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/**
* Copyright (C) 2021-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.
*/
#include "mongo/db/transaction_api.h"
#include <fmt/format.h>
#include "mongo/db/api_parameters.h"
#include "mongo/db/auth/authorization_session.h"
#include "mongo/db/client.h"
#include "mongo/db/commands.h"
#include "mongo/db/commands/txn_cmds_gen.h"
#include "mongo/db/error_labels.h"
#include "mongo/db/internal_session_pool.h"
#include "mongo/db/logical_session_id_helpers.h"
#include "mongo/db/namespace_string.h"
#include "mongo/db/operation_context.h"
#include "mongo/db/operation_time_tracker.h"
#include "mongo/db/ops/write_ops.h"
#include "mongo/db/query/cursor_response.h"
#include "mongo/db/query/getmore_command_gen.h"
#include "mongo/db/repl/read_concern_args.h"
#include "mongo/db/repl/repl_client_info.h"
#include "mongo/db/s/operation_sharding_state.h"
#include "mongo/db/session_catalog.h"
#include "mongo/db/transaction_validation.h"
#include "mongo/db/write_concern_options.h"
#include "mongo/executor/task_executor.h"
#include "mongo/logv2/log.h"
#include "mongo/rpc/factory.h"
#include "mongo/rpc/get_status_from_command_result.h"
#include "mongo/rpc/reply_interface.h"
#include "mongo/stdx/future.h"
#include "mongo/transport/service_entry_point.h"
#include "mongo/util/cancellation.h"
#include "mongo/util/future_util.h"
#define MONGO_LOGV2_DEFAULT_COMPONENT ::mongo::logv2::LogComponent::kTransaction
MONGO_FAIL_POINT_DEFINE(overrideTransactionApiMaxRetriesToThree);
namespace mongo {
const Backoff kExponentialBackoff(Seconds(1), Milliseconds::max());
namespace txn_api {
SyncTransactionWithRetries::SyncTransactionWithRetries(
OperationContext* opCtx,
std::shared_ptr<executor::TaskExecutor> executor,
std::unique_ptr<ResourceYielder> resourceYielder,
std::unique_ptr<TransactionClient> txnClient)
: _resourceYielder(std::move(resourceYielder)),
_txn(std::make_shared<details::TransactionWithRetries>(
opCtx,
executor,
txnClient ? std::move(txnClient)
: std::make_unique<details::SEPTransactionClient>(
opCtx,
executor,
std::make_unique<details::DefaultSEPTransactionClientBehaviors>()))) {
// Callers should always provide a yielder when using the API with a session checked out,
// otherwise commands run by the API won't be able to check out that session.
invariant(!OperationContextSession::get(opCtx) || _resourceYielder);
}
StatusWith<CommitResult> SyncTransactionWithRetries::runNoThrow(OperationContext* opCtx,
Callback callback) noexcept {
// Pre transaction processing, which must happen inline because it uses the caller's opCtx.
auto yieldStatus = _resourceYielder ? _resourceYielder->yieldNoThrow(opCtx) : Status::OK();
if (!yieldStatus.isOK()) {
return yieldStatus;
}
auto txnResult = _txn->run(std::move(callback)).getNoThrow(opCtx);
// Post transaction processing, which must also happen inline.
