ntoreturn >= 0); CurOp& curop = *CurOp::get(txn); // For testing, we may want to fail if we receive a getmore. if (MONGO_FAIL_POINT(failReceivedGetmore)) { invariant(0); } *exhaust = false; const NamespaceString nss(ns); // Depending on the type of cursor being operated on, we hold locks for the whole getMore, // or none of the getMore, or part of the getMore. The three cases in detail: // // 1) Normal cursor: we lock with "ctx" and hold it for the whole getMore. // 2) Cursor owned by global cursor manager: we don't lock anything. These cursors don't own // any collection state. These cursors are generated either by the listCollections or // listIndexes commands, as these special cursor-generating commands operate over catalog // data rather than targeting the data within a collection. // 3) Agg cursor: we lock with "ctx", then release, then relock with "unpinDBLock" and // "unpinCollLock". This is because agg cursors handle locking internally (hence the // release), but the pin and unpin of the cursor must occur under the collection lock. // We don't use our AutoGetCollectionForRead "ctx" to relock, because // AutoGetCollectionForRead checks the sharding version (and we want the relock for the // unpin to succeed even if the sharding version has changed). // // Note that we declare our locks before our ClientCursorPin, in order to ensure that the // pin's destructor is called before the lock destructors (so that the unpin occurs under // the lock). unique_ptr<AutoGetCollectionForRead> ctx; unique_ptr<Lock::DBLock> unpinDBLock; unique_ptr<Lock::CollectionLock> unpinCollLock; CursorManager* cursorManager; if (nss.isListIndexesCursorNS() || nss.isListCollectionsCursorNS()) { // List collections and list indexes are special cursor-generating commands whose // cursors are managed globally, as they operate over catalog data rather than targeting // the data within a collection. cursorManager = CursorManager::getGlobalCursorManager(); } else { ctx = stdx::make_unique<AutoGetCollectionForRead>(txn, nss); Collection* collection = ctx->getCollection(); uassert(17356, "collection dropped between getMore calls", collection); cursorManager = collection->getCursorManager(); } LOG(5) << "Running getMore, cursorid: " << cursorid << endl; // This checks to make sure the operation is allowed on a replicated node. Since we are not // passing in a query object (necessary to check SlaveOK query option), the only state where // reads are allowed is PRIMARY (or master in master/slave). This function uasserts if // reads are not okay. Status status = repl::getGlobalReplicationCoordinator()->checkCanServeReadsFor(txn, nss, true); uassertStatusOK(status); // A pin performs a CC lookup and if there is a CC, increments the CC's pin value so it // doesn't time out. Also informs ClientCursor that there is somebody actively holding the // CC, so don't delete it. ClientCursorPin ccPin(cursorManager, cursorid); ClientCursor* cc = ccPin.c(); // These are set in the QueryResult msg we return. int resultFlags = ResultFlag_AwaitCapable; int numResults = 0; int startingResult = 0; const int InitialBufSize = 512 + sizeof(QueryResult::Value) + FindCommon::kMaxBytesToReturnToClientAtOnce; BufBuilder bb(InitialBufSize); bb.skip(sizeof(QueryResult::Value)); if (NULL == cc) { cursorid = 0; resultFlags = ResultFlag_CursorNotFound; } else { // Check for spoofing of the ns such that it does not match the one originally // there for the cursor. uassert(ErrorCodes::Unauthorized, str::stream() << "Requested getMore on namespace " << ns << ", but cursor " << cursorid << " belongs to namespace " << cc->ns(), ns == cc->ns()); *isCursorAuthorized = true; if (cc->isReadCommitted()) uassertStatusOK(txn->recoveryUnit()->setReadFromMajorityCommittedSnapshot()); // Reset timeout timer on the cursor since the cursor is still in use. cc->setIdleTime(0); // If the operation that spawned this cursor had a time limit set, apply leftover // time to this getmore. curop.setMaxTimeMicros(cc->getLeftoverMaxTimeMicros()); txn->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. // Ensure that the original query or command object is available in the slow query log, // profiler, and currentOp. curop.debug().query = cc->getQuery(); { stdx::lock_guard<Client> lk(*txn->getClient()); curop.setQuery_inlock(cc->getQuery()); } cc->updateSlaveLocation(txn); if (cc->isAggCursor()) { // Agg cursors handle their own locking internally. ctx.reset(); // unlocks } // If we're replaying the oplog, we save the last time that we read. Timestamp slaveReadTill; // What number result are we starting at? Used to fill out the reply. startingResult = cc->pos(); uint64_t notifierVersion = 0; std::shared_ptr<CappedInsertNotifier> notifier; if (isCursorAwaitData(cc)) { invariant(ctx->getCollection()->isCapped()); // Retrieve the notifier which we will wait on until new data arrives. We make sure // to do this in the lock because once we drop the lock it is possible for the // collection to become invalid. The notifier itself will outlive the collection if // the collection is dropped, as we keep a shared_ptr to it. notifier = ctx->getCollection()->getCappedInsertNotifier(); // Must get the version before we call generateBatch in case a write comes in after // that call and before we call wait on the notifier. notifierVersion = notifier->getVersion(); } PlanExecutor* exec = cc->getExecutor(); exec->reattachToOperationContext(txn); exec->restoreState(); PlanExecutor::ExecState state; generateBatch(ntoreturn, cc, &bb, &numResults, &slaveReadTill, &state); // If this is an await data cursor, and we hit EOF without generating any results, then // we block waiting for new data to arrive. if (isCursorAwaitData(cc) && state == PlanExecutor::IS_EOF && numResults == 0) { // Save the PlanExecutor and drop our locks. exec->saveState(); ctx.reset(); // Block waiting for data for up to 1 second. Seconds timeout(1); notifier->wait(notifierVersion, timeout); notifier.reset(); // Set expected latency to match wait time. This makes sure the logs aren't spammed // by awaitData queries that exceed slowms due to blocking on the CappedInsertNotifier. curop.setExpectedLatencyMs(durationCount<Milliseconds>(timeout)); // Reacquiring locks. ctx = make_unique<AutoGetCollectionForRead>(txn, nss); exec->restoreState(); // We woke up because either the timed_wait expired, or there was more data. Either // way, attempt to generate another batch of results. generateBatch(ntoreturn, cc, &bb, &numResults, &slaveReadTill, &state); } // We have to do this before re-acquiring locks in the agg case because // shouldSaveCursorGetMore() can make a network call for agg cursors. // // TODO: Getting rid of PlanExecutor::isEOF() in favor of PlanExecutor::IS_EOF would mean // that this network operation is no longer necessary. const bool shouldSaveCursor = shouldSaveCursorGetMore(state, exec, isCursorTailable(cc)); // In order to deregister a cursor, we need to be holding the DB + collection lock and // if the cursor is aggregation, we release these locks. if (cc->isAggCursor()) { invariant(NULL == ctx.get()); unpinDBLock = make_unique<Lock::DBLock>(txn->lockState(), nss.db(), MODE_IS); unpinCollLock = make_unique<Lock::CollectionLock>(txn->lockState(), nss.ns(), MODE_IS); } // Our two possible ClientCursorPin cleanup paths are: // 1) If the cursor is not going to be saved, we call deleteUnderlying() on the pin. // 2) If the cursor is going to be saved, we simply let the pin go out of scope. In // this case, the pin's destructor will be invoked, which will call release() on the // pin. Because our ClientCursorPin is declared after our lock is declared, this // will happen under the lock. if (!shouldSaveCursor) { ccPin.deleteUnderlying(); // cc is now invalid, as is the executor cursorid = 0; cc = NULL; curop.debug().cursorExhausted = true; LOG(5) << "getMore NOT saving client cursor, ended with state " << PlanExecutor::statestr(state) << endl; } else { // Continue caching the ClientCursor. cc->incPos(numResults); exec->saveState(); exec->detachFromOperationContext(); LOG(5) << "getMore saving client cursor ended with state " << PlanExecutor::statestr(state) << endl; // Possibly note slave's position in the oplog. if ((cc->queryOptions() & QueryOption_OplogReplay) && !slaveReadTill.isNull()) { cc->slaveReadTill(slaveReadTill); } *exhaust = cc->queryOptions() & QueryOption_Exhaust; // If the getmore had a time limit, remaining time is "rolled over" back to the // cursor (for use by future getmore ops). cc->setLeftoverMaxTimeMicros(curop.getRemainingMaxTimeMicros()); } } QueryResult::View qr = bb.buf(); qr.msgdata().setLen(bb.len()); qr.msgdata().setOperation(opReply); qr.setResultFlags(resultFlags); qr.setCursorId(cursorid); qr.setStartingFrom(startingResult); qr.setNReturned(numResults); bb.decouple(); LOG(5) << "getMore returned " << numResults << " results\n"; return qr; }
