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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 LOGV2_FOR_ELECTION(ID, DLEVEL, MESSAGE, ...) \
LOGV2_DEBUG_OPTIONS( \
ID, DLEVEL, {logv2::LogComponent::kReplicationElection}, MESSAGE, ##__VA_ARGS__)
#define LOGV2_FOR_HEARTBEATS(ID, DLEVEL, MESSAGE, ...) \
LOGV2_DEBUG_OPTIONS( \
ID, DLEVEL, {logv2::LogComponent::kReplicationHeartbeats}, MESSAGE, ##__VA_ARGS__)
#include "mongo/db/repl/topology_coordinator.h"
#include "mongo/db/repl/topology_coordinator_gen.h"
#include <fmt/format.h>
#include <fmt/ostream.h>
#include <limits>
#include <string>
#include "mongo/bson/simple_bsonobj_comparator.h"
#include "mongo/db/audit.h"
#include "mongo/db/catalog/commit_quorum_options.h"
#include "mongo/db/client.h"
#include "mongo/db/commands/server_status_metric.h"
#include "mongo/db/mongod_options.h"
#include "mongo/db/operation_context.h"
#include "mongo/db/repl/heartbeat_response_action.h"
#include "mongo/db/repl/isself.h"
#include "mongo/db/repl/member_data.h"
#include "mongo/db/repl/repl_server_parameters_gen.h"
#include "mongo/logv2/log.h"
#include "mongo/rpc/metadata/oplog_query_metadata.h"
#include "mongo/rpc/metadata/repl_set_metadata.h"
#include "mongo/util/assert_util.h"
#include "mongo/util/fail_point.h"
#include "mongo/util/hex.h"
#include "mongo/util/scopeguard.h"
#include "mongo/util/str.h"
#define MONGO_LOGV2_DEFAULT_COMPONENT ::mongo::logv2::LogComponent::kReplication
namespace mongo {
namespace repl {
MONGO_FAIL_POINT_DEFINE(forceSyncSourceCandidate);
MONGO_FAIL_POINT_DEFINE(voteNoInElection);
MONGO_FAIL_POINT_DEFINE(voteYesInDryRunButNoInRealElection);
// If this fail point is enabled, TopologyCoordinator::shouldChangeSyncSource() will ignore
// the option TopologyCoordinator::Options::maxSyncSourceLagSecs. The sync source will not be
// re-evaluated if it lags behind another node by more than 'maxSyncSourceLagSecs' seconds.
MONGO_FAIL_POINT_DEFINE(disableMaxSyncSourceLagSecs);
constexpr Milliseconds TopologyCoordinator::PingStats::UninitializedPingTime;
// Tracks the number of times we decide to change sync sources in order to sync from a significantly
// closer node.
CounterMetric numSyncSourceChangesDueToSignificantlyCloserNode(
"repl.syncSource.numSyncSourceChangesDueToSignificantlyCloserNode");
using namespace fmt::literals;
std::string TopologyCoordinator::roleToString(TopologyCoordinator::Role role) {
switch (role) {
case TopologyCoordinator::Role::kLeader:
return "leader";
case TopologyCoordinator::Role::kFollower:
return "follower";
case TopologyCoordinator::Role::kCandidate:
return "candidate";
}
MONGO_UNREACHABLE;
}
TopologyCoordinator::~TopologyCoordinator() {}
std::ostream& operator<<(std::ostream& os, TopologyCoordinator::Role role) {
return os << TopologyCoordinator::roleToString(role);
}
std::ostream& operator<<(std::ostream& os,
TopologyCoordinator::PrepareFreezeResponseResult result) {
switch (result) {
case TopologyCoordinator::PrepareFreezeResponseResult::kNoAction:
return os << "no action";
case TopologyCoordinator::PrepareFreezeResponseResult::kSingleNodeSelfElect:
return os << "single node self elect";
}
MONGO_UNREACHABLE;
}
namespace {
template <typename T>
int indexOfIterator(const std::vector<T>& vec, typename std::vector<T>::const_iterator& it) {
return static_cast<int>(it - vec.begin());
}
/**
* Returns true if the only up heartbeats are auth errors.
*/
bool _hasOnlyAuthErrorUpHeartbeats(const std::vector<MemberData>& hbdata, const int selfIndex) {
bool foundAuthError = false;
for (std::vector<MemberData>::const_iterator it = hbdata.begin(); it != hbdata.end(); ++it) {
if (indexOfIterator(hbdata, it) == selfIndex) {
continue;
}
if (it->up()) {
return false;
}
if (it->hasAuthIssue()) {
foundAuthError = true;
}
}
return foundAuthError;
}
void appendOpTime(BSONObjBuilder* bob, const char* elemName, const OpTime& opTime) {
opTime.append(bob, elemName);
}
} // namespace
void TopologyCoordinator::PingStats::start(Date_t now) {
_lastHeartbeatStartDate = now;
_numFailuresSinceLastStart = 0;
_state = HeartbeatState::TRYING;
}
void TopologyCoordinator::PingStats::hit(Milliseconds millis) {
_state = HeartbeatState::SUCCEEDED;
++hitCount;
averagePingTimeMs = averagePingTimeMs == UninitializedPingTime
? millis
: Milliseconds((averagePingTimeMs * 4 + millis) / 5);
}
void TopologyCoordinator::PingStats::set_forTest(Milliseconds millis) {
_state = HeartbeatState::SUCCEEDED;
averagePingTimeMs = millis;
}
void TopologyCoordinator::PingStats::miss() {
++_numFailuresSinceLastStart;
// Transition to 'FAILED' state if this was our last retry.
if (_numFailuresSinceLastStart > kMaxHeartbeatRetries) {
_state = PingStats::HeartbeatState::FAILED;
}
}
bool TopologyCoordinator::RecentSyncSourceChanges::changedTooOftenRecently(Date_t now) {
size_t maxSize = maxNumSyncSourceChangesPerHour.load();
// Return false if we have fewer than maxNumSyncSourceChangesPerHour entries.
if (_recentChanges.empty() || _recentChanges.size() < maxSize) {
return false;
}
// Remove additional entries in case maxNumSyncSourceChangesPerHour was changed.
while (_recentChanges.size() > maxSize) {
_recentChanges.pop();
}
// Return whether all entries in the queue happened within the last hour by checking the oldest
// entry.
auto hourBefore = now - Hours(1);
return _recentChanges.front() > hourBefore;
}
void TopologyCoordinator::RecentSyncSourceChanges::addNewEntry(Date_t now) {
// Remove additional entries if the queue already has maxNumSyncSourceChangerPerHour entries.
while (_recentChanges.size() >= static_cast<size_t>(maxNumSyncSourceChangesPerHour.load())) {
_recentChanges.pop();
}
_recentChanges.push(now);
return;
}
std::queue<Date_t> TopologyCoordinator::RecentSyncSourceChanges::getChanges_forTest() {
return _recentChanges;
}
TopologyCoordinator::TopologyCoordinator(Options options)
: _role(Role::kFollower),
_topologyVersion(instanceId, 0),
_term(OpTime::kUninitializedTerm),
_currentPrimaryIndex(-1),
_forceSyncSourceIndex(-1),
_replSetSyncFromSet(false),
_options(std::move(options)),
_selfIndex(-1),
_maintenanceModeCalls(0),
_followerMode(MemberState::RS_STARTUP2) {
invariant(getMemberState() == MemberState::RS_STARTUP);
// Need an entry for self in the memberHearbeatData.
_memberData.emplace_back();
_memberData.back().setIsSelf(true);
}
TopologyCoordinator::Role TopologyCoordinator::getRole() const {
return _role;
}
TopologyVersion TopologyCoordinator::getTopologyVersion() const {
return _topologyVersion;
}
void TopologyCoordinator::setForceSyncSourceIndex(int index) {
invariant(_forceSyncSourceIndex < _rsConfig.getNumMembers());
_forceSyncSourceIndex = index;
}
HostAndPort TopologyCoordinator::getSyncSourceAddress() const {
return _syncSource;
}
void TopologyCoordinator::_clearSyncSource() {
_syncSource = HostAndPort();
_replSetSyncFromSet = false;
}
void TopologyCoordinator::_setSyncSource(HostAndPort newSyncSource,
Date_t now,
bool fromReplSetSyncFrom) {
_syncSource = newSyncSource;
_replSetSyncFromSet = fromReplSetSyncFrom;
// If we chose another node rather than clearing the sync source, update the recent sync source
// changes.
if (!_syncSource.empty()) {
_recentSyncSourceChanges.addNewEntry(now);
}
}
HostAndPort TopologyCoordinator::chooseNewSyncSource(Date_t now,
const OpTime& lastOpTimeFetched,
ReadPreference readPreference) {
// Check to see if we should choose a sync source because the 'replSetSyncFrom' command was set.
auto maybeSyncSource = _chooseSyncSourceReplSetSyncFrom(now);
if (maybeSyncSource) {
// If we have a forced sync source via 'replSetSyncFrom', set the _replSetSyncFromSet flag
// to true.
_setSyncSource(*maybeSyncSource, now, true /* fromReplSetSyncFrom */);
return _syncSource;
}
// Check to make sure we can choose a sync source, and choose one if the
// 'forceSyncSourceCandidate' failpoint is set.
maybeSyncSource = _chooseSyncSourceInitialChecks(now);
if (maybeSyncSource) {
_setSyncSource(*maybeSyncSource, now);
return _syncSource;
}
// If we are only allowed to sync from the primary, use it as the sync source if possible.
if (readPreference == ReadPreference::PrimaryOnly) {
_setSyncSource(_choosePrimaryAsSyncSource(now, lastOpTimeFetched), now);
if (_syncSource.empty()) {
LOGV2_DEBUG(3873104,
1,
"Cannot select a sync source because the primary is not a valid sync "
"source and the sync source read preference is 'primary'.");
}
return _syncSource;
} else if (readPreference == ReadPreference::PrimaryPreferred) {
// If we prefer the primary, try it first.
_setSyncSource(_choosePrimaryAsSyncSource(now, lastOpTimeFetched), now);
if (!_syncSource.empty()) {
return _syncSource;
}
}
_setSyncSource(_chooseNearbySyncSource(now, lastOpTimeFetched, readPreference), now);
return _syncSource;
}
HostAndPort TopologyCoordinator::_chooseNearbySyncSource(Date_t now,
const OpTime& lastOpTimeFetched,
ReadPreference readPreference) {
// We should have handled PrimaryOnly before calling this.
invariant(readPreference != ReadPreference::PrimaryOnly);
// find the member with the lowest ping time that is ahead of me
int closestIndex = -1;
// Make two attempts, with less restrictive rules the second time.
//
// During the first attempt, we ignore those nodes that have a larger secondary
// delay, hidden nodes or non-voting, and nodes that are excessively behind.
//
// For the second attempt include those nodes, in case those are the only ones we can reach.
