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/**
* Copyright (C) 2018-present MongoDB, Inc.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the Server Side Public License, version 1,
* as published by MongoDB, Inc.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* Server Side Public License for more details.
*
* You should have received a copy of the Server Side Public License
* along with this program. If not, see
* <http://www.mongodb.com/licensing/server-side-public-license>.
*
* As a special exception, the copyright holders give permission to link the
* code of portions of this program with the OpenSSL library under certain
* conditions as described in each individual source file and distribute
* linked combinations including the program with the OpenSSL library. You
* must comply with the Server Side Public License in all respects for
* all of the code used other than as permitted herein. If you modify file(s)
* with this exception, you may extend this exception to your version of the
* file(s), but you are not obligated to do so. If you do not wish to do so,
* delete this exception statement from your version. If you delete this
* exception statement from all source files in the program, then also delete
* it in the license file.
*/
#define MONGO_LOGV2_DEFAULT_COMPONENT ::mongo::logv2::LogComponent::kStorage
#define LOGV2_FOR_TRANSACTION(ID, DLEVEL, MESSAGE, ...) \
LOGV2_DEBUG_OPTIONS(ID, DLEVEL, {logv2::LogComponent::kTransaction}, MESSAGE, ##__VA_ARGS__)
#include "mongo/platform/basic.h"
#include "mongo/db/transaction_participant.h"
#include <fmt/format.h>
#include "mongo/db/catalog/database_holder.h"
#include "mongo/db/catalog/index_catalog.h"
#include "mongo/db/catalog/local_oplog_info.h"
#include "mongo/db/catalog_raii.h"
#include "mongo/db/commands/test_commands_enabled.h"
#include "mongo/db/concurrency/d_concurrency.h"
#include "mongo/db/concurrency/lock_state.h"
#include "mongo/db/concurrency/locker.h"
#include "mongo/db/concurrency/replication_state_transition_lock_guard.h"
#include "mongo/db/concurrency/write_conflict_exception.h"
#include "mongo/db/curop_failpoint_helpers.h"
#include "mongo/db/dbdirectclient.h"
#include "mongo/db/dbhelpers.h"
#include "mongo/db/index/index_access_method.h"
#include "mongo/db/internal_transactions_feature_flag_gen.h"
#include "mongo/db/logical_session_id.h"
#include "mongo/db/op_observer.h"
#include "mongo/db/ops/update.h"
#include "mongo/db/query/get_executor.h"
#include "mongo/db/repl/apply_ops_command_info.h"
#include "mongo/db/repl/repl_client_info.h"
#include "mongo/db/repl/storage_interface.h"
#include "mongo/db/retryable_writes_stats.h"
#include "mongo/db/server_recovery.h"
#include "mongo/db/server_transactions_metrics.h"
#include "mongo/db/stats/fill_locker_info.h"
#include "mongo/db/storage/flow_control.h"
#include "mongo/db/transaction_history_iterator.h"
#include "mongo/db/transaction_participant_gen.h"
#include "mongo/db/txn_retry_counter_too_old_info.h"
#include "mongo/db/vector_clock_mutable.h"
#include "mongo/logv2/log.h"
#include "mongo/util/fail_point.h"
#include "mongo/util/log_with_sampling.h"
#include "mongo/util/net/socket_utils.h"
namespace mongo {
using namespace fmt::literals;
namespace {
// Failpoint which will pause an operation just after allocating a point-in-time storage engine
// transaction.
MONGO_FAIL_POINT_DEFINE(hangAfterPreallocateSnapshot);
MONGO_FAIL_POINT_DEFINE(hangAfterReservingPrepareTimestamp);
MONGO_FAIL_POINT_DEFINE(hangAfterSettingPrepareStartTime);
MONGO_FAIL_POINT_DEFINE(hangBeforeReleasingTransactionOplogHole);
MONGO_FAIL_POINT_DEFINE(skipCommitTxnCheckPrepareMajorityCommitted);
MONGO_FAIL_POINT_DEFINE(restoreLocksFail);
MONGO_FAIL_POINT_DEFINE(failTransactionNoopWrite);
const auto getTransactionParticipant = Session::declareDecoration<TransactionParticipant>();
// The command names that are allowed in a prepared transaction.
const StringMap<int> preparedTxnCmdAllowlist = {
{"abortTransaction", 1}, {"commitTransaction", 1}, {"prepareTransaction", 1}};
void fassertOnRepeatedExecution(const LogicalSessionId& lsid,
TxnNumberAndRetryCounter txnNumberAndRetryCounter,
StmtId stmtId,
const repl::OpTime& firstOpTime,
const repl::OpTime& secondOpTime) {
LOGV2_FATAL(
40526,
"Statement id {stmtId} from transaction [ {lsid}:{txnNumberAndRetryCounter} ] was "
"committed once with opTime {firstCommitOpTime} and a second time with opTime { "
"secondCommitOpTime}. This indicates possible data corruption or server bug and the "
"process will be terminated.",
"Statement from transaction was committed twice. This indicates possible data corruption "
"or server bug and the process will be terminated",
"stmtId"_attr = stmtId,
"lsid"_attr = lsid.toBSON(),
"txnNumberAndRetryCounter"_attr = txnNumberAndRetryCounter,
"firstCommitOpTime"_attr = firstOpTime,
"secondCommitOpTime"_attr = secondOpTime);
}
void validateTransactionHistoryApplyOpsOplogEntry(const repl::OplogEntry& oplogEntry) {
uassert(5875601,
"Found an applyOps oplog entry for retryable writes that were executed without "
"using a retryable internal transaction",
isInternalSessionForRetryableWrite(*oplogEntry.getSessionId()));
uassert(5875602,
"Found an applyOps oplog entry for retryable internal transaction with top-level "
"'stmtId' field",
oplogEntry.getStatementIds().empty());
}
struct ActiveTransactionHistory {
boost::optional<SessionTxnRecord> lastTxnRecord;
TransactionParticipant::CommittedStatementTimestampMap committedStatements;
bool hasIncompleteHistory{false};
};
ActiveTransactionHistory fetchActiveTransactionHistory(OperationContext* opCtx,
const LogicalSessionId& lsid,
bool fetchOplogEntries) {
// Storage engine operations require at least Global IS.
Lock::GlobalLock lk(opCtx, MODE_IS);
// Restore the current timestamp read source after fetching transaction history using
// DBDirectClient, which may change our ReadSource.
ReadSourceScope readSourceScope(opCtx, RecoveryUnit::ReadSource::kNoTimestamp);
ActiveTransactionHistory result;
result.lastTxnRecord = [&]() -> boost::optional<SessionTxnRecord> {
DBDirectClient client(opCtx);
// Even though the request only performs a read, the OpCtx's "in multi document transaction"
// field has been set, bumping the global lock acquisition to an IX. That upconvert would
// require a flow control ticket to be obtained.
FlowControl::Bypass flowControlBypass(opCtx);
auto result = client.findOne(NamespaceString::kSessionTransactionsTableNamespace,
BSON(SessionTxnRecord::kSessionIdFieldName << lsid.toBSON()));
if (result.isEmpty()) {
return boost::none;
}
return SessionTxnRecord::parse(IDLParserErrorContext("parse latest txn record for session"),
result);
}();
if (!result.lastTxnRecord) {
return result;
}
if (auto state = result.lastTxnRecord->getState()) {
if (!isInternalSessionForRetryableWrite(lsid) || state == DurableTxnStateEnum::kAborted) {
// When state is given, it must be a transaction, so we don't need to traverse the
// history if it is not a transaction for retryable writes.
return result;
}
}
if (!fetchOplogEntries) {
return result;
}
auto insertStmtIdsForOplogEntry = [&](const repl::OplogEntry& entry) {
for (auto stmtId : entry.getStatementIds()) {
uassert(5875604,
str::stream() << "Found an oplog entry with an invalid stmtId "
<< entry.toBSONForLogging(),
stmtId >= 0);
const auto insertRes = result.committedStatements.emplace(stmtId, entry.getOpTime());
if (!insertRes.second) {
const auto& existingOpTime = insertRes.first->second;
fassertOnRepeatedExecution(lsid,
result.lastTxnRecord->getTxnNum(),
stmtId,
existingOpTime,
entry.getOpTime());
}
}
};
auto it = TransactionHistoryIterator(result.lastTxnRecord->getLastWriteOpTime());
while (it.hasNext()) {
try {
const auto entry = it.next(opCtx);
// Each entry should correspond to a retryable write or a FCV4.0 format transaction.
// These oplog entries must have statementIds.
auto stmtIds = entry.getStatementIds();
if (isInternalSessionForRetryableWrite(lsid)) {
uassert(5875605,
"Found an oplog entry for retryable internal transaction with top-level "
"'stmtId' field",
stmtIds.empty());
if (entry.getCommandType() == repl::OplogEntry::CommandType::kCommitTransaction) {
continue;
} else if (entry.getCommandType() == repl::OplogEntry::CommandType::kApplyOps) {
validateTransactionHistoryApplyOpsOplogEntry(entry);
std::vector<repl::OplogEntry> innerEntries;
repl::ApplyOps::extractOperationsTo(
entry, entry.getEntry().toBSON(), &innerEntries);
for (const auto& innerEntry : innerEntries) {
insertStmtIdsForOplogEntry(innerEntry);
}
} else {
MONGO_UNREACHABLE;
}
} else {
invariant(!stmtIds.empty());
if (stmtIds.front() == kIncompleteHistoryStmtId) {
// Only the dead end sentinel can have this id for oplog write history
invariant(stmtIds.size() == 1);
invariant(entry.getObject2());
invariant(entry.getObject2()->woCompare(
TransactionParticipant::kDeadEndSentinel) == 0);
result.hasIncompleteHistory = true;
continue;
}
if (entry.getCommandType() == repl::OplogEntry::CommandType::kApplyOps &&
!entry.shouldPrepare() && !entry.isPartialTransaction()) {
result.lastTxnRecord->setState(DurableTxnStateEnum::kCommitted);
return result;
}
insertStmtIdsForOplogEntry(entry);
}
} catch (const DBException& ex) {
if (ex.code() == ErrorCodes::IncompleteTransactionHistory) {
result.hasIncompleteHistory = true;
break;
}
throw;
}
}
return result;
}
void updateSessionEntry(OperationContext* opCtx,
const UpdateRequest& updateRequest,
const LogicalSessionId& sessionId,
TxnNumber txnNum) {
// Current code only supports replacement update.
dassert(UpdateDriver::isDocReplacement(updateRequest.getUpdateModification()));
// TODO SERVER-58243: evaluate whether this is safe or whether acquiring the lock can block.
AllowLockAcquisitionOnTimestampedUnitOfWork allowLockAcquisition(opCtx->lockState());
AutoGetCollection collection(
opCtx, NamespaceString::kSessionTransactionsTableNamespace, MODE_IX);
uassert(40527,
str::stream() << "Unable to persist transaction state because the session transaction "
"collection is missing. This indicates that the "
<< NamespaceString::kSessionTransactionsTableNamespace.ns()
<< " collection has been manually deleted.",
collection.getCollection());
WriteUnitOfWork wuow(opCtx);
auto idIndex = collection->getIndexCatalog()->findIdIndex(opCtx);
uassert(40672,
str::stream() << "Failed to fetch _id index for "
<< NamespaceString::kSessionTransactionsTableNamespace.ns(),
idIndex);
auto indexAccess = collection->getIndexCatalog()->getEntry(idIndex)->accessMethod();
// Since we are looking up a key inside the _id index, create a key object consisting of only
// the _id field.
auto idToFetch = updateRequest.getQuery().firstElement();
auto toUpdateIdDoc = idToFetch.wrap();
dassert(idToFetch.fieldNameStringData() == "_id"_sd);
auto recordId = indexAccess->findSingle(opCtx, *collection, toUpdateIdDoc);
auto startingSnapshotId = opCtx->recoveryUnit()->getSnapshotId();
const auto updateMod = updateRequest.getUpdateModification().getUpdateClassic();
if (recordId.isNull()) {
// Upsert case.
auto status = collection->insertDocument(opCtx, InsertStatement(updateMod), nullptr, false);
if (status == ErrorCodes::DuplicateKey) {
throw WriteConflictException(
str::stream() << "Updating session entry failed with duplicate key, session "_sd
<< sessionId << ", transaction "_sd << txnNum);
}
uassertStatusOK(status);
wuow.commit();
return;
}
auto originalRecordData = collection->getRecordStore()->dataFor(opCtx, recordId);
auto originalDoc = originalRecordData.toBson();
const auto parentLsidFieldName = SessionTxnRecord::kParentSessionIdFieldName;
uassert(5875700,
str::stream() << "Cannot modify the '" << parentLsidFieldName << "' field of "
<< NamespaceString::kSessionTransactionsTableNamespace << " entries",
updateMod.getObjectField(parentLsidFieldName)
.woCompare(originalDoc.getObjectField(parentLsidFieldName)) == 0);
invariant(collection->getDefaultCollator() == nullptr);
boost::intrusive_ptr<ExpressionContext> expCtx(
new ExpressionContext(opCtx, nullptr, updateRequest.getNamespaceString()));
auto matcher =
fassert(40673, MatchExpressionParser::parse(updateRequest.getQuery(), std::move(expCtx)));
if (!matcher->matchesBSON(originalDoc)) {
// Document no longer match what we expect so throw WCE to make the caller re-examine.
throw WriteConflictException(
str::stream() << "Updating session entry failed as document no longer matches, "_sd
<< "session "_sd << sessionId << ", transaction "_sd << txnNum);
}
CollectionUpdateArgs args;
args.update = updateMod;
args.criteria = toUpdateIdDoc;
// Specify indexesAffected = false because the sessions collection has two indexes: {_id: 1} and
// {parentLsid: 1, _id.txnNumber: 1, _id: 1}, and none of the fields are mutable.
collection->updateDocument(opCtx,
recordId,
Snapshotted<BSONObj>(startingSnapshotId, originalDoc),
updateMod,
false, /* indexesAffected */
nullptr,
&args);
wuow.commit();
}
// Failpoint which allows different failure actions to happen after each write. Supports the
// parameters below, which can be combined with each other (unless explicitly disallowed):
//
// closeConnection (bool, default = true): Closes the connection on which the write was executed.