OperationTimeTracker::get(opCtx)->updateOperationTime(_txn->getOperationTime());
repl::ReplClientInfo::forClient(opCtx->getClient())
.setLastProxyWriteTimestampForward(_txn->getOperationTime().asTimestamp());
auto unyieldStatus = _resourceYielder ? _resourceYielder->unyieldNoThrow(opCtx) : Status::OK();
if (!txnResult.isOK()) {
return txnResult;
} else if (!unyieldStatus.isOK()) {
return unyieldStatus;
}
return txnResult;
}
namespace details {
std::string execContextToString(Transaction::ExecutionContext execContext) {
switch (execContext) {
case Transaction::ExecutionContext::kOwnSession:
return "own session";
case Transaction::ExecutionContext::kClientSession:
return "client session";
case Transaction::ExecutionContext::kClientRetryableWrite:
return "client retryable write";
case Transaction::ExecutionContext::kClientTransaction:
return "client transaction";
}
MONGO_UNREACHABLE;
}
std::string errorHandlingStepToString(Transaction::ErrorHandlingStep nextStep) {
switch (nextStep) {
case Transaction::ErrorHandlingStep::kDoNotRetry:
return "do not retry";
case Transaction::ErrorHandlingStep::kAbortAndDoNotRetry:
return "abort and do not retry";
case Transaction::ErrorHandlingStep::kRetryTransaction:
return "retry transaction";
case Transaction::ErrorHandlingStep::kRetryCommit:
return "retry commit";
}
MONGO_UNREACHABLE;
}
std::string Transaction::_transactionStateToString(TransactionState txnState) const {
switch (txnState) {
case TransactionState::kInit:
return "init";
case TransactionState::kStarted:
return "started";
case TransactionState::kStartedCommit:
return "started commit";
case TransactionState::kRetryingCommit:
return "retrying commit";
case TransactionState::kStartedAbort:
return "started abort";
case TransactionState::kDone:
return "done";
}
MONGO_UNREACHABLE;
}
void logNextStep(Transaction::ErrorHandlingStep nextStep, const BSONObj& txnInfo, int attempts) {
LOGV2(5918600,
"Chose internal transaction error handling step",
"nextStep"_attr = errorHandlingStepToString(nextStep),
"txnInfo"_attr = txnInfo,
"attempts"_attr = attempts);
}
SemiFuture<CommitResult> TransactionWithRetries::run(Callback callback) noexcept {
_internalTxn->setCallback(std::move(callback));
return AsyncTry([this, bodyAttempts = 0]() mutable {
bodyAttempts++;
return _runBodyHandleErrors(bodyAttempts).then([this] {
return _runCommitWithRetries();
});
})
.until([](StatusOrStatusWith<CommitResult> txnStatus) {
// Commit retries should be handled within _runCommitWithRetries().
invariant(txnStatus != ErrorCodes::TransactionAPIMustRetryCommit);
return txnStatus.isOK() || txnStatus != ErrorCodes::TransactionAPIMustRetryTransaction;
})
.withBackoffBetweenIterations(kExponentialBackoff)
// Cancellation happens by interrupting the caller's opCtx.
.on(_executor, CancellationToken::uncancelable())
// Safe to inline because the continuation only holds state.
.unsafeToInlineFuture()
.tapAll([anchor = shared_from_this()](auto&&) {})
.semi();
}
ExecutorFuture<void> TransactionWithRetries::_runBodyHandleErrors(int bodyAttempts) {
return _internalTxn->runCallback().thenRunOn(_executor).onError(
[this, bodyAttempts](Status bodyStatus) {
auto nextStep = _internalTxn->handleError(bodyStatus, bodyAttempts);
logNextStep(nextStep, _internalTxn->reportStateForLog(), bodyAttempts);
if (nextStep == Transaction::ErrorHandlingStep::kDoNotRetry) {
iassert(bodyStatus);
} else if (nextStep == Transaction::ErrorHandlingStep::kAbortAndDoNotRetry) {
return _bestEffortAbort().then([bodyStatus] { return bodyStatus; });
} else if (nextStep == Transaction::ErrorHandlingStep::kRetryTransaction) {
return _bestEffortAbort().then([this, bodyStatus] {
_internalTxn->primeForTransactionRetry();
iassert(Status(ErrorCodes::TransactionAPIMustRetryTransaction,
str::stream() << "Must retry body loop on internal body error: "
<< bodyStatus));
});
}
MONGO_UNREACHABLE;
});
}
ExecutorFuture<CommitResult> TransactionWithRetries::_runCommitHandleErrors(int commitAttempts) {
return _internalTxn->commit().thenRunOn(_executor).onCompletion(
[this, commitAttempts](StatusWith<CommitResult> swCommitResult) {
if (swCommitResult.isOK() && swCommitResult.getValue().getEffectiveStatus().isOK()) {
// Commit succeeded so return to the caller.