//
// This loop attempts to set 'closestIndex', to select a viable candidate.
for (int attempts = 0; attempts < 2; ++attempts) {
for (size_t candidateIndex = 0; candidateIndex < _memberData.size(); candidateIndex++) {
if (!_isEligibleSyncSource(candidateIndex,
now,
lastOpTimeFetched,
readPreference,
attempts == 0 /* firstAttempt */,
true /* shouldCheckStaleness */)) {
// Node is not a viable sync source candidate.
continue;
}
// Set 'closestIndex' if this node is the first viable candidate we have encountered.
if (closestIndex == -1) {
closestIndex = candidateIndex;
continue;
}
const auto syncSourceCandidate = _rsConfig.getMemberAt(candidateIndex).getHostAndPort();
const auto closestNode = _rsConfig.getMemberAt(closestIndex).getHostAndPort();
// Do not update 'closestIndex' if the candidate is not the closest node we've seen.
auto syncSourceCandidatePing = _getPing(syncSourceCandidate);
auto closestPing = _getPing(closestNode);
if (syncSourceCandidatePing > closestPing) {
LOGV2_DEBUG(3873114,
2,
"Cannot select sync source with higher latency than the best "
"candidate",
"syncSourceCandidate"_attr = syncSourceCandidate,
"syncSourceCandidatePing"_attr = syncSourceCandidatePing,
"closestNode"_attr = closestNode,
"closestPing"_attr = closestPing);
continue;
}
closestIndex = candidateIndex;
}
if (closestIndex != -1)
break; // no need for second attempt
}
if (closestIndex == -1) {
// Did not find any members to sync from
// Only log when we had a valid sync source before
static constexpr char message[] = "Could not find member to sync from";
if (!_syncSource.empty()) {
LOGV2(21798, message);
}
setMyHeartbeatMessage(now, message);
return HostAndPort();
}
auto syncSource = _rsConfig.getMemberAt(closestIndex).getHostAndPort();
LOGV2(21799, "Sync source candidate chosen", "syncSource"_attr = syncSource);
std::string msg(str::stream() << "syncing from: " << syncSource.toString(), 0);
setMyHeartbeatMessage(now, msg);
return syncSource;
}
OpTime TopologyCoordinator::_getOldestSyncOpTime() const {
OpTime oldestSyncOpTime = OpTime();
// Find primary's oplog time. We will reject sync candidates that are more than
// _options.maxSyncSourceLagSecs seconds behind this optime.
if (_currentPrimaryIndex != -1) {
OpTime primaryOpTime = _memberData.at(_currentPrimaryIndex).getHeartbeatAppliedOpTime();
// Check if primaryOpTime is still close to 0 because we haven't received
// our first heartbeat from a new primary yet.
auto maxLag =
static_cast<unsigned int>(durationCount<Seconds>(_options.maxSyncSourceLagSecs));
if (primaryOpTime.getSecs() >= maxLag) {
oldestSyncOpTime =
OpTime(Timestamp(primaryOpTime.getSecs() - maxLag, 0), primaryOpTime.getTerm());
}
}
return oldestSyncOpTime;
}
bool TopologyCoordinator::_isEligibleSyncSource(int candidateIndex,
Date_t now,
const OpTime& lastOpTimeFetched,
ReadPreference readPreference,
const bool firstAttempt,
const bool shouldCheckStaleness) const {
// Don't consider ourselves.
if (candidateIndex == _selfIndex) {
return false;
}
const MemberConfig& memberConfig(_rsConfig.getMemberAt(candidateIndex));
const auto syncSourceCandidate = memberConfig.getHostAndPort();
const auto memberData = _memberData[candidateIndex];
// Candidate must be up to be considered.
if (!memberData.up()) {
LOGV2_DEBUG(3873106,
2,
"Cannot select sync source because it is not up",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
// Candidate must be PRIMARY or SECONDARY state to be considered.
if (!memberData.getState().readable()) {
LOGV2_DEBUG(3873107,
2,
"Cannot select sync source because it is not readable",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
// Disallow the primary for first or all attempts depending on the readPreference.
if (readPreference == ReadPreference::SecondaryOnly ||
(readPreference == ReadPreference::SecondaryPreferred && firstAttempt)) {
if (memberData.getState().primary()) {
LOGV2_DEBUG(3873101,
2,
"Cannot select sync source because it is a primary and we are "
"looking for a secondary",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
}
// On the first attempt, we skip candidates that do not match these criteria.
if (firstAttempt) {
// Candidate must be a voter if we are a voter.
if (_selfConfig().isVoter() && !memberConfig.isVoter()) {
LOGV2_DEBUG(3873108,
2,
"Cannot select sync source because we are a voter and it is not",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
// Candidates must not be hidden.
if (memberConfig.isHidden()) {
LOGV2_DEBUG(3873109,
2,
"Cannot select sync source because it is hidden",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
// Candidates cannot be excessively behind, if we are checking for staleness.
if (shouldCheckStaleness) {
const auto oldestSyncOpTime = _getOldestSyncOpTime();
if (memberData.getHeartbeatAppliedOpTime() < oldestSyncOpTime) {
LOGV2_DEBUG(3873110,
2,
"Cannot select sync source because it is too far behind",
"syncSourceCandidate"_attr = syncSourceCandidate,
"syncSourceCandidateOpTime"_attr =
memberData.getHeartbeatAppliedOpTime(),
"oldestAcceptableOpTime"_attr = oldestSyncOpTime);
return false;
}
}
// Candidate must not have a configured delay larger than ours.
if (_selfConfig().getSecondaryDelay() < memberConfig.getSecondaryDelay()) {
LOGV2_DEBUG(3873111,
2,
"Cannot select sync source with larger secondaryDelaySecs than ours",
"syncSourceCandidate"_attr = syncSourceCandidate,
"syncSourceCandidateSecondaryDelaySecs"_attr =
memberConfig.getSecondaryDelay(),
"secondaryDelaySecs"_attr = _selfConfig().getSecondaryDelay());
return false;
}
}
// Candidate must build indexes if we build indexes, to be considered.
if (_selfConfig().shouldBuildIndexes()) {
if (!memberConfig.shouldBuildIndexes()) {
LOGV2_DEBUG(3873112,
2,
"Cannot select sync source which does not build indexes when we do",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
}
// Only select a candidate that is ahead of me, if we are checking for staleness.
if (shouldCheckStaleness && memberData.getHeartbeatAppliedOpTime() <= lastOpTimeFetched) {
LOGV2_DEBUG(3873113,
1,
"Cannot select sync source which is not ahead of me",
"syncSourceCandidate"_attr = syncSourceCandidate,
"syncSourceCandidateLastAppliedOpTime"_attr =
memberData.getHeartbeatAppliedOpTime().toBSON(),
"lastOpTimeFetched"_attr = lastOpTimeFetched.toBSON());
return false;
}
// Candidate cannot be denylisted.
if (_memberIsDenylisted(memberConfig, now)) {
LOGV2_DEBUG(3873115,
1,
"Cannot select sync source which is denylisted",
"syncSourceCandidate"_attr = syncSourceCandidate);
return false;
}
// This candidate has passed all tests.
return true;
}
boost::optional<HostAndPort> TopologyCoordinator::_chooseSyncSourceReplSetSyncFrom(Date_t now) {
if (_selfIndex == -1) {
return boost::none;
}
if (_forceSyncSourceIndex == -1) {
return boost::none;
}
// If we have a target we've requested to sync from, use it.
invariant(_forceSyncSourceIndex < _rsConfig.getNumMembers());
auto syncSource = _rsConfig.getMemberAt(_forceSyncSourceIndex).getHostAndPort();
_forceSyncSourceIndex = -1;
LOGV2(21782, "Choosing sync source candidate by request", "syncSource"_attr = syncSource);
std::string msg(str::stream() << "syncing from: " << syncSource.toString() << " by request");
setMyHeartbeatMessage(now, msg);
return syncSource;
}
boost::optional<HostAndPort> TopologyCoordinator::_chooseSyncSourceInitialChecks(Date_t now) {
// If we are not a member of the current replica set configuration, no sync source is valid.