// failBeforeCommitExceptionCode (int, default = not specified): If set, the specified exception
// code will be thrown, which will cause the write to not commit; if not specified, the write
// will be allowed to commit.
MONGO_FAIL_POINT_DEFINE(onPrimaryTransactionalWrite);
} // namespace
const BSONObj TransactionParticipant::kDeadEndSentinel(BSON("$incompleteOplogHistory" << 1));
TransactionParticipant::TransactionParticipant() = default;
TransactionParticipant::~TransactionParticipant() {
// invariant(!_o.txnState.isInProgress());
}
TransactionParticipant::Observer::Observer(const ObservableSession& osession)
: Observer(&getTransactionParticipant(osession.get())) {}
TransactionParticipant::Participant::Participant(OperationContext* opCtx)
: Observer([opCtx]() -> TransactionParticipant* {
if (auto session = OperationContextSession::get(opCtx)) {
return &getTransactionParticipant(session);
}
return nullptr;
}()) {}
TransactionParticipant::Participant::Participant(const SessionToKill& session)
: Observer(&getTransactionParticipant(session.get())) {}
void TransactionParticipant::performNoopWrite(OperationContext* opCtx, StringData msg) {
const auto replCoord = repl::ReplicationCoordinator::get(opCtx);
// The locker must not have a max lock timeout when this noop write is performed, since if it
// threw LockTimeout, this would be treated as a TransientTransactionError, which would indicate
// it's safe to retry the entire transaction. We cannot know it is safe to attach
// TransientTransactionError until the noop write has been performed and the writeConcern has
// been satisfied.
invariant(!opCtx->lockState()->hasMaxLockTimeout());
// Simulate an operation timeout and fail the noop write if the fail point is enabled. This is
// to test that NoSuchTransaction error is not considered transient if the noop write cannot
// occur.
if (MONGO_unlikely(failTransactionNoopWrite.shouldFail())) {
uasserted(ErrorCodes::MaxTimeMSExpired, "failTransactionNoopWrite fail point enabled");
}
{
AutoGetOplog oplogWrite(opCtx, OplogAccessMode::kWrite);
uassert(ErrorCodes::NotWritablePrimary,
"Not primary when performing noop write for {}"_format(msg),
replCoord->canAcceptWritesForDatabase(opCtx, "admin"));
writeConflictRetry(
opCtx, "performNoopWrite", NamespaceString::kRsOplogNamespace.ns(), [&opCtx, &msg] {
WriteUnitOfWork wuow(opCtx);
opCtx->getClient()->getServiceContext()->getOpObserver()->onOpMessage(
opCtx, BSON("msg" << msg));
wuow.commit();
});
}
}
StorageEngine::OldestActiveTransactionTimestampResult
TransactionParticipant::getOldestActiveTimestamp(Timestamp stableTimestamp) {
// Read from config.transactions at the stable timestamp for the oldest active transaction
// timestamp. Use a short timeout: another thread might have the global lock e.g. to shut down
// the server, and it both blocks this thread from querying config.transactions and waits for
// this thread to terminate.
auto client = getGlobalServiceContext()->makeClient("OldestActiveTxnTimestamp");
AlternativeClientRegion acr(client);
try {
auto opCtx = cc().makeOperationContext();
auto nss = NamespaceString::kSessionTransactionsTableNamespace;
auto deadline = Date_t::now() + Milliseconds(100);
ShouldNotConflictWithSecondaryBatchApplicationBlock shouldNotConflictBlock(
opCtx->lockState());
Lock::DBLock dbLock(opCtx.get(), nss.db(), MODE_IS, deadline);
Lock::CollectionLock collLock(opCtx.get(), nss, MODE_IS, deadline);
auto databaseHolder = DatabaseHolder::get(opCtx.get());
auto db = databaseHolder->getDb(opCtx.get(), nss.db());
if (!db) {
// There is no config database, so there cannot be any active transactions.
return boost::none;
}
auto collection =
CollectionCatalog::get(opCtx.get())->lookupCollectionByNamespace(opCtx.get(), nss);
if (!collection) {
return boost::none;
}
if (!stableTimestamp.isNull()) {
opCtx->recoveryUnit()->setTimestampReadSource(RecoveryUnit::ReadSource::kProvided,
stableTimestamp);
}
// Scan. We guess that occasional scans are cheaper than the write overhead of an index.
boost::optional<Timestamp> oldestTxnTimestamp;
auto cursor = collection->getCursor(opCtx.get());
while (auto record = cursor->next()) {
auto doc = record.get().data.toBson();
auto txnRecord = SessionTxnRecord::parse(
IDLParserErrorContext("parse oldest active txn record"), doc);
if (txnRecord.getState() != DurableTxnStateEnum::kPrepared &&
txnRecord.getState() != DurableTxnStateEnum::kInProgress) {
continue;
}
// A prepared transaction must have a start timestamp.
invariant(txnRecord.getStartOpTime());
auto ts = txnRecord.getStartOpTime()->getTimestamp();
if (!oldestTxnTimestamp || ts < oldestTxnTimestamp.value()) {
oldestTxnTimestamp = ts;
}
}
return oldestTxnTimestamp;
} catch (const DBException&) {
return exceptionToStatus();
}
}
const LogicalSessionId& TransactionParticipant::Observer::_sessionId() const {
const auto* owningSession = getTransactionParticipant.owner(_tp);
return owningSession->getSessionId();
}
bool TransactionParticipant::Observer::_isInternalSessionForRetryableWrite() const {
return isInternalSessionForRetryableWrite(_sessionId());
}
void TransactionParticipant::Participant::_beginOrContinueRetryableWrite(
OperationContext* opCtx, const TxnNumberAndRetryCounter& txnNumberAndRetryCounter) {
invariant(!txnNumberAndRetryCounter.getTxnRetryCounter());
if (txnNumberAndRetryCounter.getTxnNumber() >
o().activeTxnNumberAndRetryCounter.getTxnNumber()) {
// New retryable write.
_setNewTxnNumberAndRetryCounter(
opCtx, {txnNumberAndRetryCounter.getTxnNumber(), kUninitializedTxnRetryCounter});
p().autoCommit = boost::none;
} else {
// Retrying a retryable write.
uassert(ErrorCodes::IncompleteTransactionHistory,
"Cannot retry a retryable write that has been converted into a transaction",
o().txnState.isInRetryableWriteMode());
invariant(p().autoCommit == boost::none);
}
}
void TransactionParticipant::Participant::_continueMultiDocumentTransaction(
OperationContext* opCtx, const TxnNumberAndRetryCounter& txnNumberAndRetryCounter) {
uassert(ErrorCodes::NoSuchTransaction,
str::stream()
<< "Given transaction number " << txnNumberAndRetryCounter.getTxnNumber()
<< " does not match any in-progress transactions. The active transaction number is "
<< o().activeTxnNumberAndRetryCounter.getTxnNumber(),
txnNumberAndRetryCounter.getTxnNumber() ==
o().activeTxnNumberAndRetryCounter.getTxnNumber() &&
!o().txnState.isInRetryableWriteMode());
uassert(TxnRetryCounterTooOldInfo(*o().activeTxnNumberAndRetryCounter.getTxnRetryCounter()),
str::stream() << "Cannot continue transaction "
<< txnNumberAndRetryCounter.getTxnNumber() << " on session "
<< _sessionId() << " using txnRetryCounter "
<< txnNumberAndRetryCounter.getTxnRetryCounter()
<< " because it has already been restarted using a higher"
<< " txnRetryCounter "
<< o().activeTxnNumberAndRetryCounter.getTxnRetryCounter(),
txnNumberAndRetryCounter.getTxnRetryCounter() >=
o().activeTxnNumberAndRetryCounter.getTxnRetryCounter());
uassert(ErrorCodes::IllegalOperation,
str::stream() << "Cannot continue transaction "
<< txnNumberAndRetryCounter.getTxnNumber() << " on session "
<< _sessionId() << " using txnNumberAndRetryCounter.getTxnRetryCounter() "
<< txnNumberAndRetryCounter.getTxnRetryCounter()
<< " because it is currently in state " << o().txnState
<< " with txnRetryCounter "
<< o().activeTxnNumberAndRetryCounter.getTxnRetryCounter(),
txnNumberAndRetryCounter.getTxnRetryCounter() ==
o().activeTxnNumberAndRetryCounter.getTxnRetryCounter());
if (o().txnState.isInProgress() && !o().txnResourceStash) {
// This indicates that the first command in the transaction failed but did not implicitly
// abort the transaction. It is not safe to continue the transaction, in particular because
// we have not saved the readConcern from the first statement of the transaction. Mark the
// transaction as active here, since _abortTransactionOnSession() will assume we are
// aborting an active transaction since there are no stashed resources.
{
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).transactionMetricsObserver.onUnstash(
ServerTransactionsMetrics::get(opCtx->getServiceContext()),
opCtx->getServiceContext()->getTickSource());
}
_abortTransactionOnSession(opCtx);
uasserted(
ErrorCodes::NoSuchTransaction,
str::stream()
<< "Transaction with " << txnNumberAndRetryCounter.toBSON()
<< " has been aborted because an earlier command in this transaction failed.");
}
}
void TransactionParticipant::Participant::_beginMultiDocumentTransaction(
OperationContext* opCtx, const TxnNumberAndRetryCounter& txnNumberAndRetryCounter) {
if (txnNumberAndRetryCounter.getTxnNumber() ==
o().activeTxnNumberAndRetryCounter.getTxnNumber()) {
if (txnNumberAndRetryCounter.getTxnRetryCounter() <
o().activeTxnNumberAndRetryCounter.getTxnRetryCounter()) {
uasserted(
TxnRetryCounterTooOldInfo(*o().activeTxnNumberAndRetryCounter.getTxnRetryCounter()),
str::stream() << "Cannot start a transaction at given transaction number "
<< txnNumberAndRetryCounter.getTxnNumber() << " on session "
<< _sessionId() << " using txnRetryCounter "
<< txnNumberAndRetryCounter.getTxnRetryCounter()
<< " because it has already been restarted using a "
<< "higher txnRetryCounter "
<< o().activeTxnNumberAndRetryCounter.getTxnRetryCounter());
} else if (txnNumberAndRetryCounter.getTxnRetryCounter() ==
o().activeTxnNumberAndRetryCounter.getTxnRetryCounter() ||
o().activeTxnNumberAndRetryCounter.getTxnRetryCounter() ==
kUninitializedTxnRetryCounter) {
// Servers in a sharded cluster can start a new transaction at the active transaction
// number to allow internal retries by routers on re-targeting errors, like
// StaleShard/DatabaseVersion or SnapshotTooOld.
uassert(ErrorCodes::ConflictingOperationInProgress,
"Only servers in a sharded cluster can start a new transaction at the active "
"transaction number",
serverGlobalParams.clusterRole != ClusterRole::None);
if (_isInternalSessionForRetryableWrite() &&
o().txnState.isInSet(TransactionState::kCommitted)) {
// This is a retry of a committed internal transaction for retryable writes so
// skip resetting the state and updating the metrics.
return;
}
// The active transaction number can only be reused if:
// 1. The transaction participant is in retryable write mode and has not yet executed a
// retryable write, or
// 2. A transaction is aborted and has not been involved in a two phase commit.
//
// Assuming routers target primaries in increasing order of term and in the absence of
// byzantine messages, this check should never fail.
const auto restartableStates =
TransactionState::kNone | TransactionState::kAbortedWithoutPrepare;
uassert(50911,
str::stream() << "Cannot start a transaction at given transaction with "
<< txnNumberAndRetryCounter.toBSON()
<< " because a transaction with the same number is in state "
<< o().txnState,
o().txnState.isInSet(restartableStates));
} else {
const auto restartableStates = TransactionState::kNone | TransactionState::kInProgress |
TransactionState::kAbortedWithoutPrepare | TransactionState::kAbortedWithPrepare;
uassert(ErrorCodes::IllegalOperation,
str::stream() << "Cannot restart transaction "
<< txnNumberAndRetryCounter.getTxnNumber()
<< " using txnRetryCounter "
<< txnNumberAndRetryCounter.getTxnRetryCounter()
<< " because it is already in state " << o().txnState
<< " with txnRetryCounter "
<< o().activeTxnNumberAndRetryCounter.getTxnRetryCounter(),
o().txnState.isInSet(restartableStates));
}
} else {
invariant(txnNumberAndRetryCounter.getTxnNumber() >
o().activeTxnNumberAndRetryCounter.getTxnNumber());
}
// Aborts any in-progress txns.
_setNewTxnNumberAndRetryCounter(opCtx, txnNumberAndRetryCounter);
p().autoCommit = false;
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).txnState.transitionTo(TransactionState::kInProgress);
// Start tracking various transactions metrics.