/** * Called by db/instance.cpp. This is the getMore entry point. */ Message getMore(OperationContext* opCtx, const char* ns, int ntoreturn, long long cursorid, bool* exhaust, bool* isCursorAuthorized) { invariant(ntoreturn >= 0); CurOp& curOp = *CurOp::get(opCtx); curOp.ensureStarted(); // For testing, we may want to fail if we receive a getmore. if (MONGO_FAIL_POINT(failReceivedGetmore)) { MONGO_UNREACHABLE; } *exhaust = false; const NamespaceString nss(ns); // Cursors come in one of two flavors: // - Cursors owned by the collection cursor manager, such as those generated via the find // command. For these cursors, we hold the appropriate collection lock for the duration of the // getMore using AutoGetCollectionForRead. // - Cursors owned by the global cursor manager, such as those generated via the aggregate // command. These cursors either hold no collection state or manage their collection state // internally, so we acquire no locks. // // While we only need to acquire locks in the case of a cursor which is *not* globally owned, we // need to create an AutoStatsTracker in either case. This is responsible for updating // statistics in CurOp and Top. We avoid using AutoGetCollectionForReadCommand because we may // need to drop and reacquire locks when the cursor is awaitData, but we don't want to update // the stats twice. // // Note that we acquire our locks before our ClientCursorPin, in order to ensure that the pin's // destructor is called before the lock's destructor (if there is one) so that the cursor // cleanup can occur under the lock. UninterruptibleLockGuard noInterrupt(opCtx->lockState()); boost::optional<AutoGetCollectionForRead> readLock; boost::optional<AutoStatsTracker> statsTracker; CursorManager* cursorManager; if (CursorManager::isGloballyManagedCursor(cursorid)) { cursorManager = CursorManager::getGlobalCursorManager(); if (boost::optional<NamespaceString> nssForCurOp = nss.isGloballyManagedNamespace() ? nss.getTargetNSForGloballyManagedNamespace() : nss) { AutoGetDb autoDb(opCtx, nssForCurOp->db(), MODE_IS); const auto profilingLevel = autoDb.getDb() ? boost::optional<int>{autoDb.getDb()->getProfilingLevel()} : boost::none; statsTracker.emplace(opCtx, *nssForCurOp, Top::LockType::NotLocked, profilingLevel); auto view = autoDb.getDb() ? autoDb.getDb()->getViewCatalog()->lookup(opCtx, nssForCurOp->ns()) : nullptr; uassert( ErrorCodes::CommandNotSupportedOnView, str::stream() << "Namespace " << nssForCurOp->ns() << " is a view. OP_GET_MORE operations are not supported on views. " << "Only clients which support the getMore command can be used to " "query views.", !view); } } else { readLock.emplace(opCtx, nss); const int doNotChangeProfilingLevel = 0; statsTracker.emplace(opCtx, nss, Top::LockType::ReadLocked, readLock->getDb() ? readLock->getDb()->getProfilingLevel() : doNotChangeProfilingLevel); Collection* collection = readLock->getCollection(); uassert( ErrorCodes::OperationFailed, "collection dropped between getMore calls", collection); cursorManager = collection->getCursorManager(); // This checks to make sure the operation is allowed on a replicated node. Since we are not // passing in a query object (necessary to check SlaveOK query option), we allow reads // whether we are PRIMARY or SECONDARY. uassertStatusOK( repl::ReplicationCoordinator::get(opCtx)->checkCanServeReadsFor(opCtx, nss, true)); } LOG(5) << "Running getMore, cursorid: " << cursorid; // A pin performs a CC lookup and if there is a CC, increments the CC's pin value so it // doesn't time out. Also informs ClientCursor that there is somebody actively holding the // CC, so don't delete it. auto ccPin = cursorManager->pinCursor(opCtx, cursorid); // These are set in the QueryResult msg we return. int resultFlags = ResultFlag_AwaitCapable; int numResults = 0; int startingResult = 0; const int InitialBufSize = 512 + sizeof(QueryResult::Value) + FindCommon::kMaxBytesToReturnToClientAtOnce; BufBuilder bb(InitialBufSize); bb.skip(sizeof(QueryResult::Value)); if (!ccPin.isOK()) { if (ccPin == ErrorCodes::CursorNotFound) { cursorid = 0; resultFlags = ResultFlag_CursorNotFound; } else { uassertStatusOK(ccPin.getStatus()); } } else { ClientCursor* cc = ccPin.getValue().getCursor(); // Check for spoofing of the ns such that it does not match the one originally // there for the cursor. uassert(ErrorCodes::Unauthorized, str::stream() << "Requested getMore on namespace " << ns << ", but cursor " << cursorid << " belongs to namespace " << cc->nss().ns(), nss == cc->nss()); // A user can only call getMore on their own cursor. If there were multiple users // authenticated when the cursor was created, then at least one of them must be // authenticated in order to run getMore on the cursor. uassert(ErrorCodes::Unauthorized, str::stream() << "cursor id " << cursorid << " was not created by the authenticated user", AuthorizationSession::get(opCtx->getClient()) ->isCoauthorizedWith(cc->getAuthenticatedUsers())); *isCursorAuthorized = true; const auto replicationMode = repl::ReplicationCoordinator::get(opCtx)->getReplicationMode(); opCtx->recoveryUnit()->setReadConcernLevelAndReplicationMode(cc->getReadConcernLevel(), replicationMode); // TODO SERVER-33698: Remove kSnapshotReadConcern clause once we can guarantee that a // readConcern level snapshot getMore will have an established point-in-time WiredTiger // snapshot. if (replicationMode == repl::ReplicationCoordinator::modeReplSet && (cc->getReadConcernLevel() == repl::ReadConcernLevel::kMajorityReadConcern || cc->getReadConcernLevel() == repl::ReadConcernLevel::kSnapshotReadConcern)) { uassertStatusOK(opCtx->recoveryUnit()->obtainMajorityCommittedSnapshot()); } uassert(40548, "OP_GET_MORE operations are not supported on tailable aggregations. Only clients " "which support the getMore command can be used on tailable aggregations.", readLock || !cc->isAwaitData()); // If the operation that spawned this cursor had a time limit set, apply leftover // time to this getmore. if (cc->getLeftoverMaxTimeMicros() < Microseconds::max()) { uassert(40136, "Illegal attempt to set operation deadline within DBDirectClient", !opCtx->getClient()->isInDirectClient()); opCtx->setDeadlineAfterNowBy(cc->getLeftoverMaxTimeMicros()); } opCtx->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. // What number result are we starting at? Used to fill out the reply. startingResult = cc->pos(); uint64_t notifierVersion = 0; std::shared_ptr<CappedInsertNotifier> notifier; if (cc->isAwaitData()) { invariant(readLock->getCollection()->isCapped()); // Retrieve the notifier which we will wait on until new data arrives. We make sure // to do this in the lock because once we drop the lock it is possible for the // collection to become invalid. The notifier itself will outlive the collection if // the collection is dropped, as we keep a shared_ptr to it. notifier = readLock->getCollection()->getCappedInsertNotifier(); // Must get the version before we call generateBatch in case a write comes in after // that call and before we call wait on the notifier. notifierVersion = notifier->getVersion(); } PlanExecutor* exec = cc->getExecutor(); exec->reattachToOperationContext(opCtx); uassertStatusOK(exec->restoreState()); auto planSummary = Explain::getPlanSummary(exec); { stdx::lock_guard<Client> lk(*opCtx->getClient()); curOp.setPlanSummary_inlock(planSummary); // Ensure that the original query object is available in the slow query log, profiler // and currentOp. Upconvert _query to resemble a getMore command, and set the original // command or upconverted legacy query in the originatingCommand field. curOp.setOpDescription_inlock(upconvertGetMoreEntry(nss, cursorid, ntoreturn)); curOp.setOriginatingCommand_inlock(cc->getOriginatingCommandObj()); } PlanExecutor::ExecState state; // We report keysExamined and docsExamined to OpDebug for a given getMore operation. To // obtain these values we need to take a diff of the pre-execution and post-execution // metrics, as they accumulate over the course of a cursor's lifetime. PlanSummaryStats preExecutionStats; Explain::getSummaryStats(*exec, &preExecutionStats); generateBatch(ntoreturn, cc, &bb, &numResults, &state); // If