if (_selfIndex == -1) {
LOGV2_DEBUG(
21778, 1, "Cannot sync from any members because we are not in the replica set config");
return HostAndPort();
}
if (auto sfp = forceSyncSourceCandidate.scoped(); MONGO_unlikely(sfp.isActive())) {
const auto& data = sfp.getData();
const auto hostAndPortElem = data["hostAndPort"];
if (!hostAndPortElem) {
LOGV2_FATAL(50835,
"'forceSyncSoureCandidate' parameter set with invalid host and port: "
"{failpointData}",
"'forceSyncSoureCandidate' parameter set with invalid host and port",
"failpointData"_attr = data);
}
const auto hostAndPort = HostAndPort(hostAndPortElem.checkAndGetStringData());
const int syncSourceIndex = _rsConfig.findMemberIndexByHostAndPort(hostAndPort);
if (syncSourceIndex < 0) {
LOGV2(3873118,
"'forceSyncSourceCandidate' failed due to host and port not in "
"replica set config.",
"syncSourceCandidate"_attr = hostAndPort.toString());
fassertFailed(50836);
}
if (_memberIsDenylisted(_rsConfig.getMemberAt(syncSourceIndex), now)) {
LOGV2(3873119,
"Cannot select a sync source because forced candidate is denylisted.",
"syncSourceCandidate"_attr = hostAndPort.toString());
return HostAndPort();
}
auto syncSource = _rsConfig.getMemberAt(syncSourceIndex).getHostAndPort();
LOGV2(21781,
"Choosing sync source candidate due to 'forceSyncSourceCandidate' parameter",
"syncSource"_attr = syncSource);
std::string msg(str::stream() << "syncing from: " << syncSource.toString()
<< " by 'forceSyncSourceCandidate' parameter");
setMyHeartbeatMessage(now, msg);
return syncSource;
}
// wait for 2N pings (not counting ourselves) before choosing a sync target
int numPingsNeeded = (_memberData.size() - 1) * 2 - pingsInConfig;
if (numPingsNeeded > 0) {
static Occasionally sampler;
if (sampler.tick()) {
LOGV2(21783,
"waiting for {pingsNeeded} pings from other members before syncing",
"Waiting for pings from other members before syncing",
"pingsNeeded"_attr = numPingsNeeded);
}
return HostAndPort();
}
return boost::none;
}
HostAndPort TopologyCoordinator::_choosePrimaryAsSyncSource(Date_t now,
const OpTime& lastOpTimeFetched) {
LOGV2_DEBUG(5676400,
2,
"Attempting to choose current primary as sync source",
"currentPrimaryIndex"_attr = _currentPrimaryIndex);
if (_currentPrimaryIndex == -1) {
LOGV2_DEBUG(21784,
1,
"Cannot select the primary as sync source because"
" the primary is unknown/down.");
return HostAndPort();
} else if (_memberIsDenylisted(*getCurrentPrimaryMember(), now)) {
LOGV2_DEBUG(
3873116,
1,
"Cannot select the primary as sync source because the primary member is denylisted",
"primary"_attr = getCurrentPrimaryMember()->getHostAndPort());
return HostAndPort();
} else if (_currentPrimaryIndex == _selfIndex) {
LOGV2_DEBUG(
21786, 1, "Cannot select the primary as sync source because this node is primary.");
return HostAndPort();
} else if (_memberData.at(_currentPrimaryIndex).getLastAppliedOpTime() < lastOpTimeFetched) {
LOGV2_DEBUG(4615639,
1,
"Cannot select the primary as sync source because the primary "
"is behind this node.",
"primary"_attr = getCurrentPrimaryMember()->getHostAndPort(),
"primaryOpTime"_attr =
_memberData.at(_currentPrimaryIndex).getLastAppliedOpTime(),
"lastFetchedOpTime"_attr = lastOpTimeFetched);
return HostAndPort();
} else {
auto syncSource = getCurrentPrimaryMember()->getHostAndPort();
LOGV2(3873117, "Choosing primary as sync source", "primary"_attr = syncSource);
std::string msg(str::stream() << "syncing from primary: " << syncSource.toString());
setMyHeartbeatMessage(now, msg);
return syncSource;
}
}
bool TopologyCoordinator::_memberIsDenylisted(const MemberConfig& memberConfig, Date_t now) const {
std::map<HostAndPort, Date_t>::const_iterator denylisted =
_syncSourceDenylist.find(memberConfig.getHostAndPort());
if (denylisted != _syncSourceDenylist.end()) {
if (denylisted->second > now) {
return true;
}
}
return false;
}
void TopologyCoordinator::denylistSyncSource(const HostAndPort& host, Date_t until) {
LOGV2_DEBUG(21800,
2,
"denylisting {syncSource} until {until}",
"Denylisting sync source",
"syncSource"_attr = host,
"until"_attr = until.toString());
_syncSourceDenylist[host] = until;
}
void TopologyCoordinator::undenylistSyncSource(const HostAndPort& host, Date_t now) {
std::map<HostAndPort, Date_t>::iterator hostItr = _syncSourceDenylist.find(host);
if (hostItr != _syncSourceDenylist.end() && now >= hostItr->second) {
LOGV2_DEBUG(21801,
2,
"undenylisting {syncSource}",
"Undenylisting sync source",
"syncSource"_attr = host);
_syncSourceDenylist.erase(hostItr);
}
}
void TopologyCoordinator::clearSyncSourceDenylist() {
_syncSourceDenylist.clear();
}
void TopologyCoordinator::prepareSyncFromResponse(const HostAndPort& target,
BSONObjBuilder* response,
Status* result) {
response->append("syncFromRequested", target.toString());
if (_selfIndex == -1) {
*result = Status(ErrorCodes::NotSecondary, "Removed and uninitialized nodes do not sync");
return;
}
const MemberConfig& selfConfig = _selfConfig();
if (selfConfig.isArbiter()) {
*result = Status(ErrorCodes::NotSecondary, "arbiters don't sync");
return;
}
if (_selfIndex == _currentPrimaryIndex) {
*result = Status(ErrorCodes::NotSecondary, "primaries don't sync");
return;
}
ReplSetConfig::MemberIterator targetConfig = _rsConfig.membersEnd();
int targetIndex = 0;
for (ReplSetConfig::MemberIterator it = _rsConfig.membersBegin(); it != _rsConfig.membersEnd();
++it) {
if (it->getHostAndPort() == target) {
targetConfig = it;
break;
}
++targetIndex;
}
if (targetConfig == _rsConfig.membersEnd()) {
*result = Status(ErrorCodes::NodeNotFound,
str::stream() << "Could not find member \"" << target.toString()
<< "\" in replica set");
return;
}
if (targetIndex == _selfIndex) {
*result = Status(ErrorCodes::InvalidOptions, "I cannot sync from myself");
return;
}
if (targetConfig->isArbiter()) {
*result = Status(ErrorCodes::InvalidOptions,
str::stream() << "Cannot sync from \"" << target.toString()
<< "\" because it is an arbiter");
return;
}
if (!targetConfig->shouldBuildIndexes() && selfConfig.shouldBuildIndexes()) {
*result = Status(ErrorCodes::InvalidOptions,
str::stream() << "Cannot sync from \"" << target.toString()
<< "\" because it does not build indexes");
return;
}
if (selfConfig.isVoter() && !targetConfig->isVoter()) {
*result = Status(ErrorCodes::InvalidOptions,
str::stream() << "Cannot sync from \"" << target.toString()
<< "\" because it is not a voter");
return;
}
const MemberData& hbdata = _memberData.at(targetIndex);
if (hbdata.hasAuthIssue()) {
*result =
Status(ErrorCodes::Unauthorized,
str::stream() << "not authorized to communicate with " << target.toString());
return;
}
if (hbdata.getHealth() == 0) {
*result =
Status(ErrorCodes::HostUnreachable,
str::stream() << "I cannot reach the requested member: " << target.toString());
return;
}
const OpTime lastOpApplied = getMyLastAppliedOpTime();
if (hbdata.getHeartbeatAppliedOpTime().getSecs() + 10 < lastOpApplied.getSecs()) {
LOGV2_WARNING(
21837,
"attempting to sync from {syncSource}, but its latest opTime is "
"{syncSourceHeartbeatAppliedOpTime} and ours is "
"{lastOpApplied} so this may not work",
"Attempting to sync from sync source, but it is more than 10 seconds behind us",
"syncSource"_attr = target,
"syncSourceHeartbeatAppliedOpTime"_attr = hbdata.getHeartbeatAppliedOpTime().getSecs(),
"lastOpApplied"_attr = lastOpApplied.getSecs());
response->append("warning",
str::stream() << "requested member \"" << target.toString()
<< "\" is more than 10 seconds behind us");
// not returning bad Status, just warning
}
HostAndPort prevSyncSource = getSyncSourceAddress();
if (!prevSyncSource.empty()) {
response->append("prevSyncTarget", prevSyncSource.toString());
}
setForceSyncSourceIndex(targetIndex);
*result = Status::OK();
}
// produce a reply to a heartbeat, and return whether the remote node's config has changed.
StatusWith<bool> TopologyCoordinator::prepareHeartbeatResponseV1(
Date_t now,
const ReplSetHeartbeatArgsV1& args,
StringData ourSetName,
ReplSetHeartbeatResponse* response) {
// Verify that replica set names match
const std::string rshb = args.getSetName();
if (ourSetName != rshb) {
LOGV2(21802,
"replSet set names do not match, ours: {ourSetName}; remote node's: "
"{remoteNodeSetName}",
"replSet set names do not match",
"ourSetName"_attr = ourSetName,
"remoteNodeSetName"_attr = rshb);
return Status(ErrorCodes::InconsistentReplicaSetNames,
str::stream() << "Our set name of " << ourSetName << " does not match name "
<< rshb << " reported by remote node");
}
const MemberState myState = getMemberState();
if (_selfIndex == -1) {
if (myState.removed()) {
return Status(ErrorCodes::InvalidReplicaSetConfig,
"Our replica set configuration is invalid or does not include us");
}
} else {
if (args.getSenderId() == _selfConfig().getId().getData()) {
return Status(ErrorCodes::BadValue,
str::stream() << "Received heartbeat from member with the same "
"member ID as ourself: "
<< args.getSenderId());
}
}
response->setSetName(ourSetName);
response->setState(myState.s);
if (myState.primary()) {
response->setElectionTime(_electionTime);
}
OpTimeAndWallTime lastOpApplied;
OpTimeAndWallTime lastOpDurable;
// We include null times for lastApplied and lastDurable if we are in STARTUP_2, as we do not
// want to report replication progress and be part of write majorities while in initial sync.
if (!myState.startup2()) {
lastOpApplied = getMyLastAppliedOpTimeAndWallTime();
lastOpDurable = getMyLastDurableOpTimeAndWallTime();
}
response->setAppliedOpTimeAndWallTime(lastOpApplied);
response->setDurableOpTimeAndWallTime(lastOpDurable);
if (_currentPrimaryIndex != -1) {
response->setPrimaryId(_rsConfig.getMemberAt(_currentPrimaryIndex).getId().getData());
}
response->setTerm(_term);
if (!_syncSource.empty()) {
response->setSyncingTo(_syncSource);
}
if (!_rsConfig.isInitialized()) {
response->setConfigVersion(-2);
return false;
}
response->setElectable(
!_getMyUnelectableReason(now, StartElectionReasonEnum::kElectionTimeout));
const long long v = _rsConfig.getConfigVersion();
const long long t = _rsConfig.getConfigTerm();
response->setConfigVersion(v);
response->setConfigTerm(t);
// Deliver new config if caller's config is older than ours
if (_rsConfig.getConfigVersionAndTerm() > args.getConfigVersionAndTerm()) {
response->setConfig(_rsConfig);
}
// Resolve the caller's id in our Member list
int from = -1;
if (v == args.getConfigVersion() && args.getSenderId() != -1) {
from = _getMemberIndex(args.getSenderId());
}
if (from == -1) {
return false;
}
invariant(from != _selfIndex);
auto& fromNodeData = _memberData.at(from);
// note that we got a heartbeat from this node
fromNodeData.setLastHeartbeatRecv(now);
// Update liveness for sending node.
fromNodeData.updateLiveness(now);
return fromNodeData.getConfigVersionAndTerm() < args.getConfigVersionAndTerm();
}
int TopologyCoordinator::_getMemberIndex(int id) const {
int index = 0;
for (ReplSetConfig::MemberIterator it = _rsConfig.membersBegin(); it != _rsConfig.membersEnd();
++it, ++index) {
if (it->getId() == MemberId(id)) {
return index;
}
}
return -1;
}
std::pair<ReplSetHeartbeatArgsV1, Milliseconds> TopologyCoordinator::prepareHeartbeatRequestV1(
Date_t now, StringData ourSetName, const HostAndPort& target) {
PingStats& hbStats = _pings[target];
Milliseconds alreadyElapsed(now.asInt64() - hbStats.getLastHeartbeatStartDate().asInt64());
if ((!_rsConfig.isInitialized()) || !hbStats.trying() ||
(alreadyElapsed >= _rsConfig.getHeartbeatTimeoutPeriodMillis())) {
// This is either the first request ever for "target", or the heartbeat timeout has
// passed, so we're starting a "new" heartbeat.
hbStats.start(now);
alreadyElapsed = Milliseconds(0);
}
ReplSetHeartbeatArgsV1 hbArgs;
if (_rsConfig.isInitialized()) {
hbArgs.setSetName(_rsConfig.getReplSetName());
hbArgs.setConfigVersion(_rsConfig.getConfigVersion());
if (_rsConfig.getConfigTerm() != OpTime::kUninitializedTerm) {
hbArgs.setConfigTerm(_rsConfig.getConfigTerm());
}
if (_currentPrimaryIndex >= 0) {
// Send primary member id if one exists.
hbArgs.setPrimaryId(_memberData.at(_currentPrimaryIndex).getMemberId().getData());
}
if (_selfIndex >= 0) {
const MemberConfig& me = _selfConfig();
hbArgs.setSenderId(me.getId().getData());
hbArgs.setSenderHost(me.getHostAndPort());
}
hbArgs.setTerm(_term);
} else {
hbArgs.setSetName(ourSetName);
// Config version -2 is for uninitialized config.