//
// We measure the start time in both microsecond and millisecond resolution. The TickSource
// provides microsecond resolution to record the duration of the transaction. The start "wall
// clock" time can be considered an approximation to the microsecond measurement.
auto now = opCtx->getServiceContext()->getPreciseClockSource()->now();
auto tickSource = opCtx->getServiceContext()->getTickSource();
o(lk).transactionExpireDate = now + Seconds(gTransactionLifetimeLimitSeconds.load());
o(lk).transactionMetricsObserver.onStart(
ServerTransactionsMetrics::get(opCtx->getServiceContext()),
*p().autoCommit,
tickSource,
now,
*o().transactionExpireDate);
invariant(p().transactionOperations.empty());
}
void TransactionParticipant::Participant::beginOrContinue(
OperationContext* opCtx,
TxnNumberAndRetryCounter txnNumberAndRetryCounter,
boost::optional<bool> autocommit,
boost::optional<bool> startTransaction) {
// Make sure we are still a primary. We need to hold on to the RSTL through the end of this
// method, as we otherwise risk stepping down in the interim and incorrectly updating the
// transaction number, which can abort active transactions.
repl::ReplicationStateTransitionLockGuard rstl(opCtx, MODE_IX);
if (opCtx->writesAreReplicated()) {
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
uassert(ErrorCodes::NotWritablePrimary,
"Not primary so we cannot begin or continue a transaction",
replCoord->canAcceptWritesForDatabase(opCtx, "admin"));
// Disallow multi-statement transactions on shard servers that have
// writeConcernMajorityJournalDefault=false unless enableTestCommands=true. But allow
// retryable writes (autocommit == boost::none).
uassert(ErrorCodes::OperationNotSupportedInTransaction,
"Transactions are not allowed on shard servers when "
"writeConcernMajorityJournalDefault=false",
replCoord->getWriteConcernMajorityShouldJournal() ||
serverGlobalParams.clusterRole != ClusterRole::ShardServer || !autocommit ||
getTestCommandsEnabled());
}
if (txnNumberAndRetryCounter.getTxnNumber() <
o().activeTxnNumberAndRetryCounter.getTxnNumber()) {
const std::string currOperation =
o().txnState.isInRetryableWriteMode() ? "retryable write" : "transaction";
if (!autocommit) {
uasserted(ErrorCodes::TransactionTooOld,
str::stream()
<< "Retryable write with txnNumber "
<< txnNumberAndRetryCounter.getTxnNumber() << " is prohibited on session "
<< _sessionId() << " because a newer " << currOperation
<< " with txnNumber " << o().activeTxnNumberAndRetryCounter.getTxnNumber()
<< " has already started on this session.");
} else {
uasserted(ErrorCodes::TransactionTooOld,
str::stream()
<< "Cannot start transaction with " << txnNumberAndRetryCounter.toBSON()
<< " on session " << _sessionId() << " because a newer " << currOperation
<< " with txnNumberAndRetryCounter "
<< o().activeTxnNumberAndRetryCounter.toBSON()
<< " has already started on this session.");
}
}
// Requests without an autocommit field are interpreted as retryable writes. They cannot specify
// startTransaction, which is verified earlier when parsing the request.
if (!autocommit) {
invariant(!startTransaction);
invariant(!txnNumberAndRetryCounter.getTxnRetryCounter(),
"Cannot specify a txnRetryCounter for retryable write");
_beginOrContinueRetryableWrite(opCtx, txnNumberAndRetryCounter);
return;
}
// Attempt to continue a multi-statement transaction. In this case, it is required that
// autocommit be given as an argument on the request, and currently it can only be false, which
// is verified earlier when parsing the request.
invariant(*autocommit == false);
invariant(opCtx->inMultiDocumentTransaction());
if (txnNumberAndRetryCounter.getTxnRetryCounter()) {
uassert(ErrorCodes::InvalidOptions,
"txnRetryCounter is only supported in sharded clusters",
serverGlobalParams.clusterRole != ClusterRole::None);
invariant(*txnNumberAndRetryCounter.getTxnRetryCounter() >= 0,
"Cannot specify a negative txnRetryCounter");
} else {
txnNumberAndRetryCounter.setTxnRetryCounter(0);
}
if (!startTransaction) {
_continueMultiDocumentTransaction(opCtx, txnNumberAndRetryCounter);
return;
}
// Attempt to start a multi-statement transaction, which requires startTransaction be given as
// an argument on the request. The 'startTransaction' argument currently can only be specified
// as true, which is verified earlier, when parsing the request.
invariant(*startTransaction);
_beginMultiDocumentTransaction(opCtx, txnNumberAndRetryCounter);
}
void TransactionParticipant::Participant::beginOrContinueTransactionUnconditionally(
OperationContext* opCtx, TxnNumberAndRetryCounter txnNumberAndRetryCounter) {
invariant(opCtx->inMultiDocumentTransaction());
// We don't check or fetch any on-disk state, so treat the transaction as 'valid' for the
// purposes of this method and continue the transaction unconditionally
p().isValid = true;
if (o().activeTxnNumberAndRetryCounter.getTxnNumber() !=
txnNumberAndRetryCounter.getTxnNumber()) {
if (!txnNumberAndRetryCounter.getTxnRetryCounter()) {
txnNumberAndRetryCounter.setTxnRetryCounter(0);
}
_beginMultiDocumentTransaction(opCtx, txnNumberAndRetryCounter);
} else {
invariant(o().txnState.isInSet(TransactionState::kInProgress | TransactionState::kPrepared),
str::stream() << "Current state: " << o().txnState);
}
// Assume we need to write an abort if we abort this transaction. This method is called only
// on secondaries (in which case we never write anything) and when a new primary knows about
// an in-progress transaction. If a new primary knows about an in-progress transaction, it
// needs an abort oplog entry to be written if aborted (because the new primary could not
// have found out if there wasn't an oplog entry for the new primary).
p().needToWriteAbortEntry = true;
}
SharedSemiFuture<void> TransactionParticipant::Participant::onExitPrepare() const {
if (!o().txnState._exitPreparePromise) {
// The participant is not in prepare, so just return a ready future.
return Future<void>::makeReady();
}
// The participant is in prepare, so return a future that will be signaled when the participant
// transitions out of prepare.
return o().txnState._exitPreparePromise->getFuture();
}
void TransactionParticipant::Participant::_setReadSnapshot(OperationContext* opCtx,
repl::ReadConcernArgs readConcernArgs) {
if (readConcernArgs.getArgsAtClusterTime()) {
// Read concern code should have already set the timestamp on the recovery unit.
const auto readTimestamp = readConcernArgs.getArgsAtClusterTime()->asTimestamp();
const auto ruTs = opCtx->recoveryUnit()->getPointInTimeReadTimestamp(opCtx);
invariant(readTimestamp == ruTs,
"readTimestamp: {}, pointInTime: {}"_format(readTimestamp.toString(),
ruTs ? ruTs->toString() : "none"));
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).transactionMetricsObserver.onChooseReadTimestamp(readTimestamp);
} else if (readConcernArgs.getLevel() == repl::ReadConcernLevel::kSnapshotReadConcern) {
// For transactions with read concern level specified as 'snapshot', we will use
// 'kAllDurableSnapshot' which ensures a snapshot with no 'holes'; that is, it is a state
// of the system that could be reconstructed from the oplog.
opCtx->recoveryUnit()->setTimestampReadSource(
RecoveryUnit::ReadSource::kAllDurableSnapshot);
const auto readTimestamp =
repl::StorageInterface::get(opCtx)->getPointInTimeReadTimestamp(opCtx);
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).transactionMetricsObserver.onChooseReadTimestamp(readTimestamp);
} else {
// For transactions with read concern level specified as 'local' or 'majority', we will use
// 'kNoTimestamp' which gives us the most recent snapshot. This snapshot may reflect oplog
// 'holes' from writes earlier than the last applied write which have not yet completed.
// Using 'kNoTimestamp' ensures that transactions with mode 'local' are always able to read
// writes from earlier transactions with mode 'local' on the same connection.
opCtx->recoveryUnit()->setTimestampReadSource(RecoveryUnit::ReadSource::kNoTimestamp);
// Catalog conflicting timestamps must be set on primaries performing transactions.
// However, secondaries performing oplog application must avoid setting
// _catalogConflictTimestamp. Currently, only oplog application on secondaries can run
// inside a transaction, thus `writesAreReplicated` is a suitable proxy to single out
// transactions on primaries.
if (opCtx->writesAreReplicated()) {
// Since this snapshot may reflect oplog holes, record the most visible timestamp before
// opening a storage transaction. This timestamp will be used later to detect any
// changes in the catalog after a storage transaction is opened.
opCtx->recoveryUnit()->setCatalogConflictingTimestamp(
opCtx->getServiceContext()->getStorageEngine()->getAllDurableTimestamp());
}
}
opCtx->recoveryUnit()->preallocateSnapshot();
}
TransactionParticipant::OplogSlotReserver::OplogSlotReserver(OperationContext* opCtx,
int numSlotsToReserve)
: _opCtx(opCtx), _globalLock(opCtx, MODE_IX) {
// Stash the transaction on the OperationContext on the stack. At the end of this function it
// will be unstashed onto the OperationContext.
TransactionParticipant::SideTransactionBlock sideTxn(opCtx);
// Begin a new WUOW and reserve a slot in the oplog.
WriteUnitOfWork wuow(opCtx);
auto oplogInfo = LocalOplogInfo::get(opCtx);
_oplogSlots = oplogInfo->getNextOpTimes(opCtx, numSlotsToReserve);
// Release the WUOW state since this WUOW is no longer in use.
wuow.release();
// We must lock the Client to change the Locker on the OperationContext.
stdx::lock_guard<Client> lk(*opCtx->getClient());
// Save the RecoveryUnit from the new transaction and replace it with an empty one.
_recoveryUnit = opCtx->releaseAndReplaceRecoveryUnit();
// End two-phase locking on locker manually since the WUOW has been released.
_opCtx->lockState()->endWriteUnitOfWork();
}
TransactionParticipant::OplogSlotReserver::~OplogSlotReserver() {
if (MONGO_unlikely(hangBeforeReleasingTransactionOplogHole.shouldFail())) {
LOGV2(22520,
"transaction - hangBeforeReleasingTransactionOplogHole fail point enabled. Blocking "
"until fail point is disabled");
hangBeforeReleasingTransactionOplogHole.pauseWhileSet();
}
// If the constructor did not complete, we do not attempt to abort the units of work.
if (_recoveryUnit) {
// We should be at WUOW nesting level 1, only the top level WUOW for the oplog reservation
// side transaction.
_recoveryUnit->abortUnitOfWork();
}
}
TransactionParticipant::TxnResources::TxnResources(WithLock wl,
OperationContext* opCtx,
StashStyle stashStyle) noexcept {
// We must hold the Client lock to change the Locker on the OperationContext. Hence the
// WithLock.
_ruState = opCtx->getWriteUnitOfWork()->release();
opCtx->setWriteUnitOfWork(nullptr);
_locker = opCtx->swapLockState(std::make_unique<LockerImpl>(), wl);
// Inherit the locking setting from the original one.
opCtx->lockState()->setShouldConflictWithSecondaryBatchApplication(
_locker->shouldConflictWithSecondaryBatchApplication());
_locker->releaseTicket();
_locker->unsetThreadId();
if (opCtx->getLogicalSessionId()) {
_locker->setDebugInfo("lsid: " + opCtx->getLogicalSessionId()->toBSON().toString());
}
// On secondaries, we yield the locks for transactions.
if (stashStyle == StashStyle::kSecondary) {
_lockSnapshot = std::make_unique<Locker::LockSnapshot>();
// Transactions have at least a global IX lock. Invariant that we have something to release.
invariant(_locker->releaseWriteUnitOfWorkAndUnlock(_lockSnapshot.get()));
}
// This thread must still respect the transaction lock timeout, since it can prevent the
// transaction from making progress.
auto maxTransactionLockMillis = gMaxTransactionLockRequestTimeoutMillis.load();
if (stashStyle == StashStyle::kPrimary && maxTransactionLockMillis >= 0) {
opCtx->lockState()->setMaxLockTimeout(Milliseconds(maxTransactionLockMillis));
}
// On secondaries, max lock timeout must not be set.
invariant(!(stashStyle == StashStyle::kSecondary && opCtx->lockState()->hasMaxLockTimeout()));
_recoveryUnit = opCtx->releaseAndReplaceRecoveryUnit();
_apiParameters = APIParameters::get(opCtx);
_readConcernArgs = repl::ReadConcernArgs::get(opCtx);
_uncommittedCollections = UncommittedCollections::get(opCtx).releaseResources();
_uncommittedMultikey = UncommittedMultikey::get(opCtx).releaseResources();
}
TransactionParticipant::TxnResources::~TxnResources() {
if (!_released && _recoveryUnit) {
// This should only be reached when aborting a transaction that isn't active, i.e.
// when starting a new transaction before completing an old one. So we should
// be at WUOW nesting level 1 (only the top level WriteUnitOfWork).
_recoveryUnit->abortUnitOfWork();
// If locks are not yielded, release them.
if (!_lockSnapshot) {
_locker->endWriteUnitOfWork();
}
invariant(!_locker->inAWriteUnitOfWork());
}
}
void TransactionParticipant::TxnResources::release(OperationContext* opCtx) {
// Perform operations that can fail the release before marking the TxnResources as released.
ScopeGuard onError([&] {
// Release any locks acquired as part of lock restoration.
if (_lockSnapshot) {
// WUOW should be released before unlocking.
Locker::WUOWLockSnapshot dummyWUOWLockInfo;
_locker->releaseWriteUnitOfWork(&dummyWUOWLockInfo);
Locker::LockSnapshot dummyLockInfo;
_locker->saveLockStateAndUnlock(&dummyLockInfo);
}
// Release the ticket if acquired.
// restoreWriteUnitOfWorkAndLock() can reacquire the ticket as well.
if (_locker->getClientState() != Locker::ClientState::kInactive) {
_locker->releaseTicket();
}
});
// Restore locks if they are yielded.
if (_lockSnapshot) {
invariant(!_locker->isLocked());
// opCtx is passed in to enable the restoration to be interrupted.
_locker->restoreWriteUnitOfWorkAndLock(opCtx, *_lockSnapshot);
}
_locker->reacquireTicket(opCtx);
if (MONGO_unlikely(restoreLocksFail.shouldFail())) {
uasserted(ErrorCodes::LockTimeout, str::stream() << "Lock restore failed due to failpoint");
}
invariant(!_released);
_released = true;
// Successfully reacquired the locks and tickets.
onError.dismiss();
_lockSnapshot.reset(nullptr);
// It is necessary to lock the client to change the Locker on the OperationContext.
stdx::lock_guard<Client> lk(*opCtx->getClient());
invariant(opCtx->lockState()->getClientState() == Locker::ClientState::kInactive);
// We intentionally do not capture the return value of swapLockState(), which is just an empty
// locker. At the end of the operation, if the transaction is not complete, we will stash the
// operation context's locker and replace it with a new empty locker.
opCtx->swapLockState(std::move(_locker), lk);
opCtx->lockState()->updateThreadIdToCurrentThread();
// Transfer ownership of UncommittedCollections
UncommittedCollections::get(opCtx).receiveResources(_uncommittedCollections);
_uncommittedCollections = nullptr;
// Transfer ownership of UncommittedMultikey
UncommittedMultikey::get(opCtx).receiveResources(_uncommittedMultikey);
_uncommittedMultikey = nullptr;
auto oldState = opCtx->setRecoveryUnit(std::move(_recoveryUnit),
WriteUnitOfWork::RecoveryUnitState::kNotInUnitOfWork);
invariant(oldState == WriteUnitOfWork::RecoveryUnitState::kNotInUnitOfWork,
str::stream() << "RecoveryUnit state was " << oldState);
opCtx->setWriteUnitOfWork(WriteUnitOfWork::createForSnapshotResume(opCtx, _ruState));
auto& apiParameters = APIParameters::get(opCtx);
apiParameters = _apiParameters;
auto& readConcernArgs = repl::ReadConcernArgs::get(opCtx);
readConcernArgs = _readConcernArgs;
}
void TransactionParticipant::TxnResources::setNoEvictionAfterRollback() {
_recoveryUnit->setNoEvictionAfterRollback();
}
TransactionParticipant::SideTransactionBlock::SideTransactionBlock(OperationContext* opCtx)
: _opCtx(opCtx) {
// Do nothing if we are already in a SideTransactionBlock. We can tell we are already in a
// SideTransactionBlock because there is no top level write unit of work.
if (!_opCtx->getWriteUnitOfWork()) {
return;
}
// Release WUOW.