return ExecutorFuture<CommitResult>(_executor, swCommitResult);
}
auto nextStep = _internalTxn->handleError(swCommitResult, commitAttempts);
logNextStep(nextStep, _internalTxn->reportStateForLog(), commitAttempts);
if (nextStep == Transaction::ErrorHandlingStep::kDoNotRetry) {
return ExecutorFuture<CommitResult>(_executor, swCommitResult);
} else if (nextStep == Transaction::ErrorHandlingStep::kAbortAndDoNotRetry) {
MONGO_UNREACHABLE;
} else if (nextStep == Transaction::ErrorHandlingStep::kRetryTransaction) {
_internalTxn->primeForTransactionRetry();
iassert(Status(ErrorCodes::TransactionAPIMustRetryTransaction,
str::stream() << "Must retry body loop on commit error: "
<< swCommitResult.getStatus()));
} else if (nextStep == Transaction::ErrorHandlingStep::kRetryCommit) {
_internalTxn->primeForCommitRetry();
iassert(Status(ErrorCodes::TransactionAPIMustRetryCommit,
str::stream() << "Must retry commit loop on internal commit error: "
<< swCommitResult.getStatus()));
}
MONGO_UNREACHABLE;
});
}
ExecutorFuture<CommitResult> TransactionWithRetries::_runCommitWithRetries() {
return AsyncTry([this, commitAttempts = 0]() mutable {
commitAttempts++;
return _runCommitHandleErrors(commitAttempts);
})
.until([](StatusWith<CommitResult> swResult) {
return swResult.isOK() || swResult != ErrorCodes::TransactionAPIMustRetryCommit;
})
.withBackoffBetweenIterations(kExponentialBackoff)
// Cancellation happens by interrupting the caller's opCtx.
.on(_executor, CancellationToken::uncancelable());
}
ExecutorFuture<void> TransactionWithRetries::_bestEffortAbort() {
return _internalTxn->abort().thenRunOn(_executor).onError([this](Status abortStatus) {
LOGV2(5875900,
"Unable to abort internal transaction",
"reason"_attr = abortStatus,
"txnInfo"_attr = _internalTxn->reportStateForLog());
});
}
// Sets the appropriate options on the given client and operation context for running internal
// commands.
void primeInternalClientAndOpCtx(Client* client, OperationContext* opCtx) {
auto as = AuthorizationSession::get(client);
if (as) {
as->grantInternalAuthorization(client);
}
}
Future<DbResponse> DefaultSEPTransactionClientBehaviors::handleRequest(
OperationContext* opCtx, const Message& request) const {
auto serviceEntryPoint = opCtx->getServiceContext()->getServiceEntryPoint();
return serviceEntryPoint->handleRequest(opCtx, request);
}
SemiFuture<BSONObj> SEPTransactionClient::runCommand(StringData dbName, BSONObj cmdObj) const {
invariant(_hooks, "Transaction metadata hooks must be injected before a command can be run");
BSONObjBuilder cmdBuilder(_behaviors->maybeModifyCommand(std::move(cmdObj)));
_hooks->runRequestHook(&cmdBuilder);
invariant(!haveClient());
auto client = _serviceContext->makeClient("SEP-internal-txn-client");
AlternativeClientRegion clientRegion(client);
auto cancellableOpCtx = _cancelableOpCtxFactory->makeOperationContext(&cc());
primeInternalClientAndOpCtx(&cc(), cancellableOpCtx.get());
auto opMsgRequest = OpMsgRequest::fromDBAndBody(dbName, cmdBuilder.obj());
auto requestMessage = opMsgRequest.serialize();
return _behaviors->handleRequest(cancellableOpCtx.get(), requestMessage)
.then([this](DbResponse dbResponse) {
auto reply = rpc::makeReply(&dbResponse.response)->getCommandReply().getOwned();
_hooks->runReplyHook(reply);
return reply;
})
.semi();
}
SemiFuture<BatchedCommandResponse> SEPTransactionClient::runCRUDOp(
const BatchedCommandRequest& cmd, std::vector<StmtId> stmtIds) const {
invariant(!stmtIds.size() || (cmd.sizeWriteOps() == stmtIds.size()),
fmt::format("If stmtIds are specified, they must match the number of write ops. "
"Found {} stmtId(s) and {} write op(s).",
stmtIds.size(),
cmd.sizeWriteOps()));
BSONObjBuilder cmdBob(cmd.toBSON());
if (stmtIds.size()) {
cmdBob.append(write_ops::WriteCommandRequestBase::kStmtIdsFieldName, stmtIds);
}
return runCommand(cmd.getNS().db(), cmdBob.obj())
.thenRunOn(_executor)
.then([](BSONObj reply) {
uassertStatusOK(getStatusFromCommandResult(reply));
BatchedCommandResponse response;
std::string errmsg;
if (!response.parseBSON(reply, &errmsg)) {
uasserted(ErrorCodes::FailedToParse, errmsg);
}
return response;
})
.semi();
}
SemiFuture<std::vector<BSONObj>> SEPTransactionClient::exhaustiveFind(
const FindCommandRequest& cmd) const {
return runCommand(cmd.getDbName(), cmd.toBSON({}))
.thenRunOn(_executor)
.then([this, batchSize = cmd.getBatchSize()](BSONObj reply) {
auto cursorResponse = std::make_shared<CursorResponse>(
uassertStatusOK(CursorResponse::parseFromBSON(reply)));
auto response = std::make_shared<std::vector<BSONObj>>();
return AsyncTry([this,
batchSize = batchSize,
cursorResponse = std::move(cursorResponse),
response]() mutable {
auto releasedBatch = cursorResponse->releaseBatch();
response->insert(
response->end(), releasedBatch.begin(), releasedBatch.end());
// If we've fetched all the documents, we can return the response vector
// wrapped in an OK status.