hbArgs.setConfigVersion(-2);
hbArgs.setTerm(OpTime::kInitialTerm);
}
hbArgs.setHeartbeatVersion(1);
const Milliseconds timeoutPeriod(
_rsConfig.isInitialized() ? _rsConfig.getHeartbeatTimeoutPeriodMillis()
: Milliseconds{ReplSetConfig::kDefaultHeartbeatTimeoutPeriod});
const Milliseconds timeout(timeoutPeriod - alreadyElapsed);
return std::make_pair(hbArgs, timeout);
}
bool isUnrecoverableHeartbeatFailure(Status status) {
return status.code() == ErrorCodes::InconsistentReplicaSetNames;
}
HeartbeatResponseAction TopologyCoordinator::processHeartbeatResponse(
Date_t now,
Milliseconds networkRoundTripTime,
const HostAndPort& target,
const StatusWith<ReplSetHeartbeatResponse>& hbResponse) {
PingStats& hbStats = _pings[target];
invariant(hbStats.getLastHeartbeatStartDate() != Date_t());
const bool isUnauthorized = (hbResponse.getStatus().code() == ErrorCodes::Unauthorized) ||
(hbResponse.getStatus().code() == ErrorCodes::AuthenticationFailed);
// Replication of auth changes can cause temporary auth failures.
if (hbResponse.isOK() || isUnauthorized) {
hbStats.hit(networkRoundTripTime);
} else {
hbStats.miss();
}
// If a node is not PRIMARY and has no sync source, we increase the heartbeat rate in order
// to help it find a sync source more quickly, which helps ensure the PRIMARY will continue to
// see the majority of the cluster.
//
// Arbiters also decrease their heartbeat interval to at most half the election timeout period.
Milliseconds heartbeatInterval = _rsConfig.getHeartbeatInterval();
if (getMemberState().arbiter()) {
heartbeatInterval =
std::min(_rsConfig.getElectionTimeoutPeriod() / 2, _rsConfig.getHeartbeatInterval());
} else if (getSyncSourceAddress().empty() && !_iAmPrimary()) {
heartbeatInterval = std::min(_rsConfig.getElectionTimeoutPeriod() / 2,
_rsConfig.getHeartbeatInterval() / 4);
}
const Milliseconds alreadyElapsed = now - hbStats.getLastHeartbeatStartDate();
Date_t nextHeartbeatStartDate;
// Determine the next heartbeat start time. If a heartbeat has not succeeded or failed, and we
// have not used up the timeout period, we should retry.
if (hbStats.trying() && (alreadyElapsed < _rsConfig.getHeartbeatTimeoutPeriod())) {
// There are still retries left, let's use one.
nextHeartbeatStartDate = now;
} else {
nextHeartbeatStartDate = now + heartbeatInterval;
}
if (hbStats.failed()) {
LOGV2_FOR_HEARTBEATS(
23974,
0,
"Heartbeat to {target} failed after {maxHeartbeatRetries} retries, response "
"status: {error}",
"Heartbeat failed after max retries",
"target"_attr = target,
"maxHeartbeatRetries"_attr = kMaxHeartbeatRetries,
"error"_attr = hbResponse.getStatus());
}
HeartbeatResponseAction nextAction = HeartbeatResponseAction::makeNoAction();
nextAction.setNextHeartbeatStartDate(nextHeartbeatStartDate);
if (hbResponse.isOK() && hbResponse.getValue().hasConfig()) {
// -2 is for uninitialized config.
const ConfigVersionAndTerm currentConfigVersionAndTerm = _rsConfig.isInitialized()
? _rsConfig.getConfigVersionAndTerm()
: ConfigVersionAndTerm(-2, OpTime::kUninitializedTerm);
const ReplSetConfig& newConfig = hbResponse.getValue().getConfig();
if (newConfig.getConfigVersionAndTerm() > currentConfigVersionAndTerm) {
nextAction = HeartbeatResponseAction::makeReconfigAction();
nextAction.setNextHeartbeatStartDate(nextHeartbeatStartDate);
// Only continue processing heartbeat in primary state. In other states it is not
// safe to continue processing heartbeat and should start reconfig right away.
// e.g. if this node was removed from replSet, _selfIndex is -1, and a following
// check on _selfIndex will keep retrying heartbeat to fetch new config, preventing
// the new config to be installed.
if (_role != Role::kLeader) {
return nextAction;
}
// Continue processing heartbeat responses even if we decide to install a new config.
} else {
// Could be we got the newer version before we got the response, or the
// target erroneously sent us one, even though it isn't newer.
if (newConfig.getConfigVersionAndTerm() < currentConfigVersionAndTerm) {
LOGV2_DEBUG(21803, 1, "Config version from heartbeat was older than ours");
} else {
LOGV2_DEBUG(21804, 2, "Config from heartbeat response was same as ours");
}
if (_rsConfig.isInitialized()) {
LOGV2_DEBUG(
4615641,
2,
"Current config: {currentConfig}; Config in heartbeat: {heartbeatConfig}",
"Heartbeat config",
"currentConfig"_attr = _rsConfig.toBSON(),
"heartbeatConfig"_attr = newConfig.toBSON());
} else {
LOGV2_DEBUG(4615647,
2,
"Config in heartbeat: {heartbeatConfig}",
"Heartbeat config",
"heartbeatConfig"_attr = newConfig.toBSON());
}
}
}
// Check if the heartbeat target is in our config. If it isn't, there's nothing left to do,
// so return early.
if (!_rsConfig.isInitialized()) {
return nextAction;
}
// This server is not in the config, either because it was removed or a DNS error finding self.
if (_selfIndex == -1) {
LOGV2(3564900,
"Could not find self in current config, retrying DNS resolution of members",
"target"_attr = target,
"currentConfig"_attr = _rsConfig.toBSON());
nextAction = HeartbeatResponseAction::makeRetryReconfigAction();
nextAction.setNextHeartbeatStartDate(nextHeartbeatStartDate);
return nextAction;
}
const int memberIndex = _rsConfig.findMemberIndexByHostAndPort(target);
if (memberIndex == -1) {
LOGV2_DEBUG(21806,
1,
"Could not find {target} in current config so ignoring --"
" current config: {currentConfig}",
"Could not find target in current config so ignoring",
"target"_attr = target,
"currentConfig"_attr = _rsConfig.toBSON());
return nextAction;
}
invariant(memberIndex != _selfIndex);
MemberData& hbData = _memberData.at(memberIndex);
const MemberConfig member = _rsConfig.getMemberAt(memberIndex);
bool advancedOpTimeOrUpdatedConfig = false;
bool becameElectable = false;
bool changedMemberState = false;
if (!hbResponse.isOK()) {
if (isUnauthorized) {
hbData.setAuthIssue(now);
}
// If the heartbeat has failed i.e. used up all retries, then we mark the target node as
// down.
else if (hbStats.failed() || (alreadyElapsed >= _rsConfig.getHeartbeatTimeoutPeriod()) ||
isUnrecoverableHeartbeatFailure(hbResponse.getStatus())) {
hbData.setDownValues(now, hbResponse.getStatus().reason());
} else {
LOGV2_DEBUG(21807,
3,
"Bad heartbeat response from {target}; trying again; Retries left: "
"{retriesLeft}; {retriesElapsed} have already elapsed",
"Bad heartbeat response; trying again",
"target"_attr = target,
"retriesLeft"_attr = (hbStats.retriesLeft()),
"retriesElapsed"_attr = alreadyElapsed);
}
} else {
ReplSetHeartbeatResponse hbr = std::move(hbResponse.getValue());
LOGV2_DEBUG(21808,
3,
"setUpValues: heartbeat response good for member _id:{memberId}",
"setUpValues: heartbeat response good",
"memberId"_attr = member.getId());
pingsInConfig++;
auto wasUnelectable = hbData.isUnelectable();
auto hbChanges = hbData.setUpValues(now, std::move(hbr));
advancedOpTimeOrUpdatedConfig =
hbChanges.getOpTimeAdvanced() || hbChanges.getConfigChanged();
changedMemberState = hbChanges.getMemberStateChanged();
becameElectable = wasUnelectable && !hbData.isUnelectable();
}
_updatePrimaryFromHBDataV1(now);
// If we've decided to install a newer config, we don't need to consider takeovers.
if (nextAction.getAction() == HeartbeatResponseAction::Reconfig) {
return nextAction;
}
nextAction = _shouldTakeOverPrimary(memberIndex);
nextAction.setNextHeartbeatStartDate(nextHeartbeatStartDate);
nextAction.setAdvancedOpTimeOrUpdatedConfig(advancedOpTimeOrUpdatedConfig);
nextAction.setBecameElectable(becameElectable);
nextAction.setChangedMemberState(changedMemberState);
return nextAction;
}
bool TopologyCoordinator::haveNumNodesReachedOpTime(const OpTime& targetOpTime,
int numNodes,
bool durablyWritten) {
// Replication progress that is for some reason ahead of us should not allow us to
// satisfy a write concern if we aren't caught up ourselves.
OpTime myOpTime = durablyWritten ? getMyLastDurableOpTime() : getMyLastAppliedOpTime();
if (myOpTime < targetOpTime) {
return false;
}
// Invariants that we only wait for an OpTime in the term that this node is currently writing
// to. In other words, we do not support waiting for an OpTime written by a previous primary
// because comparing members' lastApplied/lastDurable alone is not sufficient to tell if the
// OpTime has been replicated.
invariant(targetOpTime.getTerm() == getMyLastAppliedOpTime().getTerm());
for (auto&& memberData : _memberData) {
const auto isArbiter = _rsConfig.getMemberAt(memberData.getConfigIndex()).isArbiter();
// We do not count arbiters towards the write concern.
if (isArbiter) {
continue;
}
const OpTime& memberOpTime =
durablyWritten ? memberData.getLastDurableOpTime() : memberData.getLastAppliedOpTime();
// In addition to checking if a member has a greater/equal timestamp field we also need to
// make sure that the memberOpTime is in the same term as the OpTime we wait for. If a
// member's OpTime has a higher term, it indicates that this node will be stepping down. And
// thus we do not know if the target OpTime in our previous term has been replicated to the
// member because the memberOpTime in a higher term could correspond to an operation in a
// divergent branch of history regardless of its timestamp.
if (memberOpTime.getTerm() == targetOpTime.getTerm() &&
memberOpTime.getTimestamp() >= targetOpTime.getTimestamp()) {
--numNodes;
}
if (numNodes <= 0) {
return true;
}
}
return false;
}
bool TopologyCoordinator::haveTaggedNodesReachedOpTime(const OpTime& opTime,
const ReplSetTagPattern& tagPattern,
bool durablyWritten) {
auto pred = makeOpTimePredicate(opTime, durablyWritten);
return haveTaggedNodesSatisfiedCondition(pred, tagPattern);
}
TopologyCoordinator::MemberPredicate TopologyCoordinator::makeOpTimePredicate(const OpTime& opTime,
bool durablyWritten) {
// Invariants that we only wait for an OpTime in the term that this node is currently writing
// to. In other words, we do not support waiting for an OpTime written by a previous primary
// because comparing members' lastApplied/lastDurable alone is not sufficient to tell if the
// OpTime has been replicated.