_ruState = opCtx->getWriteUnitOfWork()->release();
opCtx->setWriteUnitOfWork(nullptr);
// Remember the locking state of WUOW, opt out two-phase locking, but don't release locks.
opCtx->lockState()->releaseWriteUnitOfWork(&_WUOWLockSnapshot);
// Release recovery unit, saving the recovery unit off to the side, keeping open the storage
// transaction.
_recoveryUnit = opCtx->releaseAndReplaceRecoveryUnit();
}
TransactionParticipant::SideTransactionBlock::~SideTransactionBlock() {
if (!_recoveryUnit) {
return;
}
// Restore locker's state about WUOW.
_opCtx->lockState()->restoreWriteUnitOfWork(_WUOWLockSnapshot);
// Restore recovery unit.
auto oldState = _opCtx->setRecoveryUnit(std::move(_recoveryUnit),
WriteUnitOfWork::RecoveryUnitState::kNotInUnitOfWork);
invariant(oldState == WriteUnitOfWork::RecoveryUnitState::kNotInUnitOfWork,
str::stream() << "RecoveryUnit state was " << oldState);
// Restore WUOW.
_opCtx->setWriteUnitOfWork(WriteUnitOfWork::createForSnapshotResume(_opCtx, _ruState));
}
void TransactionParticipant::Participant::_stashActiveTransaction(OperationContext* opCtx) {
if (p().inShutdown) {
return;
}
invariant(o().activeTxnNumberAndRetryCounter.getTxnNumber() == opCtx->getTxnNumber());
stdx::lock_guard<Client> lk(*opCtx->getClient());
{
auto tickSource = opCtx->getServiceContext()->getTickSource();
o(lk).transactionMetricsObserver.onStash(ServerTransactionsMetrics::get(opCtx), tickSource);
o(lk).transactionMetricsObserver.onTransactionOperation(
opCtx, CurOp::get(opCtx)->debug().additiveMetrics, o().txnState.isPrepared());
}
invariant(!o().txnResourceStash);
// If this is a prepared transaction, invariant that it does not hold the RSTL lock.
invariant(!o().txnState.isPrepared() || !opCtx->lockState()->isRSTLLocked());
auto stashStyle = opCtx->writesAreReplicated() ? TxnResources::StashStyle::kPrimary
: TxnResources::StashStyle::kSecondary;
o(lk).txnResourceStash = TxnResources(lk, opCtx, stashStyle);
}
void TransactionParticipant::Participant::stashTransactionResources(OperationContext* opCtx) {
if (opCtx->getClient()->isInDirectClient()) {
return;
}
invariant(opCtx->getTxnNumber());
if (o().txnState.isOpen()) {
_stashActiveTransaction(opCtx);
}
}
void TransactionParticipant::Participant::resetRetryableWriteState(OperationContext* opCtx) {
if (opCtx->getClient()->isInDirectClient()) {
return;
}
invariant(opCtx->getTxnNumber());
stdx::lock_guard<Client> lk(*opCtx->getClient());
if (o().txnState.isNone() && p().autoCommit == boost::none) {
_resetRetryableWriteState();
}
}
void TransactionParticipant::Participant::_releaseTransactionResourcesToOpCtx(
OperationContext* opCtx, MaxLockTimeout maxLockTimeout, AcquireTicket acquireTicket) {
// Transaction resources already exist for this transaction. Transfer them from the
// stash to the operation context.
//
// Because TxnResources::release must acquire the Client lock midway through, and because we
// must hold the Client clock to mutate txnResourceStash, we jump through some hoops here to
// move the TxnResources in txnResourceStash into a local variable that can be manipulated
// without holding the Client lock.
auto tempTxnResourceStash = [&]() noexcept {
using std::swap;
boost::optional<TxnResources> trs;
stdx::lock_guard<Client> lk(*opCtx->getClient());
swap(trs, o(lk).txnResourceStash);
return trs;
}
();
ScopeGuard releaseOnError([&] {
// Restore the lock resources back to transaction participant.
using std::swap;
stdx::lock_guard<Client> lk(*opCtx->getClient());
swap(o(lk).txnResourceStash, tempTxnResourceStash);
});
invariant(tempTxnResourceStash);
auto stashLocker = tempTxnResourceStash->locker();
invariant(stashLocker);
if (maxLockTimeout == MaxLockTimeout::kNotAllowed) {
stashLocker->unsetMaxLockTimeout();
} else {
// If maxTransactionLockRequestTimeoutMillis is set, then we will ensure no
// future lock request waits longer than maxTransactionLockRequestTimeoutMillis
// to acquire a lock. This is to avoid deadlocks and minimize non-transaction
// operation performance degradations.
auto maxTransactionLockMillis = gMaxTransactionLockRequestTimeoutMillis.load();
if (maxTransactionLockMillis >= 0) {
stashLocker->setMaxLockTimeout(Milliseconds(maxTransactionLockMillis));
}
}
if (acquireTicket == AcquireTicket::kSkip) {
stashLocker->skipAcquireTicket();
}
tempTxnResourceStash->release(opCtx);
releaseOnError.dismiss();
}
void TransactionParticipant::Participant::unstashTransactionResources(OperationContext* opCtx,
const std::string& cmdName) {
invariant(!opCtx->getClient()->isInDirectClient());
invariant(opCtx->getTxnNumber());
// If this is not a multi-document transaction, there is nothing to unstash.
if (o().txnState.isInRetryableWriteMode()) {
invariant(!o().txnResourceStash);
return;
}
_checkIsCommandValidWithTxnState({*opCtx->getTxnNumber()}, cmdName);
if (o().txnResourceStash) {
MaxLockTimeout maxLockTimeout;
// Default is we should acquire ticket.
AcquireTicket acquireTicket{AcquireTicket::kNoSkip};
if (opCtx->writesAreReplicated()) {
// Primaries should respect the transaction lock timeout, since it can prevent
// the transaction from making progress.
maxLockTimeout = MaxLockTimeout::kAllowed;
// commitTransaction and abortTransaction commands can skip ticketing mechanism as they
// don't acquire any new storage resources (except writing to oplog) but they release
// any claimed storage resources.
// Prepared transactions should not acquire ticket. Else, it can deadlock with other
// non-transactional operations that have exhausted the write tickets and are blocked on
// them due to prepare or lock conflict.
if (o().txnState.isPrepared() || cmdName == "commitTransaction" ||
cmdName == "abortTransaction") {
acquireTicket = AcquireTicket::kSkip;
}
} else {
// Max lock timeout must not be set on secondaries, since secondary oplog application
// cannot fail.
maxLockTimeout = MaxLockTimeout::kNotAllowed;
}
_releaseTransactionResourcesToOpCtx(opCtx, maxLockTimeout, acquireTicket);
stdx::lock_guard<Client> lg(*opCtx->getClient());
o(lg).transactionMetricsObserver.onUnstash(ServerTransactionsMetrics::get(opCtx),
opCtx->getServiceContext()->getTickSource());
return;
}
// If we have no transaction resources then we cannot be prepared. If we're not in progress,
// we don't do anything else.
invariant(!o().txnState.isPrepared());
if (!o().txnState.isInProgress()) {
// At this point we're either committed and this is a 'commitTransaction' command, or we
// are in the process of committing.
return;
}
// All locks of transactions must be acquired inside the global WUOW so that we can
// yield and restore all locks on state transition. Otherwise, we'd have to remember
// which locks are managed by WUOW.
invariant(!opCtx->lockState()->isLocked());
invariant(!opCtx->lockState()->isRSTLLocked());
invariant(!opCtx->lockState()->inAWriteUnitOfWork());
// Stashed transaction resources do not exist for this in-progress multi-document
// transaction. Set up the transaction resources on the opCtx.
opCtx->setWriteUnitOfWork(std::make_unique<WriteUnitOfWork>(opCtx));
// If maxTransactionLockRequestTimeoutMillis is set, then we will ensure no
// future lock request waits longer than maxTransactionLockRequestTimeoutMillis
// to acquire a lock. This is to avoid deadlocks and minimize non-transaction
// operation performance degradations.
auto maxTransactionLockMillis = gMaxTransactionLockRequestTimeoutMillis.load();
if (opCtx->writesAreReplicated() && maxTransactionLockMillis >= 0) {
opCtx->lockState()->setMaxLockTimeout(Milliseconds(maxTransactionLockMillis));
}
// On secondaries, max lock timeout must not be set.
invariant(opCtx->writesAreReplicated() || !opCtx->lockState()->hasMaxLockTimeout());
// Storage engine transactions may be started in a lazy manner. By explicitly
// starting here we ensure that a point-in-time snapshot is established during the
// first operation of a transaction.
//
// Active transactions are protected by the locking subsystem, so we must always hold at least a
// Global intent lock before starting a transaction. We pessimistically acquire an intent
// exclusive lock here because we might be doing writes in this transaction, and it is currently
// not deadlock-safe to upgrade IS to IX.
Lock::GlobalLock globalLock(opCtx, MODE_IX);
// This begins the storage transaction and so we do it after acquiring the global lock.
_setReadSnapshot(opCtx, repl::ReadConcernArgs::get(opCtx));
// The Client lock must not be held when executing this failpoint as it will block currentOp
// execution.
if (MONGO_unlikely(hangAfterPreallocateSnapshot.shouldFail())) {
CurOpFailpointHelpers::waitWhileFailPointEnabled(
&hangAfterPreallocateSnapshot, opCtx, "hangAfterPreallocateSnapshot");
}
{
stdx::lock_guard<Client> lg(*opCtx->getClient());
o(lg).transactionMetricsObserver.onUnstash(ServerTransactionsMetrics::get(opCtx),
opCtx->getServiceContext()->getTickSource());
}
}
void TransactionParticipant::Participant::refreshLocksForPreparedTransaction(
OperationContext* opCtx, bool yieldLocks) {
// The opCtx will be used to swap locks, so it cannot hold any lock.
invariant(!opCtx->lockState()->isRSTLLocked());
invariant(!opCtx->lockState()->isLocked());
// The node must have txn resource.
invariant(o().txnResourceStash);
invariant(o().txnState.isPrepared());
// Lock and Ticket reacquisition of a prepared transaction should not fail for
// state transitions (step up/step down).
_releaseTransactionResourcesToOpCtx(opCtx, MaxLockTimeout::kNotAllowed, AcquireTicket::kNoSkip);
// Snapshot transactions don't conflict with PBWM lock on both primary and secondary.
invariant(!opCtx->lockState()->shouldConflictWithSecondaryBatchApplication());
// Transfer the txn resource back from the operation context to the stash.
auto stashStyle =
yieldLocks ? TxnResources::StashStyle::kSecondary : TxnResources::StashStyle::kPrimary;
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).txnResourceStash = TxnResources(lk, opCtx, stashStyle);
}
Timestamp TransactionParticipant::Participant::prepareTransaction(
OperationContext* opCtx, boost::optional<repl::OpTime> prepareOptime) {
ScopeGuard abortGuard([&] {
// Prepare transaction on secondaries should always succeed.
invariant(!prepareOptime);
try {
// This shouldn't cause deadlocks with other prepared txns, because the acquisition
// of RSTL lock inside abortTransaction will be no-op since we already have it.
// This abortGuard gets dismissed before we release the RSTL while transitioning to
// prepared.
UninterruptibleLockGuard noInterrupt(opCtx->lockState());
abortTransaction(opCtx);
} catch (...) {
// It is illegal for aborting a prepared transaction to fail for any reason, so we crash
// instead.
LOGV2_FATAL_CONTINUE(22525,
"Caught exception during abort of prepared transaction "
"{txnNumber} on {lsid}: {error}",
"Caught exception during abort of prepared transaction",
"txnNumber"_attr = opCtx->getTxnNumber(),
"lsid"_attr = _sessionId().toBSON(),
"error"_attr = exceptionToStatus());
std::terminate();
}
});
auto& completedTransactionOperations = retrieveCompletedTransactionOperations(opCtx);
// Ensure that no transaction operations were done against temporary collections.
// Transactions should not operate on temporary collections because they are for internal use
// only and are deleted on both repl stepup and server startup.