if (!cursorResponse->getCursorId()) {
return SemiFuture<void>(Status::OK());
}
GetMoreCommandRequest getMoreRequest(
cursorResponse->getCursorId(),
cursorResponse->getNSS().coll().toString());
getMoreRequest.setBatchSize(batchSize);
return runCommand(cursorResponse->getNSS().db(), getMoreRequest.toBSON({}))
.thenRunOn(_executor)
.then([response, cursorResponse](BSONObj reply) {
// We keep the state of cursorResponse to be able to check the
// cursorId in the next iteration.
*cursorResponse =
uassertStatusOK(CursorResponse::parseFromBSON(reply));
uasserted(ErrorCodes::InternalTransactionsExhaustiveFindHasMore,
"More documents to fetch");
})
.semi();
})
.until([&](Status result) {
// We stop execution if there is either no more documents to fetch or there was
// an error upon fetching more documents.
return result != ErrorCodes::InternalTransactionsExhaustiveFindHasMore;
})
.on(_executor, CancellationToken::uncancelable())
.then([response = std::move(response)] { return std::move(*response); });
})
.semi();
}
SemiFuture<CommitResult> Transaction::commit() {
return _commitOrAbort(NamespaceString::kAdminDb, CommitTransaction::kCommandName)
.thenRunOn(_executor)
.then([](BSONObj res) {
auto wcErrorHolder = getWriteConcernErrorDetailFromBSONObj(res);
WriteConcernErrorDetail wcError;
if (wcErrorHolder) {
wcErrorHolder->cloneTo(&wcError);
}
return CommitResult{getStatusFromCommandResult(res), wcError};
})
.semi();
}
SemiFuture<void> Transaction::abort() {
return _commitOrAbort(NamespaceString::kAdminDb, AbortTransaction::kCommandName)
.thenRunOn(_executor)
.then([](BSONObj res) {
uassertStatusOK(getStatusFromCommandResult(res));
uassertStatusOK(getWriteConcernStatusFromCommandResult(res));
})
.semi();
}
SemiFuture<BSONObj> Transaction::_commitOrAbort(StringData dbName, StringData cmdName) {
{
stdx::lock_guard<Latch> lg(_mutex);
if (_state == TransactionState::kInit) {
LOGV2_DEBUG(
5875903,
3,
"Internal transaction skipping commit or abort because no commands were run",
"cmdName"_attr = cmdName,
"txnInfo"_attr = _reportStateForLog(lg));
return BSON("ok" << 1);
}
uassert(5875902,
"Internal transaction not in progress, state: {}"_format(
_transactionStateToString(_state)),
_state == TransactionState::kStarted ||
// Allows retrying commit and the best effort abort after failing to commit.
(_isInCommit() &&
(cmdName == AbortTransaction::kCommandName ||
cmdName == CommitTransaction::kCommandName)));
if (cmdName == CommitTransaction::kCommandName) {
invariant(_state != TransactionState::kStartedAbort);
if (!_isInCommit()) {
// Only transition if we aren't already retrying commit.