invariant(opTime.getTerm() == getMyLastAppliedOpTime().getTerm());
return [=](const MemberData& memberData) {
auto memberOpTime =
durablyWritten ? memberData.getLastDurableOpTime() : memberData.getLastAppliedOpTime();
// In addition to checking if a member has a greater/equal timestamp field we also need to
// make sure that the memberOpTime is in the same term as the OpTime we wait for. If a
// member's OpTime has a higher term, it indicates that this node will be stepping down. And
// thus we do not know if the target OpTime in our previous term has been replicated to the
// member because the memberOpTime in a higher term could correspond to an operation in a
// divergent branch of history regardless of its timestamp.
return memberOpTime.getTerm() == opTime.getTerm() &&
memberOpTime.getTimestamp() >= opTime.getTimestamp();
};
}
TopologyCoordinator::MemberPredicate TopologyCoordinator::makeConfigPredicate() {
return [&](const MemberData& memberData) {
return memberData.getConfigVersionAndTerm() == _rsConfig.getConfigVersionAndTerm();
};
}
bool TopologyCoordinator::haveTaggedNodesSatisfiedCondition(
std::function<bool(const MemberData&)> pred, const ReplSetTagPattern& tagPattern) {
ReplSetTagMatch matcher(tagPattern);
for (auto&& memberData : _memberData) {
if (pred(memberData)) {
// This node has satisfied the predicate, now we need to check if it is a part
// of the tagPattern.
int memberIndex = memberData.getConfigIndex();
invariant(memberIndex >= 0);
const MemberConfig& memberConfig = _rsConfig.getMemberAt(memberIndex);
for (auto&& it = memberConfig.tagsBegin(); it != memberConfig.tagsEnd(); ++it) {
if (matcher.update(*it)) {
return true;
}
}
}
}
return false;
}
HeartbeatResponseAction TopologyCoordinator::checkMemberTimeouts(Date_t now) {
bool stepdown = false;
for (int memberIndex = 0; memberIndex < static_cast<int>(_memberData.size()); memberIndex++) {
auto& memberData = _memberData[memberIndex];
if (!memberData.isSelf() && !memberData.lastUpdateStale() &&
now - memberData.getLastUpdate() >= _rsConfig.getElectionTimeoutPeriod()) {
memberData.markLastUpdateStale();
if (_iAmPrimary()) {
stepdown = stepdown || setMemberAsDown(now, memberIndex);
}
}
}
if (stepdown) {
LOGV2(21809, "Can't see a majority of the set, relinquishing primary");
return HeartbeatResponseAction::makeStepDownSelfAction(_selfIndex);
}
return HeartbeatResponseAction::makeNoAction();
}
std::vector<HostAndPort> TopologyCoordinator::getHostsWrittenTo(const OpTime& op,
bool durablyWritten) {
std::vector<HostAndPort> hosts;
for (const auto& memberData : _memberData) {
if (durablyWritten) {
if (memberData.getLastDurableOpTime() < op) {
continue;
}
} else if (memberData.getLastAppliedOpTime() < op) {
continue;
}
hosts.push_back(memberData.getHostAndPort());
}
return hosts;
}
bool TopologyCoordinator::setMemberAsDown(Date_t now, const int memberIndex) {
invariant(memberIndex != _selfIndex);
invariant(memberIndex != -1);
invariant(_currentPrimaryIndex == _selfIndex);
MemberData& hbData = _memberData.at(memberIndex);
hbData.setDownValues(now, "no response within election timeout period");
if (CannotSeeMajority &
_getMyUnelectableReason(now, StartElectionReasonEnum::kElectionTimeout)) {
return true;
}
return false;
}
std::pair<MemberId, Date_t> TopologyCoordinator::getStalestLiveMember() const {
Date_t earliestDate = Date_t::max();
MemberId earliestMemberId;
for (const auto& memberData : _memberData) {
if (memberData.isSelf()) {
continue;
}
if (memberData.lastUpdateStale()) {
// Already stale.
continue;
}
LOGV2_DEBUG(21810,
3,
"memberData lastupdate is: {memberDataLastUpdate}",
"memberData last update",
"memberDataLastUpdate"_attr = memberData.getLastUpdate());
if (earliestDate > memberData.getLastUpdate()) {
earliestDate = memberData.getLastUpdate();
earliestMemberId = memberData.getMemberId();
}
}
LOGV2_DEBUG(21811,
3,
"stalest member {earliestMemberId} date: {earliestDate}",
"Stalest member",
"earliestMemberId"_attr = earliestMemberId,
"earliestDate"_attr = earliestDate);
return std::make_pair(earliestMemberId, earliestDate);
}
void TopologyCoordinator::resetMemberTimeouts(Date_t now,
const stdx::unordered_set<HostAndPort>& member_set) {
for (auto&& memberData : _memberData) {
if (member_set.count(memberData.getHostAndPort()))
memberData.updateLiveness(now);
}
}
OpTime TopologyCoordinator::getMyLastAppliedOpTime() const {
return _selfMemberData().getLastAppliedOpTime();
}
OpTimeAndWallTime TopologyCoordinator::getMyLastAppliedOpTimeAndWallTime() const {
return {_selfMemberData().getLastAppliedOpTime(), _selfMemberData().getLastAppliedWallTime()};
}
void TopologyCoordinator::setMyLastAppliedOpTimeAndWallTime(OpTimeAndWallTime opTimeAndWallTime,
Date_t now,
bool isRollbackAllowed) {
auto opTime = opTimeAndWallTime.opTime;
auto& myMemberData = _selfMemberData();
auto myLastAppliedOpTime = myMemberData.getLastAppliedOpTime();
if (!(isRollbackAllowed || opTime == myLastAppliedOpTime)) {
invariant(opTime > myLastAppliedOpTime);
// In pv1, oplog entries are ordered by non-decreasing term and strictly increasing
// timestamp. So, in pv1, its not possible for us to get opTime with higher term and
// timestamp lesser than or equal to our current lastAppliedOptime.
invariant(opTime.getTerm() == OpTime::kUninitializedTerm ||
myLastAppliedOpTime.getTerm() == OpTime::kUninitializedTerm ||
opTime.getTimestamp() > myLastAppliedOpTime.getTimestamp());
}
myMemberData.setLastAppliedOpTimeAndWallTime(opTimeAndWallTime, now);
}
OpTime TopologyCoordinator::getMyLastDurableOpTime() const {
return _selfMemberData().getLastDurableOpTime();
}
OpTimeAndWallTime TopologyCoordinator::getMyLastDurableOpTimeAndWallTime() const {
return {_selfMemberData().getLastDurableOpTime(), _selfMemberData().getLastDurableWallTime()};
}
void TopologyCoordinator::setMyLastDurableOpTimeAndWallTime(OpTimeAndWallTime opTimeAndWallTime,
Date_t now,
bool isRollbackAllowed) {
auto opTime = opTimeAndWallTime.opTime;
auto& myMemberData = _selfMemberData();
invariant(isRollbackAllowed || opTime >= myMemberData.getLastDurableOpTime());
myMemberData.setLastDurableOpTimeAndWallTime(opTimeAndWallTime, now);
}
StatusWith<bool> TopologyCoordinator::setLastOptimeForMember(
const UpdatePositionArgs::UpdateInfo& args, Date_t now) {
if (_selfIndex == -1) {
// Ignore updates when we're in state REMOVED.
return Status(ErrorCodes::NotPrimaryOrSecondary,
"Received replSetUpdatePosition command but we are in state REMOVED");
}
invariant(_rsConfig.isInitialized()); // Can only use setLastOptimeForMember in replSet mode.
MemberId memberId;
try {
memberId = MemberId(args.memberId);
} catch (const DBException& ex) {
return ex.toStatus();
}
if (memberId == _rsConfig.getMemberAt(_selfIndex).getId()) {
// Do not let remote nodes tell us what our optime is.
return false;
}
LOGV2_DEBUG(21812,
2,
"received notification that node with memberID {memberId} in config with version "
"{configVersion} has reached optime: {appliedOpTime} and is durable through: "
"{durableOpTime}",
"Received replSetUpdatePosition",
"memberId"_attr = memberId,
"configVersion"_attr = args.cfgver,
"appliedOpTime"_attr = args.appliedOpTime,
"durableOpTime"_attr = args.durableOpTime);
auto* memberData = _findMemberDataByMemberId(memberId.getData());
// If we are applying a splitConfig for a shard split, we may still be receiving updates for
// nodes that have been removed from the donor set.
if (_rsConfig.isSplitConfig() && !memberData &&
memberId.getData() >= _rsConfig.getNumMembers()) {
LOGV2(6234605,
"Skipping update from node",
"data"_attr = memberId.getData(),
"conf"_attr = _rsConfig);
// Do not advance optime
return false;
}
// While we can accept replSetUpdatePosition commands across config versions, we still do not
// allow receiving them from a node that is not in our config.
if (!memberData) {
invariant(!_rsConfig.findMemberByID(memberId.getData()));
static constexpr char errmsg[] =
"Received replSetUpdatePosition for node which doesn't exist in our config";
LOGV2_DEBUG(21814, 1, errmsg, "memberId"_attr = memberId);
return Status(ErrorCodes::NodeNotFound,
str::stream() << errmsg << ", memberId: " << memberId);
}
invariant(memberId == memberData->getMemberId());
auto durableOpTime = args.durableOpTime;
auto durableWallTime = args.durableWallTime;
// Arbiters are always expected to report null durable optimes (and wall times).