// Create a set of collection UUIDs through which to iterate, so that we do not recheck the same
// collection multiple times: it is a costly check.
stdx::unordered_set<UUID, UUID::Hash> transactionOperationUuids;
for (const auto& transactionOp : completedTransactionOperations) {
transactionOperationUuids.insert(transactionOp.getUuid().get());
}
auto catalog = CollectionCatalog::get(opCtx);
for (const auto& uuid : transactionOperationUuids) {
auto collection = catalog->lookupCollectionByUUID(opCtx, uuid);
uassert(ErrorCodes::OperationNotSupportedInTransaction,
str::stream() << "prepareTransaction failed because one of the transaction "
"operations was done against a temporary collection '"
<< collection->ns() << "'.",
!collection->isTemporary());
}
boost::optional<OplogSlotReserver> oplogSlotReserver;
OplogSlot prepareOplogSlot;
{
stdx::lock_guard<Client> lk(*opCtx->getClient());
// This check is necessary in order to avoid a race where a session with an active (but not
// prepared) transaction is killed, but it still ends up in the prepared state
opCtx->checkForInterrupt();
o(lk).txnState.transitionTo(TransactionState::kPrepared);
}
std::vector<OplogSlot> reservedSlots;
if (prepareOptime) {
// On secondary, we just prepare the transaction and discard the buffered ops.
prepareOplogSlot = OplogSlot(*prepareOptime);
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).prepareOpTime = *prepareOptime;
reservedSlots.push_back(prepareOplogSlot);
} else {
// Even if the prepared transaction contained no statements, we always reserve at least
// 1 oplog slot for the prepare oplog entry.
auto numSlotsToReserve = retrieveCompletedTransactionOperations(opCtx).size();
numSlotsToReserve += p().numberOfPrePostImagesToWrite;
oplogSlotReserver.emplace(opCtx, std::max(1, static_cast<int>(numSlotsToReserve)));
invariant(oplogSlotReserver->getSlots().size() >= 1);
prepareOplogSlot = oplogSlotReserver->getLastSlot();
reservedSlots = oplogSlotReserver->getSlots();
invariant(o().prepareOpTime.isNull(),
str::stream() << "This transaction has already reserved a prepareOpTime at: "
<< o().prepareOpTime.toString());
{
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).prepareOpTime = prepareOplogSlot;
}
if (MONGO_unlikely(hangAfterReservingPrepareTimestamp.shouldFail())) {
// This log output is used in js tests so please leave it.
LOGV2(22521,
"transaction - hangAfterReservingPrepareTimestamp fail point "
"enabled. Blocking until fail point is disabled. Prepare OpTime: "
"{prepareOpTime}",
"prepareOpTime"_attr = prepareOplogSlot);
hangAfterReservingPrepareTimestamp.pauseWhileSet();
}
}
opCtx->recoveryUnit()->setPrepareTimestamp(prepareOplogSlot.getTimestamp());
opCtx->getWriteUnitOfWork()->prepare();
p().needToWriteAbortEntry = true;
opCtx->getServiceContext()->getOpObserver()->onTransactionPrepare(
opCtx, reservedSlots, &completedTransactionOperations, p().numberOfPrePostImagesToWrite);
abortGuard.dismiss();
{
const auto ticks = opCtx->getServiceContext()->getTickSource()->getTicks();
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).transactionMetricsObserver.onPrepare(ServerTransactionsMetrics::get(opCtx), ticks);
// Ensure the lastWriteOpTime is set. This is needed so that we can correctly assign the
// prevOpTime for commit and abort oplog entries if a failover happens after the prepare.
// This value is updated in _registerCacheUpdateOnCommit, but only on primaries. We
// update the lastWriteOpTime here so that it is also available to secondaries. We can
// count on it to persist since we never invalidate prepared transactions.
o(lk).lastWriteOpTime = prepareOplogSlot;
}
if (MONGO_unlikely(hangAfterSettingPrepareStartTime.shouldFail())) {
LOGV2(22522,
"transaction - hangAfterSettingPrepareStartTime fail point enabled. Blocking "
"until fail point is disabled");
hangAfterSettingPrepareStartTime.pauseWhileSet();
}
// We unlock the RSTL to allow prepared transactions to survive state transitions. This should
// be the last thing we do since a state transition may happen immediately after releasing the
// RSTL.
const bool unlocked = opCtx->lockState()->unlockRSTLforPrepare();
invariant(unlocked);
return prepareOplogSlot.getTimestamp();
}
void TransactionParticipant::Participant::setPrepareOpTimeForRecovery(OperationContext* opCtx,
repl::OpTime prepareOpTime) {
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).recoveryPrepareOpTime = prepareOpTime;
}
const repl::OpTime TransactionParticipant::Participant::getPrepareOpTimeForRecovery() const {
return o().recoveryPrepareOpTime;
}
void TransactionParticipant::Participant::addTransactionOperation(
OperationContext* opCtx, const repl::ReplOperation& operation) {
// Ensure that we only ever add operations to an in progress transaction.
if (!o().txnState.isInProgress() && _isInternalSessionForRetryableWrite()) {
// Throw a uassert error instead of an invariant error if this is a retryable internal
// transaction since all write statements are allowed to bypass the checks in
// beginOrContinue if the transaction has already committed.
uasserted(5875606,
"Cannot perform writes in a retryable internal transaction that has already "
"committed, aborted or prepared");
}
invariant(o().txnState.isInProgress(), str::stream() << "Current state: " << o().txnState);
invariant(p().autoCommit && !*p().autoCommit &&
o().activeTxnNumberAndRetryCounter.getTxnNumber() != kUninitializedTxnNumber);
invariant(opCtx->lockState()->inAWriteUnitOfWork());
p().transactionOperations.push_back(operation);
const auto stmtIds = operation.getStatementIds();
for (auto stmtId : stmtIds) {
auto [_, inserted] = p().transactionStmtIds.insert(stmtId);
uassert(5875600,
str::stream() << "Found two operations using the same stmtId of " << stmtId,
inserted);
}
p().transactionOperationBytes +=
repl::DurableOplogEntry::getDurableReplOperationSize(operation);
if (!operation.getPreImage().isEmpty()) {
p().transactionOperationBytes += operation.getPreImage().objsize();
++p().numberOfPrePostImagesToWrite;
}
if (!operation.getPostImage().isEmpty()) {
p().transactionOperationBytes += operation.getPostImage().objsize();
++p().numberOfPrePostImagesToWrite;
}
auto transactionSizeLimitBytes = gTransactionSizeLimitBytes.load();
uassert(ErrorCodes::TransactionTooLarge,
str::stream() << "Total size of all transaction operations must be less than "
<< "server parameter 'transactionSizeLimitBytes' = "
<< transactionSizeLimitBytes,
p().transactionOperationBytes <= static_cast<size_t>(transactionSizeLimitBytes));
}
std::vector<repl::ReplOperation>&
TransactionParticipant::Participant::retrieveCompletedTransactionOperations(
OperationContext* opCtx) {
// Ensure that we only ever retrieve a transaction's completed operations when in progress
// or prepared.
invariant(o().txnState.isInSet(TransactionState::kInProgress | TransactionState::kPrepared),
str::stream() << "Current state: " << o().txnState);
return p().transactionOperations;
}
TxnResponseMetadata TransactionParticipant::Participant::getResponseMetadata() {
// Currently the response metadata only contains a single field, which is whether or not the
// transaction is read-only so far.
return {o().txnState.isInSet(TransactionState::kInProgress) &&
p().transactionOperations.empty()};
}
void TransactionParticipant::Participant::clearOperationsInMemory(OperationContext* opCtx) {
// Ensure that we only ever end a prepared or in-progress transaction.
invariant(o().txnState.isInSet(TransactionState::kPrepared | TransactionState::kInProgress),
str::stream() << "Current state: " << o().txnState);
invariant(p().autoCommit);
p().transactionOperationBytes = 0;
p().transactionOperations.clear();
p().transactionStmtIds.clear();
p().numberOfPrePostImagesToWrite = 0;
}
void TransactionParticipant::Participant::commitUnpreparedTransaction(OperationContext* opCtx) {
uassert(ErrorCodes::InvalidOptions,
"commitTransaction must provide commitTimestamp to prepared transaction.",
!o().txnState.isPrepared());
auto txnOps = retrieveCompletedTransactionOperations(opCtx);
auto opObserver = opCtx->getServiceContext()->getOpObserver();
invariant(opObserver);
opObserver->onUnpreparedTransactionCommit(opCtx, &txnOps, p().numberOfPrePostImagesToWrite);
// Read-only transactions with all read concerns must wait for any data they read to be majority
// committed. For local read concern this is to match majority read concern. For both local and
// majority read concerns we do an untimestamped read, so we have no read timestamp to wait on.
// Instead, we write a noop which is guaranteed to have a greater OpTime than any writes we
// read.
//
// TODO (SERVER-41165): Snapshot read concern should wait on the read timestamp instead.
auto wc = opCtx->getWriteConcern();
auto needsNoopWrite = txnOps.empty() && !opCtx->getWriteConcern().usedDefaultConstructedWC;
const size_t operationCount = p().transactionOperations.size();
const size_t oplogOperationBytes = p().transactionOperationBytes;
clearOperationsInMemory(opCtx);
// _commitStorageTransaction can throw, but it is safe for the exception to be bubbled up to
// the caller, since the transaction can still be safely aborted at this point.
_commitStorageTransaction(opCtx);
_finishCommitTransaction(opCtx, operationCount, oplogOperationBytes);
if (needsNoopWrite) {
performNoopWrite(
opCtx, str::stream() << "read-only transaction with writeConcern " << wc.toBSON());
}
}
void TransactionParticipant::Participant::commitPreparedTransaction(
OperationContext* opCtx,
Timestamp commitTimestamp,
boost::optional<repl::OpTime> commitOplogEntryOpTime) {
// A correctly functioning coordinator could hit this uassert. This could happen if this
// participant shard failed over and the new primary majority committed prepare without this
// node in its majority. The coordinator could legally send commitTransaction with a
// commitTimestamp to this shard but target the old primary (this node) that has yet to prepare
// the transaction. We uassert since this node cannot commit the transaction.
if (!o().txnState.isPrepared()) {
uasserted(ErrorCodes::InvalidOptions,
"commitTransaction cannot provide commitTimestamp to unprepared transaction.");
}
// Re-acquire the RSTL to prevent state transitions while committing the transaction. When the
// transaction was prepared, we dropped the RSTL. We do not need to reacquire the PBWM because
// if we're not the primary we will uassert anyways.
repl::ReplicationStateTransitionLockGuard rstl(opCtx, MODE_IX);
// Prepared transactions cannot hold the RSTL, or else they will deadlock with state
// transitions. If we do not commit the transaction we must unlock the RSTL explicitly so two
// phase locking doesn't hold onto it.
ScopeGuard unlockGuard([&] { invariant(opCtx->lockState()->unlockRSTLforPrepare()); });
const auto replCoord = repl::ReplicationCoordinator::get(opCtx);
if (opCtx->writesAreReplicated()) {
uassert(ErrorCodes::NotWritablePrimary,
"Not primary so we cannot commit a prepared transaction",
replCoord->canAcceptWritesForDatabase(opCtx, "admin"));
}
uassert(
ErrorCodes::InvalidOptions, "'commitTimestamp' cannot be null", !commitTimestamp.isNull());
const auto prepareTimestamp = o().prepareOpTime.getTimestamp();
uassert(ErrorCodes::InvalidOptions,
"'commitTimestamp' must be greater than or equal to 'prepareTimestamp'",
commitTimestamp >= prepareTimestamp);
if (!commitOplogEntryOpTime) {
// A correctly functioning coordinator could hit this uassert. This could happen if this
// participant shard failed over and the new primary majority committed prepare but has yet
// to communicate that to this node. The coordinator could legally send commitTransaction
// with a commitTimestamp to this shard but target the old primary (this node) that does not
// yet know prepare is majority committed. We uassert since the commit oplog entry would be
// written in an old term and be guaranteed to roll back. This makes it easier to write
// correct tests, consider fewer participant commit cases, and catch potential bugs since
// hitting this uassert correctly is unlikely.
uassert(ErrorCodes::InvalidOptions,
"commitTransaction for a prepared transaction cannot be run before its prepare "
"oplog entry has been majority committed",
replCoord->getLastCommittedOpTime().getTimestamp() >= prepareTimestamp ||
MONGO_unlikely(skipCommitTxnCheckPrepareMajorityCommitted.shouldFail()));
}
try {
// We can no longer uassert without terminating.
unlockGuard.dismiss();
// Once entering "committing with prepare" we cannot throw an exception.
UninterruptibleLockGuard noInterrupt(opCtx->lockState());
opCtx->recoveryUnit()->setCommitTimestamp(commitTimestamp);
// On secondary, we generate a fake empty oplog slot, since it's not used by opObserver.
OplogSlot commitOplogSlot;
boost::optional<OplogSlotReserver> oplogSlotReserver;
if (opCtx->writesAreReplicated()) {
invariant(!commitOplogEntryOpTime);
// When this receiving node is not in a readable state, the cluster time gossiping
// protocol is not enabled, thus it is necessary to advance it explicitely,
// so that causal consistency is maintained in these situations.
VectorClockMutable::get(opCtx)->tickClusterTimeTo(LogicalTime(commitTimestamp));
// On primary, we reserve an oplog slot before committing the transaction so that no
// writes that are causally related to the transaction commit enter the oplog at a
// timestamp earlier than the commit oplog entry.
oplogSlotReserver.emplace(opCtx);
commitOplogSlot = oplogSlotReserver->getLastSlot();
invariant(commitOplogSlot.getTimestamp() >= commitTimestamp,
str::stream() << "Commit oplog entry must be greater than or equal to commit "
"timestamp due to causal consistency. commit timestamp: "
<< commitTimestamp.toBSON()
<< ", commit oplog entry optime: " << commitOplogSlot.toBSON());
} else {
// We always expect a non-null commitOplogEntryOpTime to be passed in on secondaries
// in order to set the finishOpTime.
invariant(commitOplogEntryOpTime);
}
// We must have a lastWriteOpTime set, as that will be used for the prevOpTime on the oplog
// entry.
invariant(!o().lastWriteOpTime.isNull());
// If commitOplogEntryOpTime is a nullopt, then we grab the OpTime from the commitOplogSlot
// which will only be set if we are primary. Otherwise, the commitOplogEntryOpTime must have
// been passed in during secondary oplog application.
auto commitOplogSlotOpTime = commitOplogEntryOpTime.value_or(commitOplogSlot);
opCtx->recoveryUnit()->setDurableTimestamp(commitOplogSlotOpTime.getTimestamp());
_commitStorageTransaction(opCtx);
auto opObserver = opCtx->getServiceContext()->getOpObserver();
invariant(opObserver);
// Once the transaction is committed, the oplog entry must be written.
opObserver->onPreparedTransactionCommit(
opCtx, commitOplogSlot, commitTimestamp, retrieveCompletedTransactionOperations(opCtx));
const size_t operationCount = p().transactionOperations.size();
const size_t oplogOperationBytes = p().transactionOperationBytes;
clearOperationsInMemory(opCtx);
_finishCommitTransaction(opCtx, operationCount, oplogOperationBytes);
} catch (...) {
// It is illegal for committing a prepared transaction to fail for any reason, other than an
// invalid command, so we crash instead.