_state = TransactionState::kStartedCommit;
}
if (_execContext == ExecutionContext::kClientTransaction) {
// Don't commit if we're nested in a client's transaction.
return SemiFuture<BSONObj>::makeReady(BSON("ok" << 1));
}
} else if (cmdName == AbortTransaction::kCommandName) {
invariant(!_isInCommit());
_state = TransactionState::kStartedAbort;
invariant(_execContext != ExecutionContext::kClientTransaction);
} else {
MONGO_UNREACHABLE;
}
}
BSONObjBuilder cmdBuilder;
cmdBuilder.append(cmdName, 1);
if (_state == TransactionState::kRetryingCommit) {
// Per the drivers transaction spec, retrying commitTransaction uses majority write concern
// to avoid double applying a transaction due to a transient NoSuchTransaction error
// response.
cmdBuilder.append(WriteConcernOptions::kWriteConcernField,
CommandHelpers::kMajorityWriteConcern.toBSON());
} else {
cmdBuilder.append(WriteConcernOptions::kWriteConcernField, _writeConcern);
}
auto cmdObj = cmdBuilder.obj();
return ExecutorFuture<void>(_executor)
.then([this, dbNameCopy = dbName.toString(), cmdObj = std::move(cmdObj)] {
return _txnClient->runCommand(dbNameCopy, cmdObj);
})
// Safe to inline because the continuation only holds state.
.unsafeToInlineFuture()
.tapAll([anchor = shared_from_this()](auto&&) {})
.semi();
}
SemiFuture<void> Transaction::runCallback() {
invariant(_callback);
return ExecutorFuture<void>(_executor)
.then([this] { return _callback(*_txnClient, _executor); })
// Safe to inline because the continuation only holds state.
.unsafeToInlineFuture()
.tapAll([anchor = shared_from_this()](auto&&) {})
.semi();
}
int getMaxRetries() {
// Allow overriding the number of retries so unit tests can exhaust them faster.
return MONGO_unlikely(overrideTransactionApiMaxRetriesToThree.shouldFail()) ? 3
: kTxnRetryLimit;
}
Transaction::ErrorHandlingStep Transaction::handleError(const StatusWith<CommitResult>& swResult,
int attemptCounter) const noexcept {
stdx::lock_guard<Latch> lg(_mutex);
LOGV2_DEBUG(5875905,
3,
"Internal transaction handling error",
"error"_attr = swResult.isOK() ? swResult.getValue().getEffectiveStatus()
: swResult.getStatus(),
"hasTransientTransactionErrorLabel"_attr =
_latestResponseHasTransientTransactionErrorLabel,
"txnInfo"_attr = _reportStateForLog(lg),
"attempts"_attr = attemptCounter);
if (_execContext == ExecutionContext::kClientTransaction) {
// If we're nested in another transaction, let the outer most client decide on errors.
return ErrorHandlingStep::kDoNotRetry;
}
// If the op has a deadline, retry until it is reached regardless of the number of attempts.
if (attemptCounter > getMaxRetries() && !_opDeadline) {
return _isInCommit() ? ErrorHandlingStep::kDoNotRetry
: ErrorHandlingStep::kAbortAndDoNotRetry;
}
// The transient transaction error label is always returned in command responses, even for
// internal clients, so we use it to decide when to retry the transaction instead of inspecting
// error codes. The only exception is when a network error was received before commit, handled
// below.
if (_latestResponseHasTransientTransactionErrorLabel) {
return ErrorHandlingStep::kRetryTransaction;
}
const auto& clientStatus = swResult.getStatus();
if (!clientStatus.isOK()) {
if (ErrorCodes::isNetworkError(clientStatus)) {
// A network error before commit is a transient transaction error, so we can retry the
// entire transaction. If there is a network error after a commit is sent, we can retry
// the commit command to either recommit if the operation failed or get the result of
// the successful commit.
if (_isInCommit()) {
return ErrorHandlingStep::kRetryCommit;
}
return ErrorHandlingStep::kRetryTransaction;
}
return _isInCommit() ? ErrorHandlingStep::kDoNotRetry
: ErrorHandlingStep::kAbortAndDoNotRetry;
}
if (_isInCommit()) {
const auto& commitStatus = swResult.getValue().cmdStatus;
const auto& commitWCStatus = swResult.getValue().wcError.toStatus();
// The retryable write error label is not returned to internal clients, so we cannot rely on
// it and instead use error categories to decide when to retry commit, which is treated as a
// retryable write, per the drivers specification.