// If that is not the case here, make sure to correct these times before ingesting them.
auto& memberInConfig = _rsConfig.getMemberAt(memberData->getConfigIndex());
if ((memberData->getState().arbiter() || memberInConfig.isArbiter()) &&
(!args.durableOpTime.isNull() || args.durableWallTime != Date_t())) {
LOGV2(5662001,
"Received non-null durable optime/walltime for arbiter from "
"replSetUpdatePosition. Ignoring value(s).",
"memberId"_attr = memberId,
"durableOpTime"_attr = args.durableOpTime,
"durableWallTime"_attr = args.durableWallTime);
durableOpTime = OpTime();
durableWallTime = Date_t();
}
LOGV2_DEBUG(21815,
3,
"Node with memberID {memberId} currently has optime {oldLastAppliedOpTime} "
"durable through {oldLastDurableOpTime}; updating to optime "
"{newAppliedOpTime} and durable through {newDurableOpTime}",
"Updating member data due to replSetUpdatePosition",
"memberId"_attr = memberId,
"oldLastAppliedOpTime"_attr = memberData->getLastAppliedOpTime(),
"oldLastDurableOpTime"_attr = memberData->getLastDurableOpTime(),
"newAppliedOpTime"_attr = args.appliedOpTime,
"newDurableOpTime"_attr = durableOpTime);
bool advancedOpTime = memberData->advanceLastAppliedOpTimeAndWallTime(
{args.appliedOpTime, args.appliedWallTime}, now);
advancedOpTime =
memberData->advanceLastDurableOpTimeAndWallTime({durableOpTime, durableWallTime}, now) ||
advancedOpTime;
return advancedOpTime;
}
void TopologyCoordinator::updateLastCommittedInPrevConfig() {
_lastCommittedInPrevConfig = _lastCommittedOpTimeAndWallTime.opTime;
}
OpTime TopologyCoordinator::getLastCommittedInPrevConfig() {
return _lastCommittedInPrevConfig;
}
OpTime TopologyCoordinator::getConfigOplogCommitmentOpTime() {
// If we were previously a secondary, we must make sure that we commit a new op as primary
// before we can commit any other oplog entries, which necessitates the need for using the
// '_firstOpTimeOfMyTerm' value here.
return std::max(_lastCommittedInPrevConfig, _firstOpTimeOfMyTerm);
}
MemberData* TopologyCoordinator::_findMemberDataByMemberId(const int memberId) {
const int memberIndex = _getMemberIndex(memberId);
if (memberIndex >= 0)
return &_memberData[memberIndex];
return nullptr;
}
void TopologyCoordinator::_updatePrimaryFromHBDataV1(Date_t now) {
// Updates the local notion of which remote node, if any is primary.
invariant(_selfIndex != -1);
// If we are the primary, there must be no other primary, otherwise its higher term would
// have already made us step down.
if (_currentPrimaryIndex == _selfIndex) {
return;
}
// Scan the member list's heartbeat data for who is primary, and update _currentPrimaryIndex.
int primaryIndex = -1;
for (size_t i = 0; i < _memberData.size(); i++) {
const MemberData& member = _memberData.at(i);
if (member.getState().primary() && member.up()) {
if (primaryIndex == -1 || _memberData.at(primaryIndex).getTerm() < member.getTerm()) {
primaryIndex = i;
}
}
}
LOGV2_DEBUG(5676401,
2,
"Updating primary index from heartbeat data",
"primaryIndex"_attr = primaryIndex,
"previousPrimaryIndex"_attr = _currentPrimaryIndex);
_currentPrimaryIndex = primaryIndex;
// Clear last heartbeat message on ourselves.
setMyHeartbeatMessage(now, "");
}
HeartbeatResponseAction TopologyCoordinator::_shouldTakeOverPrimary(int updatedConfigIndex) {
// Takeover when the replset is stable.
//
// Take over the primary only if the remote primary is in the latest term I know.
// This is done only when we get a heartbeat response from the primary.
// Otherwise, there must be an outstanding election, which may succeed or not, but
// the remote primary will become aware of that election eventually and step down.
if (_currentPrimaryIndex == -1) {
return HeartbeatResponseAction::makeNoAction();
}
auto primaryIndex = _currentPrimaryIndex;
if (_memberData.at(primaryIndex).getTerm() != _term || updatedConfigIndex != primaryIndex) {
return HeartbeatResponseAction::makeNoAction();
}
// A priority 0 node cannot win an election. Even if the priority changed via reconfig to make
// the node eligible by the time a takeover scheduled here would happen, we would end up
// canceling that takeover due to the reconfig.
if (_selfConfig().getPriority() <= 0) {
return HeartbeatResponseAction::makeNoAction();
}
// Don't schedule catchup takeover if catchup takeover or primary catchup is disabled.
const bool catchupTakeoverDisabled =
ReplSetConfig::kCatchUpDisabled == _rsConfig.getCatchUpTimeoutPeriod() ||
ReplSetConfig::kCatchUpTakeoverDisabled == _rsConfig.getCatchUpTakeoverDelay();
bool scheduleCatchupTakeover = false;
bool schedulePriorityTakeover = false;
// If we have a stale view of the new primary's opTime and believe its opTime to be
// less than our own, we may end up scheduling an unecessary takeover. Primaries
// increment the term as soon as they start a real election, but they do not write
// anything in that new term until they have finished their full state transition.
// Thus, if we have applied anything in the new term, it means that the primary is
// already past the catchup phase and we should not be attempting a catchup takeover.
const bool primaryAlreadyCaughtUp = (getMyLastAppliedOpTime().getTerm() == getTerm());
if (!catchupTakeoverDisabled && !primaryAlreadyCaughtUp &&
(_memberData.at(primaryIndex).getLastAppliedOpTime() <
_memberData.at(_selfIndex).getLastAppliedOpTime())) {
LOGV2_FOR_ELECTION(23975,
2,
"I can take over the primary due to fresher data",
"primaryIndex"_attr = primaryIndex,
"primaryTerm"_attr = _memberData.at(primaryIndex).getTerm(),
"primaryOpTime"_attr =
_memberData.at(primaryIndex).getLastAppliedOpTime(),
"myOpTime"_attr = _memberData.at(_selfIndex).getLastAppliedOpTime(),
"replicaSetStatus"_attr = _getReplSetStatusString());
scheduleCatchupTakeover = true;
}
if (_rsConfig.getMemberAt(primaryIndex).getPriority() <
_rsConfig.getMemberAt(_selfIndex).getPriority()) {
LOGV2_FOR_ELECTION(23977,
2,
"I can take over the primary due to higher priority",
"primaryIndex"_attr = primaryIndex,
"primaryTerm"_attr = _memberData.at(primaryIndex).getTerm(),
"replicaSetStatus"_attr = _getReplSetStatusString());
schedulePriorityTakeover = true;
}
// Calculate rank of current node. A rank of 0 indicates that it has the highest priority.
const auto currentNodePriority = _rsConfig.getMemberAt(_selfIndex).getPriority();
// Schedule a priority takeover early only if we know that the current node has the highest
// priority in the replica set, has a higher priority than the primary, and is the most
// up to date node.
// Otherwise, prefer to schedule a catchup takeover over a priority takeover
if (scheduleCatchupTakeover && schedulePriorityTakeover &&
_rsConfig.calculatePriorityRank(currentNodePriority) == 0) {
LOGV2_FOR_ELECTION(
23979,
2,
"I can take over the primary because I have a higher priority, the highest "
"priority in the replica set, and fresher data. Current primary index: "
"{primaryIndex} in term {primaryTerm}",
"I can take over the primary because I have a higher priority, the highest "
"priority in the replica set, and fresher data",
"primaryIndex"_attr = primaryIndex,
"primaryTerm"_attr = _memberData.at(primaryIndex).getTerm());
return HeartbeatResponseAction::makePriorityTakeoverAction();
}
if (scheduleCatchupTakeover) {
return HeartbeatResponseAction::makeCatchupTakeoverAction();
}
if (schedulePriorityTakeover) {
return HeartbeatResponseAction::makePriorityTakeoverAction();
}
return HeartbeatResponseAction::makeNoAction();
}
bool TopologyCoordinator::_aMajoritySeemsToBeUp() const {
int vUp = 0;
for (std::vector<MemberData>::const_iterator it = _memberData.begin(); it != _memberData.end();
++it) {
const int itIndex = indexOfIterator(_memberData, it);
if (itIndex == _selfIndex || it->up()) {
vUp += _rsConfig.getMemberAt(itIndex).getNumVotes();
}
}
return vUp * 2 > _rsConfig.getTotalVotingMembers();
}
int TopologyCoordinator::_findHealthyPrimaryOfEqualOrGreaterPriority(
const int candidateIndex) const {
const double candidatePriority = _rsConfig.getMemberAt(candidateIndex).getPriority();
for (auto it = _memberData.begin(); it != _memberData.end(); ++it) {
if (!it->up() || it->getState() != MemberState::RS_PRIMARY) {
continue;
}
const int itIndex = indexOfIterator(_memberData, it);
const double priority = _rsConfig.getMemberAt(itIndex).getPriority();
if (itIndex != candidateIndex && priority >= candidatePriority) {
return itIndex;
}
}
return -1;
}
bool TopologyCoordinator::_amIFreshEnoughForPriorityTakeover() const {
const OpTime ourLatestKnownOpTime = latestKnownOpTime();
// Rules are:
// - If the terms don't match, we don't call for priority takeover.
// - If our optime and the latest optime happen in different seconds, our optime must be within
// at least priorityTakeoverFreshnessWindowSeconds seconds of the latest optime.
// - If our optime and the latest optime happen in the same second, our optime must be within
// at least 1000 oplog entries of the latest optime (i.e. the increment portion of the timestamp
// must be within 1000). This is to handle the case where a primary had its clock set far into
// the future, took some writes, then had its clock set back. In that case the timestamp
// component of all future oplog entries generated will be the same, until real world time
// passes the timestamp component of the last oplog entry.
const OpTime ourLastOpApplied = getMyLastAppliedOpTime();
if (ourLastOpApplied.getTerm() != ourLatestKnownOpTime.getTerm()) {
return false;
}
if (ourLastOpApplied.getTimestamp().getSecs() !=
ourLatestKnownOpTime.getTimestamp().getSecs()) {
return ourLastOpApplied.getTimestamp().getSecs() +
gPriorityTakeoverFreshnessWindowSeconds >=
ourLatestKnownOpTime.getTimestamp().getSecs();
} else {
return ourLastOpApplied.getTimestamp().getInc() + 1000 >=
ourLatestKnownOpTime.getTimestamp().getInc();
}
}
bool TopologyCoordinator::_amIFreshEnoughForCatchupTakeover() const {
const OpTime ourLatestKnownOpTime = latestKnownOpTime();
// Rules are:
// - We must have the freshest optime of all the up nodes.
// - We must specifically have a fresher optime than the primary (can't be equal).
// - The term of our last applied op must be less than the current term. This ensures that no
// writes have happened since the most recent election and that the primary is still in
// catchup mode.
// There is no point to a catchup takeover if we aren't the freshest node because
// another node would immediately perform another catchup takeover when we become primary.
const OpTime ourLastOpApplied = getMyLastAppliedOpTime();
if (ourLastOpApplied < ourLatestKnownOpTime) {
return false;
}
if (_currentPrimaryIndex == -1) {
return false;
}
// If we aren't ahead of the primary, there is no point to having a catchup takeover.
const OpTime primaryLastOpApplied = _memberData[_currentPrimaryIndex].getLastAppliedOpTime();
if (ourLastOpApplied <= primaryLastOpApplied) {
return false;
}
// If the term of our last applied op is less than the current term, the primary didn't write
// anything and it is still in catchup mode.
return ourLastOpApplied.getTerm() < _term;
}
bool TopologyCoordinator::_iAmPrimary() const {
if (_role == Role::kLeader) {
invariant(_currentPrimaryIndex == _selfIndex);
invariant(_leaderMode != LeaderMode::kNotLeader);
return true;
}
return false;
}
bool TopologyCoordinator::prepareForUnconditionalStepDown() {
if (_leaderMode == LeaderMode::kSteppingDown) {
// Can only be processing one required stepdown at a time.
return false;
}
// Heartbeat and reconfig (via cmd or heartbeat) initiated stepdowns take precedence over
// stepdown command initiated stepdowns, so it's safe to transition from kAttemptingStepDown
// to kSteppingDown.