LOGV2_FATAL_CONTINUE(22526,
"Caught exception during commit of prepared transaction {txnNumber} "
"on {lsid}: {error}",
"Caught exception during commit of prepared transaction",
"txnNumber"_attr = opCtx->getTxnNumber(),
"lsid"_attr = _sessionId().toBSON(),
"error"_attr = exceptionToStatus());
std::terminate();
}
}
void TransactionParticipant::Participant::_commitStorageTransaction(OperationContext* opCtx) {
invariant(opCtx->getWriteUnitOfWork());
invariant(opCtx->lockState()->isRSTLLocked());
opCtx->getWriteUnitOfWork()->commit();
opCtx->setWriteUnitOfWork(nullptr);
// We must clear the recovery unit and locker for the 'config.transactions' and oplog entry
// writes.
opCtx->setRecoveryUnit(std::unique_ptr<RecoveryUnit>(
opCtx->getServiceContext()->getStorageEngine()->newRecoveryUnit()),
WriteUnitOfWork::RecoveryUnitState::kNotInUnitOfWork);
opCtx->lockState()->unsetMaxLockTimeout();
}
void TransactionParticipant::Participant::_finishCommitTransaction(
OperationContext* opCtx, size_t operationCount, size_t oplogOperationBytes) noexcept {
{
auto tickSource = opCtx->getServiceContext()->getTickSource();
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).txnState.transitionTo(TransactionState::kCommitted);
o(lk).transactionMetricsObserver.onCommit(opCtx,
ServerTransactionsMetrics::get(opCtx),
tickSource,
&Top::get(opCtx->getServiceContext()),
operationCount,
oplogOperationBytes);
o(lk).transactionMetricsObserver.onTransactionOperation(
opCtx, CurOp::get(opCtx)->debug().additiveMetrics, o().txnState.isPrepared());
}
// We must clear the recovery unit and locker so any post-transaction writes can run without
// transactional settings such as a read timestamp.
_cleanUpTxnResourceOnOpCtx(opCtx, TerminationCause::kCommitted);
}
void TransactionParticipant::Participant::shutdown(OperationContext* opCtx) {
stdx::lock_guard<Client> lock(*opCtx->getClient());
p().inShutdown = true;
o(lock).txnResourceStash = boost::none;
}
APIParameters TransactionParticipant::Participant::getAPIParameters(OperationContext* opCtx) const {
// If we have are in a retryable write, use the API parameters that the client passed in with
// the write, instead of the first write's API parameters.
if (o().txnResourceStash && !o().txnState.isInRetryableWriteMode()) {
return o().txnResourceStash->getAPIParameters();
}
return APIParameters::get(opCtx);
}
void TransactionParticipant::Participant::setLastWriteOpTime(OperationContext* opCtx,
const repl::OpTime& lastWriteOpTime) {
stdx::lock_guard<Client> lg(*opCtx->getClient());
auto& curLastWriteOpTime = o(lg).lastWriteOpTime;
invariant(lastWriteOpTime.isNull() || lastWriteOpTime > curLastWriteOpTime);
curLastWriteOpTime = lastWriteOpTime;
}
bool TransactionParticipant::Observer::expiredAsOf(Date_t when) const {
return o().txnState.isInProgress() && o().transactionExpireDate &&
o().transactionExpireDate < when;
}
void TransactionParticipant::Participant::abortTransaction(OperationContext* opCtx) {
if (_isInternalSessionForRetryableWrite() && o().txnState.isCommitted()) {
// An error occurred while retrying an committed retryable internal transaction should
// not modify the state of the committed transaction.
return;
}
// Normally, absence of a transaction resource stash indicates an inactive transaction.
// However, in the case of a failed "unstash", an active transaction may exist without a stash
// and be killed externally. In that case, the opCtx will not have a transaction number.
if (o().txnResourceStash || !opCtx->getTxnNumber()) {
// Aborting an inactive transaction.
_abortTransactionOnSession(opCtx);
} else if (o().txnState.isPrepared()) {
_abortActivePreparedTransaction(opCtx);
} else {
_abortActiveTransaction(opCtx, TransactionState::kInProgress);
}
}
void TransactionParticipant::Participant::_abortActivePreparedTransaction(OperationContext* opCtx) {
// TODO SERVER-58243: evaluate whether this is safe or whether acquiring the lock can block.
AllowLockAcquisitionOnTimestampedUnitOfWork allowLockAcquisition(opCtx->lockState());
// Re-acquire the RSTL to prevent state transitions while aborting the transaction. Since the
// transaction was prepared, we dropped it on preparing the transaction. We do not need to
// reacquire the PBWM because if we're not the primary we will uassert anyways.
repl::ReplicationStateTransitionLockGuard rstl(opCtx, MODE_IX);
// Prepared transactions cannot hold the RSTL, or else they will deadlock with state
// transitions. If we do not abort the transaction we must unlock the RSTL explicitly so two
// phase locking doesn't hold onto it. Unlocking the RSTL may be a noop if it's already
// unlocked.
ON_BLOCK_EXIT([&] { opCtx->lockState()->unlockRSTLforPrepare(); });
if (opCtx->writesAreReplicated()) {
auto replCoord = repl::ReplicationCoordinator::get(opCtx);
uassert(ErrorCodes::NotWritablePrimary,
"Not primary so we cannot abort a prepared transaction",
replCoord->canAcceptWritesForDatabase(opCtx, "admin"));
}
_abortActiveTransaction(opCtx, TransactionState::kPrepared);
}
void TransactionParticipant::Participant::_abortActiveTransaction(
OperationContext* opCtx, TransactionState::StateSet expectedStates) {
invariant(!o().txnResourceStash);
if (!o().txnState.isInRetryableWriteMode()) {
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).transactionMetricsObserver.onTransactionOperation(
opCtx, CurOp::get(opCtx)->debug().additiveMetrics, o().txnState.isPrepared());
}
auto opObserver = opCtx->getServiceContext()->getOpObserver();
invariant(opObserver);
const bool needToWriteAbortEntry = opCtx->writesAreReplicated() && p().needToWriteAbortEntry;
if (needToWriteAbortEntry) {
// We reserve an oplog slot before aborting the transaction so that no writes that are
// causally related to the transaction abort enter the oplog at a timestamp earlier than the
// abort oplog entry.
OplogSlotReserver oplogSlotReserver(opCtx);
// Clean up the transaction resources on the opCtx even if the transaction resources on the
// session were not aborted. This actually aborts the storage-transaction.
_cleanUpTxnResourceOnOpCtx(opCtx, TerminationCause::kAborted);
try {
// If we need to write an abort oplog entry, this function can no longer be interrupted.
UninterruptibleLockGuard noInterrupt(opCtx->lockState());
// Write the abort oplog entry. This must be done after aborting the storage
// transaction, so that the lock state is reset, and there is no max lock timeout on the
// locker.
opObserver->onTransactionAbort(opCtx, oplogSlotReserver.getLastSlot());
_finishAbortingActiveTransaction(opCtx, expectedStates);
} catch (...) {
// It is illegal for aborting a transaction that must write an abort oplog entry to fail
// after aborting the storage transaction, so we crash instead.
LOGV2_FATAL_CONTINUE(
22527,
"Caught exception during abort of transaction that must write abort oplog "
"entry {txnNumber} on {lsid}: {error}",
"Caught exception during abort of transaction that must write abort oplog "
"entry",
"txnNumber"_attr = opCtx->getTxnNumber(),
"lsid"_attr = _sessionId().toBSON(),
"error"_attr = exceptionToStatus());
std::terminate();
}
} else {
// Clean up the transaction resources on the opCtx even if the transaction resources on the
// session were not aborted. This actually aborts the storage-transaction.
//
// These functions are allowed to throw. We are not writing an oplog entry, so the only risk
// is not cleaning up some internal TransactionParticipant state, updating metrics, or
// logging the end of the transaction. That will either be cleaned up in the
// ServiceEntryPoint's abortGuard or when the next transaction begins.
_cleanUpTxnResourceOnOpCtx(opCtx, TerminationCause::kAborted);
opObserver->onTransactionAbort(opCtx, boost::none);
_finishAbortingActiveTransaction(opCtx, expectedStates);
}
}
void TransactionParticipant::Participant::_finishAbortingActiveTransaction(
OperationContext* opCtx, TransactionState::StateSet expectedStates) {
// Only abort the transaction in session if it's in expected states.
// When the state of active transaction on session is not expected, it means another
// thread has already aborted the transaction on session.
if (o().txnState.isInSet(expectedStates)) {
invariant(opCtx->getTxnNumber() == o().activeTxnNumberAndRetryCounter.getTxnNumber());
_abortTransactionOnSession(opCtx);
} else if (opCtx->getTxnNumber() == o().activeTxnNumberAndRetryCounter.getTxnNumber()) {
if (o().txnState.isInRetryableWriteMode()) {
// The active transaction is not a multi-document transaction.
invariant(opCtx->getWriteUnitOfWork() == nullptr);
return;
}
// Cannot abort these states unless they are specified in expectedStates explicitly.
const auto unabortableStates = TransactionState::kPrepared //
| TransactionState::kCommitted; //
invariant(!o().txnState.isInSet(unabortableStates),
str::stream() << "Cannot abort transaction in " << o().txnState);
} else {
// If _activeTxnNumber is higher than ours, it means the transaction is already aborted.
invariant(o().txnState.isInSet(TransactionState::kNone |
TransactionState::kAbortedWithoutPrepare |
TransactionState::kAbortedWithPrepare |
TransactionState::kExecutedRetryableWrite),
str::stream() << "actual state: " << o().txnState);
}
}
void TransactionParticipant::Participant::_abortTransactionOnSession(OperationContext* opCtx) {
const auto tickSource = opCtx->getServiceContext()->getTickSource();
{
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).transactionMetricsObserver.onAbort(
ServerTransactionsMetrics::get(opCtx->getServiceContext()),
tickSource,
&Top::get(opCtx->getServiceContext()));
}
if (o().txnResourceStash) {
_logSlowTransaction(opCtx,
&(o().txnResourceStash->locker()->getLockerInfo(boost::none))->stats,
TerminationCause::kAborted,
o().txnResourceStash->getAPIParameters(),
o().txnResourceStash->getReadConcernArgs());
}
const auto nextState = o().txnState.isPrepared() ? TransactionState::kAbortedWithPrepare
: TransactionState::kAbortedWithoutPrepare;
stdx::lock_guard<Client> lk(*opCtx->getClient());
if (o().txnResourceStash && opCtx->recoveryUnit()->getNoEvictionAfterRollback()) {
o(lk).txnResourceStash->setNoEvictionAfterRollback();
}
_resetTransactionState(lk, nextState);
}
void TransactionParticipant::Participant::_cleanUpTxnResourceOnOpCtx(
OperationContext* opCtx, TerminationCause terminationCause) {
// Log the transaction if its duration is longer than the slowMS command threshold.
_logSlowTransaction(
opCtx,
&(opCtx->lockState()->getLockerInfo(CurOp::get(*opCtx)->getLockStatsBase()))->stats,
terminationCause,
APIParameters::get(opCtx),
repl::ReadConcernArgs::get(opCtx));
// Reset the WUOW. We should be able to abort empty transactions that don't have WUOW.
if (opCtx->getWriteUnitOfWork()) {
// We could have failed trying to get the initial global lock; in that case we will have a
// WriteUnitOfWork but not have allocated the storage transaction. That is the only case
// where it is legal to abort a unit of work without the RSTL.
invariant(opCtx->lockState()->isRSTLLocked() || !opCtx->recoveryUnit()->isActive());
opCtx->setWriteUnitOfWork(nullptr);
}
// We must clear the recovery unit and locker so any post-transaction writes can run without
// transactional settings such as a read timestamp.
opCtx->setRecoveryUnit(std::unique_ptr<RecoveryUnit>(
opCtx->getServiceContext()->getStorageEngine()->newRecoveryUnit()),
WriteUnitOfWork::RecoveryUnitState::kNotInUnitOfWork);
opCtx->lockState()->unsetMaxLockTimeout();
invariant(UncommittedCollections::get(opCtx).isEmpty());
}
void TransactionParticipant::Participant::_checkIsCommandValidWithTxnState(
const TxnNumberAndRetryCounter& requestTxnNumberAndRetryCounter,
const std::string& cmdName) const {
uassert(ErrorCodes::NoSuchTransaction,
str::stream() << "Transaction with " << requestTxnNumberAndRetryCounter.toBSON()
<< " has been aborted.",
!o().txnState.isAborted());
// Cannot change committed transaction but allow retrying:
// - commitTransaction command.