this is an await data cursor, and we hit EOF without generating any results, then // we block waiting for new data to arrive. if (cc->isAwaitData() && state == PlanExecutor::IS_EOF && numResults == 0) { // Save the PlanExecutor and drop our locks. exec->saveState(); readLock.reset(); // Block waiting for data for up to 1 second. Time spent blocking is not counted towards // the total operation latency. curOp.pauseTimer(); Seconds timeout(1); notifier->waitUntil(notifierVersion, opCtx->getServiceContext()->getPreciseClockSource()->now() + timeout); notifier.reset(); curOp.resumeTimer(); // Reacquiring locks. readLock.emplace(opCtx, nss); uassertStatusOK(exec->restoreState()); // We woke up because either the timed_wait expired, or there was more data. Either // way, attempt to generate another batch of results. generateBatch(ntoreturn, cc, &bb, &numResults, &state); } PlanSummaryStats postExecutionStats; Explain::getSummaryStats(*exec, &postExecutionStats); postExecutionStats.totalKeysExamined -= preExecutionStats.totalKeysExamined; postExecutionStats.totalDocsExamined -= preExecutionStats.totalDocsExamined; curOp.debug().setPlanSummaryMetrics(postExecutionStats); // We do not report 'execStats' for aggregation or other globally managed cursors, both in // the original request and subsequent getMore. It would be useful to have this information // for an aggregation, but the source PlanExecutor could be destroyed before we know whether // we need execStats and we do not want to generate for all operations due to cost. if (!CursorManager::isGloballyManagedCursor(cursorid) && curOp.shouldDBProfile()) { BSONObjBuilder execStatsBob; Explain::getWinningPlanStats(exec, &execStatsBob); curOp.debug().execStats = execStatsBob.obj(); } // Our two possible ClientCursorPin cleanup paths are: // 1) If the cursor is not going to be saved, we call deleteUnderlying() on the pin. // 2) If the cursor is going to be saved, we simply let the pin go out of scope. In this // case, the pin's destructor will be invoked, which will call release() on the pin. // Because our ClientCursorPin is declared after our lock is declared, this will happen // under the lock if any locking was necessary. if (!shouldSaveCursorGetMore(state, exec, cc->isTailable())) { ccPin.getValue().deleteUnderlying(); // cc is now invalid, as is the executor cursorid = 0; cc = nullptr; curOp.debug().cursorExhausted = true; LOG(5) << "getMore NOT saving client cursor, ended with state " << PlanExecutor::statestr(state); } else { // Continue caching the ClientCursor. cc->incPos(numResults); exec->saveState(); exec->detachFromOperationContext(); LOG(5) << "getMore saving client cursor ended with state " << PlanExecutor::statestr(state); *exhaust = cc->queryOptions() & QueryOption_Exhaust; // We assume that cursors created through a DBDirectClient are always used from their // original OperationContext, so we do not need to move time to and from the cursor. if (!opCtx->getClient()->isInDirectClient()) { // If the getmore had a time limit, remaining time is "rolled over" back to the // cursor (for use by future getmore ops). cc->setLeftoverMaxTimeMicros(opCtx->getRemainingMaxTimeMicros()); } } } QueryResult::View qr = bb.buf(); qr.msgdata().setLen(bb.len()); qr.msgdata().setOperation(opReply); qr.setResultFlags(resultFlags); qr.setCursorId(cursorid); qr.setStartingFrom(startingResult); qr.setNReturned(numResults); LOG(5) << "getMore returned " << numResults << " results\n"; return Message(bb.release()); }
std::string runQuery(OperationContext* txn, QueryMessage& q, const NamespaceString& nss, Message& result) { CurOp& curop = *CurOp::get(txn); uassert(ErrorCodes::InvalidNamespace, str::stream() << "Invalid ns [" << nss.ns() << "]", nss.isValid()); invariant(!nss.isCommand()); // Set curop information. beginQueryOp(txn, nss, q.query, q.ntoreturn, q.ntoskip); // Parse the qm into a CanonicalQuery. auto statusWithCQ = CanonicalQuery::canonicalize(q, ExtensionsCallbackReal(txn, &nss)); if (!statusWithCQ.isOK()) { uasserted( 17287, str::stream() << "Can't canonicalize query: " << statusWithCQ.getStatus().toString()); } unique_ptr<CanonicalQuery> cq = std::move(statusWithCQ.getValue()); invariant(cq.get()); LOG(5) << "Running