if (ErrorCodes::isRetriableError(commitStatus) ||
ErrorCodes::isRetriableError(commitWCStatus)) {
return ErrorHandlingStep::kRetryCommit;
}
return ErrorHandlingStep::kDoNotRetry;
}
return ErrorHandlingStep::kAbortAndDoNotRetry;
}
void Transaction::prepareRequest(BSONObjBuilder* cmdBuilder) {
if (isInternalSessionForRetryableWrite(*_sessionInfo.getSessionId())) {
// Statement ids are meaningful in a transaction spawned on behalf of a retryable write, so
// every write in the transaction should explicitly specify an id. Either a positive number,
// which indicates retry history should be saved for the command, or kUninitializedStmtId
// (aka -1), which indicates retry history should not be saved. If statement ids are not
// explicitly sent, implicit ids may be inferred, which could lead to bugs if different
// commands have the same ids inferred.
dassert(
!isRetryableWriteCommand(
cmdBuilder->asTempObj().firstElement().fieldNameStringData()) ||
(cmdBuilder->hasField(write_ops::WriteCommandRequestBase::kStmtIdsFieldName) ||
cmdBuilder->hasField(write_ops::WriteCommandRequestBase::kStmtIdFieldName)),
str::stream()
<< "In a retryable write transaction every retryable write command should have an "
"explicit statement id, command: "
<< redact(cmdBuilder->asTempObj()));
}
stdx::lock_guard<Latch> lg(_mutex);
_sessionInfo.serialize(cmdBuilder);
if (_state == TransactionState::kInit) {
_state = TransactionState::kStarted;
_sessionInfo.setStartTransaction(boost::none);
cmdBuilder->append(repl::ReadConcernArgs::kReadConcernFieldName, _readConcern);
}
// Append the new recalculated maxTimeMS
if (_opDeadline) {
uassert(5956600,
"Command object passed to the transaction api should not contain maxTimeMS field",
!cmdBuilder->hasField(kMaxTimeMSField));
auto timeLeftover =
std::max(Milliseconds(0), *_opDeadline - _service->getFastClockSource()->now());
cmdBuilder->append(kMaxTimeMSField, durationCount<Milliseconds>(timeLeftover));
}
// If the transaction API caller had API parameters, we should forward them in all requests.
if (_apiParameters.getParamsPassed()) {
_apiParameters.appendInfo(cmdBuilder);
}
_latestResponseHasTransientTransactionErrorLabel = false;
}
void Transaction::processResponse(const BSONObj& reply) {
stdx::lock_guard<Latch> lg(_mutex);
if (auto errorLabels = reply[kErrorLabelsFieldName]) {
for (const auto& label : errorLabels.Array()) {
if (label.String() == ErrorLabel::kTransientTransaction) {
_latestResponseHasTransientTransactionErrorLabel = true;
}
}
}
if (reply.hasField(LogicalTime::kOperationTimeFieldName)) {
_lastOperationTime = LogicalTime::fromOperationTime(reply);
}
}
void Transaction::primeForTransactionRetry() noexcept {
stdx::lock_guard<Latch> lg(_mutex);
_lastOperationTime = LogicalTime();
_latestResponseHasTransientTransactionErrorLabel = false;
switch (_execContext) {
case ExecutionContext::kOwnSession:
case ExecutionContext::kClientSession:
case ExecutionContext::kClientRetryableWrite:
// Advance txnNumber.
_sessionInfo.setTxnNumber(*_sessionInfo.getTxnNumber() + 1);
_sessionInfo.setStartTransaction(true);
_state = TransactionState::kInit;
return;
case ExecutionContext::kClientTransaction:
// The outermost client handles retries, so we should never reach here.
MONGO_UNREACHABLE;
}
}
void Transaction::primeForCommitRetry() noexcept {
stdx::lock_guard<Latch> lg(_mutex);
invariant(_isInCommit());
_latestResponseHasTransientTransactionErrorLabel = false;
_state = TransactionState::kRetryingCommit;
}
BSONObj Transaction::reportStateForLog() const {
stdx::lock_guard<Latch> lg(_mutex);
return _reportStateForLog(lg);
}
BSONObj Transaction::_reportStateForLog(WithLock) const {
return BSON("execContext" << execContextToString(_execContext) << "sessionInfo"
<< _sessionInfo.toBSON() << "state"
<< _transactionStateToString(_state));
}
void Transaction::_setSessionInfo(WithLock,
LogicalSessionId lsid,
TxnNumber txnNumber,
boost::optional<bool> startTransaction) {
_sessionInfo.setSessionId(lsid);
_sessionInfo.setTxnNumber(txnNumber);
if (startTransaction) {
invariant(startTransaction == boost::optional<bool>(true));
}
_sessionInfo.setStartTransaction(startTransaction);
}
void Transaction::_primeTransaction(OperationContext* opCtx) {
// The API does not forward shard or database versions from the caller's opCtx, so spawned
// commands would not obey sharding protocols, like the migration critical section, so it
// cannot currently be used in an operation with shard versions. This does not apply in the
// cluster commands configuration because those commands will attach appropriate shard
// versions.