// - any command if the transaction is an internal transaction for retryable writes.
uassert(ErrorCodes::TransactionCommitted,
str::stream() << "Transaction with " << requestTxnNumberAndRetryCounter.toBSON()
<< " has been committed.",
cmdName == "commitTransaction" || !o().txnState.isCommitted() ||
(_isInternalSessionForRetryableWrite() && o().txnState.isCommitted()));
// Disallow operations other than abort, prepare or commit on a prepared transaction
uassert(ErrorCodes::PreparedTransactionInProgress,
str::stream() << "Cannot call any operation other than abort, prepare or commit on"
<< " a prepared transaction",
!o().txnState.isPrepared() ||
preparedTxnCmdAllowlist.find(cmdName) != preparedTxnCmdAllowlist.cend());
}
BSONObj TransactionParticipant::Observer::reportStashedState(OperationContext* opCtx) const {
BSONObjBuilder builder;
reportStashedState(opCtx, &builder);
return builder.obj();
}
void TransactionParticipant::Observer::reportStashedState(OperationContext* opCtx,
BSONObjBuilder* builder) const {
if (o().txnResourceStash && o().txnResourceStash->locker()) {
if (auto lockerInfo = o().txnResourceStash->locker()->getLockerInfo(boost::none)) {
invariant(o().activeTxnNumberAndRetryCounter.getTxnNumber() != kUninitializedTxnNumber);
builder->append("type", "idleSession");
builder->append("host", getHostNameCachedAndPort());
builder->append("desc", "inactive transaction");
const auto& lastClientInfo =
o().transactionMetricsObserver.getSingleTransactionStats().getLastClientInfo();
builder->append("client", lastClientInfo.clientHostAndPort);
builder->append("connectionId", lastClientInfo.connectionId);
builder->append("appName", lastClientInfo.appName);
builder->append("clientMetadata", lastClientInfo.clientMetadata);
{
BSONObjBuilder lsid(builder->subobjStart("lsid"));
_sessionId().serialize(&lsid);
}
BSONObjBuilder transactionBuilder;
_reportTransactionStats(
opCtx, &transactionBuilder, o().txnResourceStash->getReadConcernArgs());
builder->append("transaction", transactionBuilder.obj());
builder->append("waitingForLock", false);
builder->append("active", false);
fillLockerInfo(*lockerInfo, *builder);
}
}
}
void TransactionParticipant::Observer::reportUnstashedState(OperationContext* opCtx,
BSONObjBuilder* builder) const {
// The Client mutex must be held when calling this function, so it is safe to access the state
// of the TransactionParticipant.
if (!o().txnResourceStash) {
BSONObjBuilder transactionBuilder;
_reportTransactionStats(opCtx, &transactionBuilder, repl::ReadConcernArgs::get(opCtx));
builder->append("transaction", transactionBuilder.obj());
}
}
std::string TransactionParticipant::TransactionState::toString(StateFlag state) {
switch (state) {
case TransactionParticipant::TransactionState::kNone:
return "TxnState::None";
case TransactionParticipant::TransactionState::kInProgress:
return "TxnState::InProgress";
case TransactionParticipant::TransactionState::kPrepared:
return "TxnState::Prepared";
case TransactionParticipant::TransactionState::kCommitted:
return "TxnState::Committed";
case TransactionParticipant::TransactionState::kAbortedWithoutPrepare:
return "TxnState::AbortedWithoutPrepare";
case TransactionParticipant::TransactionState::kAbortedWithPrepare:
return "TxnState::AbortedAfterPrepare";
case TransactionParticipant::TransactionState::kExecutedRetryableWrite:
return "TxnState::ExecutedRetryableWrite";
}
MONGO_UNREACHABLE;
}
bool TransactionParticipant::TransactionState::_isLegalTransition(StateFlag oldState,
StateFlag newState) {
switch (oldState) {
case kNone:
switch (newState) {
case kNone:
case kInProgress:
case kExecutedRetryableWrite:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
case kInProgress:
switch (newState) {
case kNone:
case kPrepared:
case kCommitted:
case kAbortedWithoutPrepare:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
case kPrepared:
switch (newState) {
case kAbortedWithPrepare:
case kCommitted:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
case kCommitted:
switch (newState) {
case kNone:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
case kAbortedWithoutPrepare:
switch (newState) {
case kNone:
case kInProgress:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
case kAbortedWithPrepare:
switch (newState) {
case kNone:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
case kExecutedRetryableWrite:
switch (newState) {
case kNone:
return true;
default:
return false;
}
MONGO_UNREACHABLE;
}
MONGO_UNREACHABLE;
}
void TransactionParticipant::TransactionState::transitionTo(StateFlag newState,
TransitionValidation shouldValidate) {
if (shouldValidate == TransitionValidation::kValidateTransition) {
invariant(TransactionState::_isLegalTransition(_state, newState),
str::stream() << "Current state: " << toString(_state)
<< ", Illegal attempted next state: " << toString(newState));
}
// If we are transitioning out of prepare, signal waiters by fulfilling the completion promise.
if (isPrepared()) {
invariant(_exitPreparePromise);
_exitPreparePromise->emplaceValue();
_exitPreparePromise.reset();
}
_state = newState;
// If we have transitioned into prepare, set the completion promise so other threads can wait
// on the participant to transition out of prepare.
if (isPrepared()) {
invariant(!_exitPreparePromise);
_exitPreparePromise.emplace();
}
}
void TransactionParticipant::Observer::_reportTransactionStats(
OperationContext* opCtx, BSONObjBuilder* builder, repl::ReadConcernArgs readConcernArgs) const {
const auto tickSource = opCtx->getServiceContext()->getTickSource();
o().transactionMetricsObserver.getSingleTransactionStats().report(
builder, readConcernArgs, tickSource, tickSource->getTicks());
}
std::string TransactionParticipant::Participant::_transactionInfoForLog(
OperationContext* opCtx,
const SingleThreadedLockStats* lockStats,
TerminationCause terminationCause,
APIParameters apiParameters,
repl::ReadConcernArgs readConcernArgs) const {
invariant(lockStats);
StringBuilder s;
// User specified transaction parameters.
BSONObjBuilder parametersBuilder;
BSONObjBuilder lsidBuilder(parametersBuilder.subobjStart("lsid"));
_sessionId().serialize(&lsidBuilder);
lsidBuilder.doneFast();
parametersBuilder.append("txnNumber", o().activeTxnNumberAndRetryCounter.getTxnNumber());
parametersBuilder.append("autocommit", p().autoCommit ? *p().autoCommit : true);
apiParameters.appendInfo(¶metersBuilder);
readConcernArgs.appendInfo(¶metersBuilder);
s << "parameters:" << parametersBuilder.obj().toString() << ",";
const auto& singleTransactionStats = o().transactionMetricsObserver.getSingleTransactionStats();
s << " readTimestamp:" << singleTransactionStats.getReadTimestamp().toString() << ",";
s << singleTransactionStats.getOpDebug()->additiveMetrics.report();
std::string terminationCauseString =
terminationCause == TerminationCause::kCommitted ? "committed" : "aborted";
s << " terminationCause:" << terminationCauseString;
auto tickSource = opCtx->getServiceContext()->getTickSource();
auto curTick = tickSource->getTicks();
s << " timeActiveMicros:"
<< durationCount<Microseconds>(
singleTransactionStats.getTimeActiveMicros(tickSource, curTick));
s << " timeInactiveMicros:"
<< durationCount<Microseconds>(
singleTransactionStats.getTimeInactiveMicros(tickSource, curTick));
// Number of yields is always 0 in multi-document transactions, but it is included mainly to
// match the format with other slow operation logging messages.
s << " numYields:" << 0;
// Aggregate lock statistics.
BSONObjBuilder locks;
lockStats->report(&locks);
s << " locks:" << locks.obj().toString();
if (singleTransactionStats.getOpDebug()->storageStats)
s << " storage:" << singleTransactionStats.getOpDebug()->storageStats->toBSON().toString();
// It is possible for a slow transaction to have aborted in the prepared state if an
// exception was thrown before prepareTransaction succeeds.
const auto totalPreparedDuration = durationCount<Microseconds>(
singleTransactionStats.getPreparedDuration(tickSource, curTick));
const bool txnWasPrepared = totalPreparedDuration > 0;
s << " wasPrepared:" << txnWasPrepared;
if (txnWasPrepared) {
s << " totalPreparedDurationMicros:" << totalPreparedDuration;
s << " prepareOpTime:" << o().prepareOpTime.toString();
}
// Total duration of the transaction.
s << ", "
<< duration_cast<Milliseconds>(singleTransactionStats.getDuration(tickSource, curTick));
return s.str();
}
void TransactionParticipant::Participant::_transactionInfoForLog(
OperationContext* opCtx,
const SingleThreadedLockStats* lockStats,
TerminationCause terminationCause,
APIParameters apiParameters,
repl::ReadConcernArgs readConcernArgs,
logv2::DynamicAttributes* pAttrs) const {
invariant(lockStats);
// User specified transaction parameters.
BSONObjBuilder parametersBuilder;
BSONObjBuilder lsidBuilder(parametersBuilder.subobjStart("lsid"));
_sessionId().serialize(&lsidBuilder);
lsidBuilder.doneFast();
parametersBuilder.append("txnNumber", o().activeTxnNumberAndRetryCounter.getTxnNumber());
parametersBuilder.append("autocommit", p().autoCommit ? *p().autoCommit : true);
apiParameters.appendInfo(¶metersBuilder);
readConcernArgs.appendInfo(¶metersBuilder);
pAttrs->add("parameters", parametersBuilder.obj());
const auto& singleTransactionStats = o().transactionMetricsObserver.getSingleTransactionStats();
pAttrs->addDeepCopy("readTimestamp", singleTransactionStats.getReadTimestamp().toString());
singleTransactionStats.getOpDebug()->additiveMetrics.report(pAttrs);
StringData terminationCauseString =
terminationCause == TerminationCause::kCommitted ? "committed" : "aborted";
pAttrs->add("terminationCause", terminationCauseString);
auto tickSource = opCtx->getServiceContext()->getTickSource();
auto curTick = tickSource->getTicks();
pAttrs->add("timeActive", singleTransactionStats.getTimeActiveMicros(tickSource, curTick));
pAttrs->add("timeInactive", singleTransactionStats.getTimeInactiveMicros(tickSource, curTick));
// Number of yields is always 0 in multi-document transactions, but it is included mainly to
// match the format with other slow operation logging messages.
pAttrs->add("numYields", 0);
// Aggregate lock statistics.
BSONObjBuilder locks;
lockStats->report(&locks);
pAttrs->add("locks", locks.obj());
if (singleTransactionStats.getOpDebug()->storageStats)
pAttrs->add("storage", singleTransactionStats.getOpDebug()->storageStats->toBSON());
// It is possible for a slow transaction to have aborted in the prepared state if an
// exception was thrown before prepareTransaction succeeds.
const auto totalPreparedDuration = durationCount<Microseconds>(
singleTransactionStats.getPreparedDuration(tickSource, curTick));
const bool txnWasPrepared = totalPreparedDuration > 0;
pAttrs->add("wasPrepared", txnWasPrepared);
if (txnWasPrepared) {
pAttrs->add("totalPreparedDuration", Microseconds(totalPreparedDuration));
pAttrs->add("prepareOpTime", o().prepareOpTime);
}
// Total duration of the transaction.
pAttrs->add(
"duration",
duration_cast<Milliseconds>(singleTransactionStats.getDuration(tickSource, curTick)));
}
// Needs to be kept in sync with _transactionInfoForLog
BSONObj TransactionParticipant::Participant::_transactionInfoBSONForLog(
OperationContext* opCtx,
const SingleThreadedLockStats* lockStats,
TerminationCause terminationCause,
APIParameters apiParameters,
repl::ReadConcernArgs readConcernArgs) const {
invariant(lockStats);
// User specified transaction parameters.
BSONObjBuilder parametersBuilder;
BSONObjBuilder lsidBuilder(parametersBuilder.subobjStart("lsid"));
_sessionId().serialize(&lsidBuilder);
lsidBuilder.doneFast();
parametersBuilder.append("txnNumber", o().activeTxnNumberAndRetryCounter.getTxnNumber());
parametersBuilder.append("autocommit", p().autoCommit ? *p().autoCommit : true);
apiParameters.appendInfo(¶metersBuilder);
readConcernArgs.appendInfo(¶metersBuilder);
BSONObjBuilder logLine;
{
BSONObjBuilder attrs = logLine.subobjStart("attr");
attrs.append("parameters", parametersBuilder.obj());
const auto& singleTransactionStats =
o().transactionMetricsObserver.getSingleTransactionStats();
attrs.append("readTimestamp", singleTransactionStats.getReadTimestamp().toString());
attrs.appendElements(singleTransactionStats.getOpDebug()->additiveMetrics.reportBSON());
StringData terminationCauseString =
terminationCause == TerminationCause::kCommitted ? "committed" : "aborted";
attrs.append("terminationCause", terminationCauseString);
auto tickSource = opCtx->getServiceContext()->getTickSource();
auto curTick = tickSource->getTicks();
attrs.append("timeActiveMicros",
durationCount<Microseconds>(
singleTransactionStats.getTimeActiveMicros(tickSource, curTick)));
attrs.append("timeInactiveMicros",
durationCount<Microseconds>(
singleTransactionStats.getTimeInactiveMicros(tickSource, curTick)));
// Number of yields is always 0 in multi-document transactions, but it is included mainly to
// match the format with other slow operation logging messages.
attrs.append("numYields", 0);
// Aggregate lock statistics.