query:\n" << cq->toString(); LOG(2) << "Running query: " << cq->toStringShort(); // Parse, canonicalize, plan, transcribe, and get a plan executor. AutoGetCollectionForRead ctx(txn, nss); Collection* collection = ctx.getCollection(); const int dbProfilingLevel = ctx.getDb() ? ctx.getDb()->getProfilingLevel() : serverGlobalParams.defaultProfile; // We have a parsed query. Time to get the execution plan for it. std::unique_ptr<PlanExecutor> exec = uassertStatusOK( getExecutorFind(txn, collection, nss, std::move(cq), PlanExecutor::YIELD_AUTO)); const LiteParsedQuery& pq = exec->getCanonicalQuery()->getParsed(); // If it's actually an explain, do the explain and return rather than falling through // to the normal query execution loop. if (pq.isExplain()) { BufBuilder bb; bb.skip(sizeof(QueryResult::Value)); BSONObjBuilder explainBob; Explain::explainStages(exec.get(), ExplainCommon::EXEC_ALL_PLANS, &explainBob); // Add the resulting object to the return buffer. BSONObj explainObj = explainBob.obj(); bb.appendBuf((void*)explainObj.objdata(), explainObj.objsize()); // TODO: Does this get overwritten/do we really need to set this twice? curop.debug().query = q.query; // Set query result fields. QueryResult::View qr = bb.buf(); bb.decouple(); qr.setResultFlagsToOk(); qr.msgdata().setLen(bb.len()); curop.debug().responseLength = bb.len(); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); result.setData(qr.view2ptr(), true); return ""; } // Handle query option $maxTimeMS (not used with commands). curop.setMaxTimeMicros(static_cast<unsigned long long>(pq.getMaxTimeMS()) * 1000); txn->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. // uassert if we are not on a primary, and not a secondary with SlaveOk query parameter set. bool slaveOK = pq.isSlaveOk() || pq.hasReadPref(); Status serveReadsStatus = repl::getGlobalReplicationCoordinator()->checkCanServeReadsFor(txn, nss, slaveOK); uassertStatusOK(serveReadsStatus); // Run the query. // bb is used to hold query results // this buffer should contain either requested documents per query or // explain information, but not both BufBuilder bb(FindCommon::kInitReplyBufferSize); bb.skip(sizeof(QueryResult::Value)); // How many results have we obtained from the executor? int numResults = 0; // If we're replaying the oplog, we save the last time that we read. Timestamp slaveReadTill; BSONObj obj; PlanExecutor::ExecState state; // Get summary info about which plan the executor is using. { stdx::lock_guard<Client> lk(*txn->getClient()); curop.setPlanSummary_inlock(Explain::getPlanSummary(exec.get())); } while (PlanExecutor::ADVANCED == (state = exec->getNext(&obj, NULL))) { // If we can't fit this result inside the current batch, then we stash it for later. if (!FindCommon::haveSpaceForNext(obj, numResults, bb.len())) { exec->enqueue(obj); break; } // Add result to output buffer. bb.appendBuf((void*)obj.objdata(), obj.objsize()); // Count the result. ++numResults; // Possibly note slave's position in the oplog. if (pq.isOplogReplay()) { BSONElement e = obj["ts"]; if (Date == e.type() || bsonTimestamp == e.type()) { slaveReadTill = e.timestamp(); } } if (FindCommon::enoughForFirstBatch(pq, numResults)) { LOG(5) << "Enough for first batch, wantMore=" << pq.wantMore() << " ntoreturn=" << pq.getNToReturn().value_or(0) << " numResults=" << numResults << endl; break; } } // If we cache the executor later, we want to deregister it as it receives notifications // anyway by virtue of being cached. // // If we don't cache the executor later, we are deleting it, so it must be deregistered. // // So, no matter what, deregister the executor. exec->deregisterExec(); // Caller expects exceptions thrown in certain cases. if (PlanExecutor::FAILURE == state || PlanExecutor::DEAD == state) { error() << "Plan executor error during find: " << PlanExecutor::statestr(state) << ", stats: " << Explain::getWinningPlanStats(exec.get()); uasserted(17144, "Executor error: " + WorkingSetCommon::toStatusString(obj)); } // Before saving the cursor, ensure that whatever plan we established happened with the expected // collection version auto css = CollectionShardingState::get(txn, nss); css->checkShardVersionOrThrow(txn); // Fill out curop based on query results. If