uassert(6638800,
"Transaction API does not currently support use within operations with shard or "
"database versions without using router commands",
!OperationShardingState::isComingFromRouter(opCtx) ||
_txnClient->canRunInShardedOperations());
stdx::lock_guard<Latch> lg(_mutex);
// Extract session options and infer execution context from client's opCtx.
auto clientSession = opCtx->getLogicalSessionId();
auto clientTxnNumber = opCtx->getTxnNumber();
auto clientInMultiDocumentTransaction = opCtx->inMultiDocumentTransaction();
if (!clientSession) {
const auto acquiredSession =
InternalSessionPool::get(opCtx)->acquireStandaloneSession(opCtx);
_acquiredSessionFromPool = true;
_setSessionInfo(lg,
acquiredSession.getSessionId(),
acquiredSession.getTxnNumber(),
{true} /* startTransaction */);
_execContext = ExecutionContext::kOwnSession;
} else if (!clientTxnNumber) {
const auto acquiredSession =
InternalSessionPool::get(opCtx)->acquireChildSession(opCtx, *clientSession);
_acquiredSessionFromPool = true;
_setSessionInfo(lg,
acquiredSession.getSessionId(),
acquiredSession.getTxnNumber(),
{true} /* startTransaction */);
_execContext = ExecutionContext::kClientSession;
} else if (!clientInMultiDocumentTransaction) {
_setSessionInfo(lg,
makeLogicalSessionIdWithTxnNumberAndUUID(*clientSession, *clientTxnNumber),
0 /* txnNumber */,
{true} /* startTransaction */);
_execContext = ExecutionContext::kClientRetryableWrite;
} else {
// Note that we don't want to include startTransaction or any first transaction command
// fields because we assume that if we're in a client transaction the component tracking
// transactions on the process must have already been started (e.g. TransactionRouter or
// TransactionParticipant), so when the API sends commands for this transacion that
// component will attach the correct fields if targeting new participants. This assumes this
// case always uses a client that runs commands against the local process service entry
// point, which we verify with this invariant.
invariant(_txnClient->supportsClientTransactionContext());
_setSessionInfo(lg, *clientSession, *clientTxnNumber, boost::none /* startTransaction */);
_execContext = ExecutionContext::kClientTransaction;
// Skip directly to the started state since we assume the client already started this
// transaction.
_state = TransactionState::kStarted;
}
_sessionInfo.setAutocommit(false);
// Extract non-session options. Strip provenance so it can be correctly inferred for the
// generated commands as if it came from an external client.
_readConcern = repl::ReadConcernArgs::get(opCtx).toBSONInner().removeField(
ReadWriteConcernProvenanceBase::kSourceFieldName);
_writeConcern = opCtx->getWriteConcern().toBSON().removeField(
ReadWriteConcernProvenanceBase::kSourceFieldName);
_apiParameters = APIParameters::get(opCtx);
if (opCtx->hasDeadline()) {
_opDeadline = opCtx->getDeadline();
}
LOGV2_DEBUG(5875901,
3,
"Started internal transaction",
"sessionInfo"_attr = _sessionInfo,
"readConcern"_attr = _readConcern,
"writeConcern"_attr = _writeConcern,
"APIParameters"_attr = _apiParameters,
"execContext"_attr = execContextToString(_execContext));
}
LogicalTime Transaction::getOperationTime() const {
stdx::lock_guard<Latch> lg(_mutex);
return _lastOperationTime;
}
Transaction::~Transaction() {
if (_acquiredSessionFromPool) {
InternalSessionPool::get(_service)->release(
{*_sessionInfo.getSessionId(), *_sessionInfo.getTxnNumber()});
_acquiredSessionFromPool = false;
}
}
} // namespace details
} // namespace txn_api
} // namespace mongo
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