_setLeaderMode(LeaderMode::kSteppingDown);
return true;
}
StatusWith<TopologyCoordinator::StepDownAttemptAbortFn>
TopologyCoordinator::prepareForStepDownAttempt() {
if (_leaderMode == LeaderMode::kSteppingDown ||
_leaderMode == LeaderMode::kAttemptingStepDown) {
return Status{ErrorCodes::ConflictingOperationInProgress,
"This node is already in the process of stepping down"};
}
if (_leaderMode == LeaderMode::kNotLeader) {
return Status{ErrorCodes::NotWritablePrimary, "This node is not a primary."};
}
invariant(_leaderMode == LeaderMode::kWritablePrimary ||
_leaderMode == LeaderMode::kLeaderElect);
const auto previousLeaderMode = _leaderMode;
_setLeaderMode(LeaderMode::kAttemptingStepDown);
return {[this, previousLeaderMode] {
if (_leaderMode == TopologyCoordinator::LeaderMode::kAttemptingStepDown) {
_setLeaderMode(previousLeaderMode);
}
}};
}
void TopologyCoordinator::changeMemberState_forTest(const MemberState& newMemberState,
const Timestamp& electionTime) {
invariant(_selfIndex != -1);
if (newMemberState == getMemberState())
return;
switch (newMemberState.s) {
case MemberState::RS_PRIMARY:
_role = Role::kCandidate;
processWinElection(OID(), electionTime);
invariant(_role == Role::kLeader);
break;
case MemberState::RS_SECONDARY:
case MemberState::RS_ROLLBACK:
case MemberState::RS_RECOVERING:
case MemberState::RS_STARTUP2:
_role = Role::kFollower;
_followerMode = newMemberState.s;
if (_currentPrimaryIndex == _selfIndex) {
_currentPrimaryIndex = -1;
_setLeaderMode(LeaderMode::kNotLeader);
}
break;
case MemberState::RS_STARTUP:
updateConfig(ReplSetConfig(), -1, Date_t());
break;
default:
LOGV2_FATAL(21840,
"Cannot switch to state {newMemberState}",
"Cannot change to this member state",
"newMemberState"_attr = newMemberState);
MONGO_UNREACHABLE;
}
if (getMemberState() != newMemberState.s) {
LOGV2_FATAL(
21841,
"Expected to enter state {expectedMemberState} but am now in {actualMemberState}",
"Failed to change member state",
"expectedMemberState"_attr = newMemberState,
"actualMemberState"_attr = getMemberState());
MONGO_UNREACHABLE;
}
LOGV2(
21816, "{newMemberState}", "Changed member state", "newMemberState"_attr = newMemberState);
}
void TopologyCoordinator::setCurrentPrimary_forTest(int primaryIndex,
const Timestamp& electionTime) {
if (primaryIndex == _selfIndex) {
changeMemberState_forTest(MemberState::RS_PRIMARY);
} else {
if (_iAmPrimary()) {
changeMemberState_forTest(MemberState::RS_SECONDARY);
}
if (primaryIndex != -1) {
ReplSetHeartbeatResponse hbResponse;
hbResponse.setState(MemberState::RS_PRIMARY);
hbResponse.setElectionTime(electionTime);
hbResponse.setAppliedOpTimeAndWallTime(
{_memberData.at(primaryIndex).getHeartbeatAppliedOpTime(), Date_t() + Seconds(1)});
hbResponse.setSyncingTo(HostAndPort());
_memberData.at(primaryIndex)
.setUpValues(_memberData.at(primaryIndex).getLastHeartbeat(),
std::move(hbResponse));
}
_currentPrimaryIndex = primaryIndex;
}
}
const MemberConfig* TopologyCoordinator::getCurrentPrimaryMember() const {
if (_currentPrimaryIndex == -1)
return nullptr;
return &(_rsConfig.getMemberAt(_currentPrimaryIndex));
}
void TopologyCoordinator::populateAllMembersConfigVersionAndTerm_forTest() {
for (auto i = 0; i < _rsConfig.getNumMembers(); i++) {
auto memberConfig = _rsConfig.getMemberAt(i);
if (i < static_cast<int>(_memberData.size())) {
MemberData& member = _memberData.at(i);
member.setConfigVersion(_rsConfig.getConfigVersion());
member.setConfigTerm(_rsConfig.getConfigTerm());
member.setMemberId(memberConfig.getId());
}
}
}
TopologyCoordinator::RecentSyncSourceChanges*
TopologyCoordinator::getRecentSyncSourceChanges_forTest() {
return &_recentSyncSourceChanges;
}
std::string TopologyCoordinator::_getReplSetStatusString() {
// Construct a ReplSetStatusArgs using default parameters. Missing parameters will not be
// included in the status string.
ReplSetStatusArgs rsStatusArgs{
Date_t::now(), 0U, OpTime(), BSONObj(), BSONObj(), BSONObj(), boost::none};
BSONObjBuilder builder;
Status result(ErrorCodes::InternalError, "didn't set status in prepareStatusResponse");
prepareStatusResponse(rsStatusArgs, &builder, &result);
if (!result.isOK()) {
return str::stream() << "Could not get replSetGetStatus output: " << result.toString();
}
return str::stream() << "Current replSetGetStatus output: " << builder.done().toString();
}
void TopologyCoordinator::prepareStatusResponse(const ReplSetStatusArgs& rsStatusArgs,
BSONObjBuilder* response,
Status* result) {
// output for each member
std::vector<BSONObj> membersOut;
const MemberState myState = getMemberState();
const Date_t now = rsStatusArgs.now;
const OpTime lastOpApplied = getMyLastAppliedOpTime();
const Date_t lastOpAppliedWall = getMyLastAppliedOpTimeAndWallTime().wallTime;
const OpTime lastOpDurable = getMyLastDurableOpTime();
const Date_t lastOpDurableWall = getMyLastDurableOpTimeAndWallTime().wallTime;
const BSONObj& initialSyncStatus = rsStatusArgs.initialSyncStatus;
const BSONObj& electionCandidateMetrics = rsStatusArgs.electionCandidateMetrics;
const BSONObj& electionParticipantMetrics = rsStatusArgs.electionParticipantMetrics;
const boost::optional<Timestamp>& lastStableRecoveryTimestamp =
rsStatusArgs.lastStableRecoveryTimestamp;
if (_selfIndex == -1) {
// We're REMOVED or have an invalid config
response->append("state", static_cast<int>(myState.s));
response->append("stateStr", myState.toString());
response->append("uptime", static_cast<int>(rsStatusArgs.selfUptime));
appendOpTime(response, "optime", lastOpApplied);
response->appendDate("optimeDate",
Date_t::fromDurationSinceEpoch(Seconds(lastOpApplied.getSecs())));
if (_maintenanceModeCalls) {
response->append("maintenanceMode", _maintenanceModeCalls);
}
response->append("lastHeartbeatMessage", "");
response->append("syncSourceHost", "");
response->append("syncSourceId", -1);
response->append("infoMessage", _getHbmsg(now));
*result = Status(ErrorCodes::InvalidReplicaSetConfig,
"Our replica set config is invalid or we are not a member of it");
return;
}
for (std::vector<MemberData>::const_iterator it = _memberData.begin(); it != _memberData.end();
++it) {
const int itIndex = indexOfIterator(_memberData, it);
if (itIndex == _selfIndex) {
// add self
BSONObjBuilder bb;
bb.append("_id", _selfConfig().getId().getData());
bb.append("name", _selfConfig().getHostAndPort().toString());
bb.append("health", 1.0);
bb.append("state", static_cast<int>(myState.s));
bb.append("stateStr", myState.toString());
bb.append("uptime", static_cast<int>(rsStatusArgs.selfUptime));
if (!_selfConfig().isArbiter()) {
appendOpTime(&bb, "optime", lastOpApplied);
bb.appendDate("optimeDate",
Date_t::fromDurationSinceEpoch(Seconds(lastOpApplied.getSecs())));
bb.appendDate("lastAppliedWallTime", it->getLastAppliedWallTime());
bb.appendDate("lastDurableWallTime", it->getLastDurableWallTime());
}
if (!_syncSource.empty() && !_iAmPrimary()) {
bb.append("syncSourceHost", _syncSource.toString());
const MemberConfig* member = _rsConfig.findMemberByHostAndPort(_syncSource);
bb.append("syncSourceId", member ? member->getId().getData() : -1);
} else {
bb.append("syncSourceHost", "");
bb.append("syncSourceId", -1);
}
if (_maintenanceModeCalls) {
bb.append("maintenanceMode", _maintenanceModeCalls);
}
bb.append("infoMessage", _getHbmsg(now));
if (myState.primary()) {
bb.append("electionTime", _electionTime);
bb.appendDate("electionDate",
Date_t::fromDurationSinceEpoch(Seconds(_electionTime.getSecs())));
}
bb.appendNumber("configVersion", static_cast<long long>(_rsConfig.getConfigVersion()));
bb.appendNumber("configTerm", static_cast<long long>(_rsConfig.getConfigTerm()));
bb.append("self", true);
bb.append("lastHeartbeatMessage", "");
membersOut.push_back(bb.obj());
} else {
// add non-self member
const MemberConfig& itConfig = _rsConfig.getMemberAt(itIndex);
BSONObjBuilder bb;
bb.append("_id", itConfig.getId().getData());
bb.append("name", itConfig.getHostAndPort().toString());
double h = it->getHealth();
bb.append("health", h);
const MemberState state = it->getState();
bb.append("state", static_cast<int>(state.s));
if (h == 0) {
// if we can't connect the state info is from the past
// and could be confusing to show
bb.append("stateStr", "(not reachable/healthy)");
} else {
bb.append("stateStr", it->getState().toString());
}
const int uptime = static_cast<int>((
it->getUpSince() != Date_t() ? durationCount<Seconds>(now - it->getUpSince()) : 0));
bb.append("uptime", uptime);
if (!itConfig.isArbiter()) {
appendOpTime(&bb, "optime", it->getHeartbeatAppliedOpTime());
appendOpTime(&bb, "optimeDurable", it->getHeartbeatDurableOpTime());
bb.appendDate("optimeDate",
Date_t::fromDurationSinceEpoch(
Seconds(it->getHeartbeatAppliedOpTime().getSecs())));
bb.appendDate("optimeDurableDate",
Date_t::fromDurationSinceEpoch(
Seconds(it->getHeartbeatDurableOpTime().getSecs())));
bb.appendDate("lastAppliedWallTime", it->getLastAppliedWallTime());
bb.appendDate("lastDurableWallTime", it->getLastDurableWallTime());
}
bb.appendDate("lastHeartbeat", it->getLastHeartbeat());
bb.appendDate("lastHeartbeatRecv", it->getLastHeartbeatRecv());
Milliseconds ping = _getPing(itConfig.getHostAndPort());
bb.append("pingMs", durationCount<Milliseconds>(ping));
bb.append("lastHeartbeatMessage", it->getLastHeartbeatMsg());
if (it->hasAuthIssue()) {
bb.append("authenticated", false);
}
const HostAndPort& syncSource = it->getSyncSource();
if (!syncSource.empty() && !state.primary()) {
bb.append("syncSourceHost", syncSource.toString());
const MemberConfig* member = _rsConfig.findMemberByHostAndPort(syncSource);
bb.append("syncSourceId", member ? member->getId().getData() : -1);
} else {
bb.append("syncSourceHost", "");
bb.append("syncSourceId", -1);
}
bb.append("infoMessage", "");
if (state == MemberState::RS_PRIMARY) {
bb.append("electionTime", it->getElectionTime());
bb.appendDate(
"electionDate",
Date_t::fromDurationSinceEpoch(Seconds(it->getElectionTime().getSecs())));
}
bb.appendNumber("configVersion", it->getConfigVersion());
bb.appendNumber("configTerm", it->getConfigTerm());
membersOut.push_back(bb.obj());
}
}
// sort members bson
sort(membersOut.begin(), membersOut.end(), SimpleBSONObjComparator::kInstance.makeLessThan());
response->append("set", _rsConfig.isInitialized() ? _rsConfig.getReplSetName() : "");
response->append("date", now);
response->append("myState", myState.s);
response->append("term", _term);
if (rsStatusArgs.tooStale) {
response->append("tooStale", true);
}
// Add sync source info
if (!_syncSource.empty() && !myState.primary() && !myState.removed()) {
response->append("syncSourceHost", _syncSource.toString());
const MemberConfig* member = _rsConfig.findMemberByHostAndPort(_syncSource);
response->append("syncSourceId", member ? member->getId().getData() : -1);
} else {
response->append("syncSourceHost", "");
response->append("syncSourceId", -1);
}
if (_rsConfig.getConfigServer()) {
response->append("configsvr", true);
}
response->append("heartbeatIntervalMillis",
durationCount<Milliseconds>(_rsConfig.getHeartbeatInterval()));
response->append("majorityVoteCount", _rsConfig.getMajorityVoteCount());
response->append("writeMajorityCount", _rsConfig.getWriteMajority());
response->append("votingMembersCount", _rsConfig.getTotalVotingMembers());
response->append("writableVotingMembersCount", _rsConfig.getWritableVotingMembersCount());
// New optimes, to hold them all.