BSONObjBuilder locks;
lockStats->report(&locks);
attrs.append("locks", locks.obj());
if (singleTransactionStats.getOpDebug()->storageStats)
attrs.append("storage", singleTransactionStats.getOpDebug()->storageStats->toBSON());
// It is possible for a slow transaction to have aborted in the prepared state if an
// exception was thrown before prepareTransaction succeeds.
const auto totalPreparedDuration = durationCount<Microseconds>(
singleTransactionStats.getPreparedDuration(tickSource, curTick));
const bool txnWasPrepared = totalPreparedDuration > 0;
attrs.append("wasPrepared", txnWasPrepared);
if (txnWasPrepared) {
attrs.append("totalPreparedDurationMicros", totalPreparedDuration);
attrs.append("prepareOpTime", o().prepareOpTime.toBSON());
}
// Total duration of the transaction.
attrs.append(
"durationMillis",
duration_cast<Milliseconds>(singleTransactionStats.getDuration(tickSource, curTick))
.count());
}
return logLine.obj();
}
void TransactionParticipant::Participant::_logSlowTransaction(
OperationContext* opCtx,
const SingleThreadedLockStats* lockStats,
TerminationCause terminationCause,
APIParameters apiParameters,
repl::ReadConcernArgs readConcernArgs) {
// Only log multi-document transactions.
if (!o().txnState.isInRetryableWriteMode()) {
const auto tickSource = opCtx->getServiceContext()->getTickSource();
const auto opDuration = duration_cast<Milliseconds>(
o().transactionMetricsObserver.getSingleTransactionStats().getDuration(
tickSource, tickSource->getTicks()));
if (shouldLogSlowOpWithSampling(opCtx,
logv2::LogComponent::kTransaction,
opDuration,
Milliseconds(serverGlobalParams.slowMS))
.first) {
logv2::DynamicAttributes attr;
_transactionInfoForLog(
opCtx, lockStats, terminationCause, apiParameters, readConcernArgs, &attr);
LOGV2_OPTIONS(51802, {logv2::LogComponent::kTransaction}, "transaction", attr);
}
}
}
void TransactionParticipant::Participant::_setNewTxnNumberAndRetryCounter(
OperationContext* opCtx, const TxnNumberAndRetryCounter& txnNumberAndRetryCounter) {
uassert(ErrorCodes::PreparedTransactionInProgress,
"Cannot change transaction number while the session has a prepared transaction",
!o().txnState.isInSet(TransactionState::kPrepared));
LOGV2_FOR_TRANSACTION(
23984,
4,
"New transaction started with txnNumber: {txnNumberAndRetryCounter} on session with lsid "
"{lsid}",
"New transaction started",
"txnNumberAndRetryCounter"_attr = txnNumberAndRetryCounter,
"lsid"_attr = _sessionId().getId(),
"apiParameters"_attr = APIParameters::get(opCtx).toBSON());
// Abort the existing transaction if it's not prepared, committed, or aborted.
if (o().txnState.isInProgress()) {
_abortTransactionOnSession(opCtx);
}
stdx::lock_guard<Client> lk(*opCtx->getClient());
o(lk).activeTxnNumberAndRetryCounter = txnNumberAndRetryCounter;
o(lk).lastWriteOpTime = repl::OpTime();
// Reset the retryable writes state
_resetRetryableWriteState();
// Reset the transactional state
_resetTransactionState(lk, TransactionState::kNone);
// Reset the transactions metrics
o(lk).transactionMetricsObserver.resetSingleTransactionStats(
txnNumberAndRetryCounter.getTxnNumber());
}
void TransactionParticipant::Participant::refreshFromStorageIfNeeded(OperationContext* opCtx) {
return _refreshFromStorageIfNeeded(opCtx, true);
}
void TransactionParticipant::Participant::refreshFromStorageIfNeededNoOplogEntryFetch(
OperationContext* opCtx) {
return _refreshFromStorageIfNeeded(opCtx, false);
}
void TransactionParticipant::Participant::_refreshFromStorageIfNeeded(OperationContext* opCtx,
bool fetchOplogEntries) {
invariant(!opCtx->getClient()->isInDirectClient());
invariant(!opCtx->lockState()->isLocked());
if (p().isValid)
return;
auto activeTxnHistory = fetchActiveTransactionHistory(opCtx, _sessionId(), fetchOplogEntries);
const auto& lastTxnRecord = activeTxnHistory.lastTxnRecord;
if (lastTxnRecord) {
stdx::lock_guard<Client> lg(*opCtx->getClient());
o(lg).activeTxnNumberAndRetryCounter.setTxnNumber(lastTxnRecord->getTxnNum());
o(lg).activeTxnNumberAndRetryCounter.setTxnRetryCounter([&] {
if (lastTxnRecord->getState()) {
if (feature_flags::gFeatureFlagInternalTransactions.isEnabled(
serverGlobalParams.featureCompatibility)) {
uassert(5875200,
str::stream()
<< "Expected the config.transactions entry for transaction "
<< lastTxnRecord->getTxnNum() << " on session "
<< lastTxnRecord->getSessionId()
<< " to have a 'txnRetryCounter' field",
lastTxnRecord->getTxnRetryCounter().has_value());
return *lastTxnRecord->getTxnRetryCounter();
}
return 0;
}
return kUninitializedTxnRetryCounter;
}());
o(lg).lastWriteOpTime = lastTxnRecord->getLastWriteOpTime();
p().activeTxnCommittedStatements = std::move(activeTxnHistory.committedStatements);
p().hasIncompleteHistory = activeTxnHistory.hasIncompleteHistory;
if (!lastTxnRecord->getState()) {
o(lg).txnState.transitionTo(
TransactionState::kExecutedRetryableWrite,
TransactionState::TransitionValidation::kRelaxTransitionValidation);
} else {
switch (*lastTxnRecord->getState()) {
case DurableTxnStateEnum::kCommitted:
o(lg).txnState.transitionTo(
TransactionState::kCommitted,
TransactionState::TransitionValidation::kRelaxTransitionValidation);
break;
case DurableTxnStateEnum::kAborted:
o(lg).txnState.transitionTo(
TransactionState::kAbortedWithPrepare,
TransactionState::TransitionValidation::kRelaxTransitionValidation);
break;
// We should never be refreshing a prepared or in-progress transaction from
// storage since it should already be in a valid state after replication
// recovery.
case DurableTxnStateEnum::kPrepared:
case DurableTxnStateEnum::kInProgress:
MONGO_UNREACHABLE;
}
}
}
p().isValid = true;
}
void TransactionParticipant::Participant::onWriteOpCompletedOnPrimary(
OperationContext* opCtx,
std::vector<StmtId> stmtIdsWritten,
const SessionTxnRecord& sessionTxnRecord) {
invariant(opCtx->lockState()->inAWriteUnitOfWork());
invariant(sessionTxnRecord.getSessionId() == _sessionId());
invariant(sessionTxnRecord.getTxnNum() == o().activeTxnNumberAndRetryCounter.getTxnNumber());
if (o().txnState.isCommitted()) {
// Only write statements in retryable internal transaction can bypass the checks in
// beginOrContinue and get to here.
invariant(_isInternalSessionForRetryableWrite());
uasserted(5875603,
"Cannot perform writes in a retryable internal transaction that has already "
"committed");
}
// Sanity check that we don't double-execute statements
for (const auto stmtId : stmtIdsWritten) {
const auto stmtOpTime = _checkStatementExecuted(stmtId);
if (stmtOpTime) {
fassertOnRepeatedExecution(_sessionId(),
sessionTxnRecord.getTxnNum(),
stmtId,
*stmtOpTime,
sessionTxnRecord.getLastWriteOpTime());
}
}
const auto updateRequest = _makeUpdateRequest(sessionTxnRecord);
repl::UnreplicatedWritesBlock doNotReplicateWrites(opCtx);
updateSessionEntry(opCtx, updateRequest, _sessionId(), sessionTxnRecord.getTxnNum());
_registerUpdateCacheOnCommit(
opCtx, std::move(stmtIdsWritten), sessionTxnRecord.getLastWriteOpTime());
}
void TransactionParticipant::Participant::onRetryableWriteCloningCompleted(
OperationContext* opCtx,
std::vector<StmtId> stmtIdsWritten,
const SessionTxnRecord& sessionTxnRecord) {
invariant(opCtx->lockState()->inAWriteUnitOfWork());
invariant(sessionTxnRecord.getSessionId() == _sessionId());
invariant(sessionTxnRecord.getTxnNum() == o().activeTxnNumberAndRetryCounter.getTxnNumber());
const auto updateRequest = _makeUpdateRequest(sessionTxnRecord);
repl::UnreplicatedWritesBlock doNotReplicateWrites(opCtx);
updateSessionEntry(opCtx, updateRequest, _sessionId(), sessionTxnRecord.getTxnNum());
_registerUpdateCacheOnCommit(
opCtx, std::move(stmtIdsWritten), sessionTxnRecord.getLastWriteOpTime());
}
void TransactionParticipant::Participant::_invalidate(WithLock wl) {
p().isValid = false;
o(wl).activeTxnNumberAndRetryCounter = {kUninitializedTxnNumber, kUninitializedTxnRetryCounter};
o(wl).lastWriteOpTime = repl::OpTime();
// Reset the transactions metrics.
o(wl).transactionMetricsObserver.resetSingleTransactionStats(
o().activeTxnNumberAndRetryCounter.getTxnNumber());
}
void TransactionParticipant::Participant::_resetRetryableWriteState() {
p().activeTxnCommittedStatements.clear();
p().hasIncompleteHistory = false;
}
void TransactionParticipant::Participant::_resetTransactionState(
WithLock wl, TransactionState::StateFlag state) {
// If we are transitioning to kNone, we are either starting a new transaction or aborting a
// prepared transaction for rollback. In the latter case, we will need to relax the
// invariant that prevents transitioning from kPrepared to kNone.
if (o().txnState.isPrepared() && state == TransactionState::kNone) {
o(wl).txnState.transitionTo(
state, TransactionState::TransitionValidation::kRelaxTransitionValidation);
} else {
o(wl).txnState.transitionTo(state);
}
p().transactionOperationBytes = 0;
p().transactionOperations.clear();
p().transactionStmtIds.clear();
o(wl).prepareOpTime = repl::OpTime();
o(wl).recoveryPrepareOpTime = repl::OpTime();
p().autoCommit = boost::none;
p().needToWriteAbortEntry = false;
// Release any locks held by this participant and abort the storage transaction.
o(wl).txnResourceStash = boost::none;
}
void TransactionParticipant::Participant::invalidate(OperationContext* opCtx) {
stdx::lock_guard<Client> lg(*opCtx->getClient());
uassert(ErrorCodes::PreparedTransactionInProgress,
"Cannot invalidate prepared transaction",
!o().txnState.isInSet(TransactionState::kPrepared));
// Invalidate the session and clear both the retryable writes and transactional states on
// this participant.
_invalidate(lg);
_resetRetryableWriteState();
_resetTransactionState(lg, TransactionState::kNone);
}
boost::optional<repl::OplogEntry> TransactionParticipant::Participant::checkStatementExecuted(
OperationContext* opCtx, StmtId stmtId) const {
const auto stmtTimestamp = _checkStatementExecuted(stmtId);
if (!stmtTimestamp)
return boost::none;
TransactionHistoryIterator txnIter(*stmtTimestamp);
while (txnIter.hasNext()) {
const auto entry = txnIter.next(opCtx);
if (entry.getCommandType() == repl::OplogEntry::CommandType::kApplyOps) {
validateTransactionHistoryApplyOpsOplogEntry(entry);
std::vector<repl::OplogEntry> innerEntries;
repl::ApplyOps::extractOperationsTo(entry, entry.getEntry().toBSON(), &innerEntries);
for (const auto& innerEntry : innerEntries) {
auto stmtIds = innerEntry.getStatementIds();
if (std::find(stmtIds.begin(), stmtIds.end(), stmtId) != stmtIds.end()) {
return innerEntry;
}
}
} else {
auto stmtIds = entry.getStatementIds();
invariant(!stmtIds.empty());
if (std::find(stmtIds.begin(), stmtIds.end(), stmtId) != stmtIds.end()) {
return entry;
}
}
}
MONGO_UNREACHABLE;
}
bool TransactionParticipant::Participant::checkStatementExecutedNoOplogEntryFetch(
StmtId stmtId) const {
return bool(_checkStatementExecuted(stmtId));
}
boost::optional<repl::OpTime> TransactionParticipant::Participant::_checkStatementExecuted(
StmtId stmtId) const {
invariant(p().isValid);
const auto it = p().activeTxnCommittedStatements.find(stmtId);
if (it == p().activeTxnCommittedStatements.end()) {
uassert(ErrorCodes::IncompleteTransactionHistory,
str::stream() << "Incomplete history detected for transaction "
<< o().activeTxnNumberAndRetryCounter.getTxnNumber() << " on session "
<< _sessionId(),
!p().hasIncompleteHistory);
return boost::none;
}
return it->second;
}
UpdateRequest TransactionParticipant::Participant::_makeUpdateRequest(
const SessionTxnRecord& sessionTxnRecord) const {
auto updateRequest = UpdateRequest();
updateRequest.setNamespaceString(NamespaceString::kSessionTransactionsTableNamespace);
updateRequest.setUpdateModification(
write_ops::UpdateModification::parseFromClassicUpdate(sessionTxnRecord.toBSON()));
updateRequest.setQuery(BSON(SessionTxnRecord::kSessionIdFieldName << _sessionId().toBSON()));
updateRequest.setUpsert(true);
return updateRequest;
}
void TransactionParticipant::Participant::setCommittedStmtIdsForTest(
std::vector<int> stmtIdsCommitted) {
p().isValid = true;
for (auto stmtId : stmtIdsCommitted) {
p().activeTxnCommittedStatements.emplace(stmtId, repl::OpTime());
}
}
void TransactionParticipant::Participant::_registerUpdateCacheOnCommit(
OperationContext* opCtx,
std::vector<StmtId> stmtIdsWritten,
const repl::OpTime& lastStmtIdWriteOpTime) {
opCtx->recoveryUnit()->onCommit([opCtx,
stmtIdsWritten = std::move(stmtIdsWritten),
lastStmtIdWriteOpTime](boost::optional<Timestamp>) {
TransactionParticipant::Participant participant(opCtx);
invariant(participant.p().isValid);
RetryableWritesStats::get(opCtx->getServiceContext())
->incrementTransactionsCollectionWriteCount();
stdx::lock_guard<Client> lg(*opCtx->getClient());
// The cache of the last written record must always be advanced after a write so that
// subsequent writes have the correct point to start from.
participant.o(lg).lastWriteOpTime = lastStmtIdWriteOpTime;
for (const auto stmtId : stmtIdsWritten) {
if (stmtId == kIncompleteHistoryStmtId) {
participant.p().hasIncompleteHistory = true;
continue;
}
const auto insertRes =
participant.p().activeTxnCommittedStatements.emplace(stmtId, lastStmtIdWriteOpTime);
if (!insertRes.second) {
const auto& existingOpTime = insertRes.first->second;
fassertOnRepeatedExecution(participant._sessionId(),
participant.o().activeTxnNumberAndRetryCounter,
stmtId,
existingOpTime,
lastStmtIdWriteOpTime);
}
}
// If this is the first time executing a retryable write, we should indicate that to
// the transaction participant.
if (participant.o(lg).txnState.isNone()) {
participant.o(lg).txnState.transitionTo(TransactionState::kExecutedRetryableWrite);
}
});
onPrimaryTransactionalWrite.execute([&](const BSONObj& data) {
const auto closeConnectionElem = data["closeConnection"];
if (closeConnectionElem.eoo() || closeConnectionElem.Bool()) {
opCtx->getClient()->session()->end();
}
const auto failBeforeCommitExceptionElem = data["failBeforeCommitExceptionCode"];
if (!failBeforeCommitExceptionElem.eoo()) {
const auto failureCode = ErrorCodes::Error(int(failBeforeCommitExceptionElem.Number()));
uasserted(failureCode,
str::stream() << "Failing write for " << _sessionId() << ":"
<< o().activeTxnNumberAndRetryCounter.getTxnNumber()
<< " due to failpoint. The write must not be reflected.");
}
});
}
} // namespace mongo
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