we have a cursorid, we will fill out curop with // this cursorid later. long long ccId = 0; if (shouldSaveCursor(txn, collection, state, exec.get())) { // We won't use the executor until it's getMore'd. exec->saveState(); exec->detachFromOperationContext(); // Allocate a new ClientCursor. We don't have to worry about leaking it as it's // inserted into a global map by its ctor. ClientCursor* cc = new ClientCursor(collection->getCursorManager(), exec.release(), nss.ns(), txn->recoveryUnit()->isReadingFromMajorityCommittedSnapshot(), pq.getOptions(), pq.getFilter()); ccId = cc->cursorid(); LOG(5) << "caching executor with cursorid " << ccId << " after returning " << numResults << " results" << endl; // TODO document if (pq.isOplogReplay() && !slaveReadTill.isNull()) { cc->slaveReadTill(slaveReadTill); } // TODO document if (pq.isExhaust()) { curop.debug().exhaust = true; } cc->setPos(numResults); // If the query had a time limit, remaining time is "rolled over" to the cursor (for // use by future getmore ops). cc->setLeftoverMaxTimeMicros(curop.getRemainingMaxTimeMicros()); endQueryOp(txn, collection, *cc->getExecutor(), dbProfilingLevel, numResults, ccId); } else { LOG(5) << "Not caching executor but returning " << numResults << " results.\n"; endQueryOp(txn, collection, *exec, dbProfilingLevel, numResults, ccId); } // Add the results from the query into the output buffer. result.appendData(bb.buf(), bb.len()); bb.decouple(); // Fill out the output buffer's header. QueryResult::View qr = result.header().view2ptr(); qr.setCursorId(ccId); qr.setResultFlagsToOk(); qr.msgdata().setOperation(opReply); qr.setStartingFrom(0); qr.setNReturned(numResults); // curop.debug().exhaust is set above. return curop.debug().exhaust ? nss.ns() : ""; }
std::string runQuery(OperationContext* opCtx, QueryMessage& q, const NamespaceString& nss, Message& result) { CurOp& curOp = *CurOp::get(opCtx); curOp.ensureStarted(); uassert(ErrorCodes::InvalidNamespace, str::stream() << "Invalid ns [" << nss.ns() << "]", nss.isValid()); invariant(!nss.isCommand()); // Set CurOp information. const auto upconvertedQuery = upconvertQueryEntry(q.query, nss, q.ntoreturn, q.ntoskip); beginQueryOp(opCtx, nss, upconvertedQuery, q.ntoreturn, q.ntoskip); // Parse the qm into a CanonicalQuery. const boost::intrusive_ptr<ExpressionContext> expCtx; auto cq = uassertStatusOKWithContext( CanonicalQuery::canonicalize(opCtx, q, expCtx, ExtensionsCallbackReal(opCtx, &nss), MatchExpressionParser::kAllowAllSpecialFeatures), "Can't canonicalize query"); invariant(cq.get()); LOG(5) << "Running query:\n" << redact(cq->toString()); LOG(2) << "Running query: " << redact(cq->toStringShort()); // Parse, canonicalize, plan, transcribe, and get a plan executor. AutoGetCollectionForReadCommand ctx(opCtx, nss, AutoGetCollection::ViewMode::kViewsForbidden); Collection* const collection = ctx.getCollection(); { const QueryRequest& qr = cq->getQueryRequest(); // Allow the query to run on secondaries if the read preference permits it. If no read // preference was specified, allow the query to run iff slaveOk has been set. const bool slaveOK = qr.hasReadPref() ? uassertStatusOK(ReadPreferenceSetting::fromContainingBSON(q.query)) .canRunOnSecondary() : qr.isSlaveOk(); uassertStatusOK( repl::ReplicationCoordinator::get(opCtx)->checkCanServeReadsFor(opCtx, nss, slaveOK)); } // We have a parsed query. Time to get the execution plan for it. auto exec = uassertStatusOK(getExecutorLegacyFind(opCtx, collection, nss, std::move(cq))); const QueryRequest& qr = exec->getCanonicalQuery()->getQueryRequest(); // If it's actually an explain, do the explain and return rather than falling through // to the normal query execution loop. if (qr.isExplain()) { BufBuilder bb; bb.skip(sizeof(QueryResult::Value)); BSONObjBuilder explainBob; Explain::explainStages( exec.get(), collection, ExplainOptions::Verbosity::kExecAllPlans, &explainBob); // Add the resulting object to the return buffer. BSONObj explainObj = explainBob.obj(); bb.appendBuf((void*)explainObj.objdata(), explainObj.objsize()); // Set query result fields. QueryResult::View qr = bb.buf(); qr.setResultFlagsToOk(); qr.msgdata().setLen(bb.len()); curOp.debug().responseLength = bb.len(); qr.msgdata().setOperation(opReply); qr.setCursorId(0); qr.setStartingFrom(0); qr.setNReturned(1); result.setData(bb.release()); return ""; } // Handle query option $maxTimeMS (not used with commands). if (qr.getMaxTimeMS() > 0) { uassert(40116, "Illegal attempt to set operation deadline within DBDirectClient", !opCtx->getClient()->isInDirectClient()); opCtx->setDeadlineAfterNowBy(Milliseconds{qr.getMaxTimeMS()}); } opCtx->checkForInterrupt(); // May trigger maxTimeAlwaysTimeOut fail point. // Run the query. // bb is used to hold query results // this buffer should contain either requested documents per query or // explain information, but not both BufBuilder bb(FindCommon::kInitReplyBufferSize); bb.skip(sizeof(QueryResult::Value)); // How many results have we obtained from the executor? int numResults = 0; BSONObj obj; PlanExecutor::ExecState state; // Get summary info about which plan the executor is using. { stdx::lock_guard<Client> lk(*opCtx->getClient()); curOp.setPlanSummary_inlock(Explain::getPlanSummary(exec.get())); } while (PlanExecutor::ADVANCED == (state = exec->getNext(&obj, NULL))) { // If we can't fit this result inside the current batch, then we stash it for later. if (!FindCommon::haveSpaceForNext(obj, numResults, bb.len())) { exec->enqueue(obj); break; } // Add result to output buffer. bb.appendBuf((void*)obj.objdata(), obj.objsize()); // Count the result. ++numResults; if (FindCommon::enoughForFirstBatch(qr, numResults)) { LOG(5) << "Enough for first batch, wantMore=" << qr.wantMore() << " ntoreturn=" << qr.getNToReturn().value_or(0) << " numResults=" << numResults; break; } } // Caller expects exceptions thrown in certain cases. if (PlanExecutor::FAILURE == state || PlanExecutor::DEAD == state) { error() << "Plan executor error during find: " << PlanExecutor::statestr(state) << ", stats: " << redact(Explain::getWinningPlanStats(exec.get())); uassertStatusOKWithContext(WorkingSetCommon::getMemberObjectStatus(obj), "Executor error during OP_QUERY find"); MONGO_UNREACHABLE; } // Before saving the cursor, ensure that whatever plan we established happened with the expected // collection version auto css = CollectionShardingState::get(opCtx, nss); css->checkShardVersionOrThrow(opCtx); // Fill out CurOp based on query results. If we have a cursorid, we will fill out CurOp with // this cursorid later. long long ccId = 0; if (shouldSaveCursor(opCtx, collection, state, exec.get())) { // We won't use the executor until it's getMore'd. exec->saveState(); exec->detachFromOperationContext(); // Allocate a new ClientCursor and register it with the cursor manager. ClientCursorPin pinnedCursor = collection->getCursorManager()->registerCursor( opCtx, {std::move(exec), nss, AuthorizationSession::get(opCtx->getClient())->getAuthenticatedUserNames(), opCtx->recoveryUnit()->getReadConcernLevel(), upconvertedQuery}); ccId = pinnedCursor.getCursor()->cursorid(); LOG(5) << "caching executor with cursorid " << ccId << " after returning " << numResults << " results"; // TODO document if (qr.isExhaust()) { curOp.debug().exhaust = true; } pinnedCursor.getCursor()->setPos(numResults); // We assume that cursors created through a DBDirectClient are always used from their // original OperationContext, so we do not need to move time to and from the cursor. if (!opCtx->getClient()->isInDirectClient()) { // If the query had a time limit, remaining time is "rolled over" to the cursor (for // use by future getmore ops). pinnedCursor.getCursor()->setLeftoverMaxTimeMicros(opCtx->getRemainingMaxTimeMicros()); } endQueryOp(opCtx, collection, *pinnedCursor.getCursor()->getExecutor(), numResults, ccId); } else { LOG(5) << "Not caching executor but returning " << numResults << " results."; endQueryOp(opCtx, collection, *exec, numResults, ccId); } // Fill out the output buffer's header. QueryResult::View queryResultView = bb.buf(); queryResultView.setCursorId(ccId); queryResultView.setResultFlagsToOk(); queryResultView.msgdata().setLen(bb.len()); queryResultView.msgdata().setOperation(opReply); queryResultView.setStartingFrom(0); queryResultView.setNReturned(numResults); // Add the results from the query into the output buffer. result.setData(bb.release()); // curOp.debug().exhaust is set above. return curOp.debug().exhaust ? nss.ns() : ""; }