BSONObjBuilder optimes;
_lastCommittedOpTimeAndWallTime.opTime.append(&optimes, "lastCommittedOpTime");
optimes.appendDate("lastCommittedWallTime", _lastCommittedOpTimeAndWallTime.wallTime);
if (!rsStatusArgs.readConcernMajorityOpTime.isNull()) {
rsStatusArgs.readConcernMajorityOpTime.append(&optimes, "readConcernMajorityOpTime");
}
appendOpTime(&optimes, "appliedOpTime", lastOpApplied);
appendOpTime(&optimes, "durableOpTime", lastOpDurable);
optimes.appendDate("lastAppliedWallTime", lastOpAppliedWall);
optimes.appendDate("lastDurableWallTime", lastOpDurableWall);
response->append("optimes", optimes.obj());
if (lastStableRecoveryTimestamp) {
// Only include this field if the storage engine supports RTT.
response->append("lastStableRecoveryTimestamp", *lastStableRecoveryTimestamp);
}
if (!initialSyncStatus.isEmpty()) {
response->append("initialSyncStatus", initialSyncStatus);
}
if (!electionCandidateMetrics.isEmpty()) {
response->append("electionCandidateMetrics", electionCandidateMetrics);
}
if (!electionParticipantMetrics.isEmpty()) {
response->append("electionParticipantMetrics", electionParticipantMetrics);
}
response->append("members", membersOut);
*result = Status::OK();
}
StatusWith<BSONObj> TopologyCoordinator::prepareReplSetUpdatePositionCommand(
OpTime currentCommittedSnapshotOpTime) const {
BSONObjBuilder cmdBuilder;
invariant(_rsConfig.isInitialized());
// Do not send updates if we have been removed from the config.
if (_selfIndex == -1) {
return Status(ErrorCodes::NodeNotFound,
"This node is not in the current replset configuration.");
}
cmdBuilder.append(UpdatePositionArgs::kCommandFieldName, 1);
// Create an array containing objects each live member connected to us and for ourself.
BSONArrayBuilder arrayBuilder(cmdBuilder.subarrayStart("optimes"));
for (const auto& memberData : _memberData) {
if (memberData.getLastAppliedOpTime().isNull()) {
// Don't include info on members we haven't heard from yet.
continue;
}
// Don't include members we think are down.
if (!memberData.isSelf() && memberData.lastUpdateStale()) {
continue;
}
BSONObjBuilder entry(arrayBuilder.subobjStart());
memberData.getLastDurableOpTime().append(&entry,
UpdatePositionArgs::kDurableOpTimeFieldName);
entry.appendDate(UpdatePositionArgs::kDurableWallTimeFieldName,
memberData.getLastDurableWallTime());
memberData.getLastAppliedOpTime().append(&entry,
UpdatePositionArgs::kAppliedOpTimeFieldName);
entry.appendDate(UpdatePositionArgs::kAppliedWallTimeFieldName,
memberData.getLastAppliedWallTime());
entry.append(UpdatePositionArgs::kMemberIdFieldName, memberData.getMemberId().getData());
entry.append(UpdatePositionArgs::kConfigVersionFieldName, _rsConfig.getConfigVersion());
}
arrayBuilder.done();
// Add metadata to command
prepareReplSetMetadata(currentCommittedSnapshotOpTime)
.writeToMetadata(&cmdBuilder)
.transitional_ignore();
return cmdBuilder.obj();
}
void TopologyCoordinator::fillMemberData(BSONObjBuilder* result) {
BSONArrayBuilder replicationProgress(result->subarrayStart("replicationProgress"));
{
for (const auto& memberData : _memberData) {
BSONObjBuilder entry(replicationProgress.subobjStart());
entry.append("host", memberData.getHostAndPort().toString());
const auto lastDurableOpTime = memberData.getLastDurableOpTime();
entry.append("optime", lastDurableOpTime.toBSON());
const auto lastAppliedOpTime = memberData.getLastAppliedOpTime();
entry.append("lastAppliedOpTime", lastAppliedOpTime.toBSON());
const auto heartbeatAppliedOpTime = memberData.getHeartbeatAppliedOpTime();
entry.append("heartbeatAppliedOpTime", heartbeatAppliedOpTime.toBSON());
const auto heartbeatDurableOpTime = memberData.getHeartbeatDurableOpTime();
entry.append("heartbeatDurableOpTime", heartbeatDurableOpTime.toBSON());
if (_selfIndex >= 0) {
entry.append("memberId", memberData.getMemberId().getData());
}
}
}
}
void TopologyCoordinator::fillHelloForReplSet(std::shared_ptr<HelloResponse> response,
const StringData& horizonString) const {
invariant(_rsConfig.isInitialized());
response->setTopologyVersion(getTopologyVersion());
const MemberState myState = getMemberState();
response->setReplSetName(_rsConfig.getReplSetName());
if (myState.removed()) {
response->markAsNoConfig();
return;
}
invariant(!_rsConfig.members().empty());
for (const auto& member : _rsConfig.members()) {
if (member.isHidden() || member.getSecondaryDelay() > Seconds{0}) {
continue;
}
auto hostView = member.getHostAndPort(horizonString);
if (member.isElectable()) {
response->addHost(std::move(hostView));
} else if (member.isArbiter()) {
response->addArbiter(std::move(hostView));
} else {
response->addPassive(std::move(hostView));
}
}
response->setReplSetVersion(_rsConfig.getConfigVersion());
// Depending on whether or not the client sent a hello/isMaster request, we set the
// "isWritablePrimary"/"ismaster" field to false if we are not primary. If we're stepping down,
// we're waiting for the Replication State Transition Lock before we can change to secondary,
// but we should report "isWritablePrimary"/"ismaster" false to indicate that we can't accept
// new writes.
response->setIsWritablePrimary(myState.primary() && !isSteppingDown());
response->setIsSecondary(myState.secondary());
const MemberConfig* curPrimary = getCurrentPrimaryMember();
if (curPrimary) {
response->setPrimary(curPrimary->getHostAndPort(horizonString));
}
const MemberConfig& selfConfig = _rsConfig.getMemberAt(_selfIndex);
if (selfConfig.isArbiter()) {
response->setIsArbiterOnly(true);
} else if (selfConfig.getPriority() == 0) {
response->setIsPassive(true);
}
if (selfConfig.getSecondaryDelay() > Seconds(0)) {
response->setSecondaryDelaySecs(selfConfig.getSecondaryDelay());
}
if (selfConfig.isHidden()) {
response->setIsHidden(true);
}
if (!selfConfig.shouldBuildIndexes()) {
response->setShouldBuildIndexes(false);
}
const ReplSetTagConfig tagConfig = _rsConfig.getTagConfig();
if (selfConfig.hasTags()) {
for (MemberConfig::TagIterator tag = selfConfig.tagsBegin(); tag != selfConfig.tagsEnd();
++tag) {
std::string tagKey = tagConfig.getTagKey(*tag);
if (tagKey[0] == '$') {
// Filter out internal tags
continue;
}
response->addTag(tagKey, tagConfig.getTagValue(*tag));
}
}
response->setMe(selfConfig.getHostAndPort(horizonString));
if (_iAmPrimary()) {
response->setElectionId(_electionId);
}
}
StatusWith<TopologyCoordinator::PrepareFreezeResponseResult>
TopologyCoordinator::prepareFreezeResponse(Date_t now, int secs, BSONObjBuilder* response) {
if (_role != TopologyCoordinator::Role::kFollower) {
static constexpr char msg[] = "Cannot freeze node when primary or running for election";
const auto state =
(_role == TopologyCoordinator::Role::kLeader ? "Primary" : "Running-Election");
LOGV2(21817, msg, "state"_attr = state);
return Status(ErrorCodes::NotSecondary, str::stream() << msg << ", state: " << state);
}
if (secs == 0) {
_stepDownUntil = now;
LOGV2(21818, "Unfreezing");
response->append("info", "unfreezing");
return PrepareFreezeResponseResult::kSingleNodeSelfElect;
} else {
if (secs == 1)
response->append("warning", "you really want to freeze for only 1 second?");
_stepDownUntil = std::max(_stepDownUntil, now + Seconds(secs));
LOGV2(21819, "'freezing' for {freezeSecs} seconds", "Freezing", "freezeSecs"_attr = secs);
}
return PrepareFreezeResponseResult::kNoAction;
}
Timestamp TopologyCoordinator::getElectionTime() const {
return _electionTime;
}
OID TopologyCoordinator::getElectionId() const {
return _electionId;
}
int TopologyCoordinator::getCurrentPrimaryIndex() const {
return _currentPrimaryIndex;
}
Date_t TopologyCoordinator::getStepDownTime() const {
return _stepDownUntil;
}
void TopologyCoordinator::_updateHeartbeatDataForReconfig(const ReplSetConfig& newConfig,
int selfIndex,
Date_t now) {
std::vector<MemberData> oldHeartbeats;
_memberData.swap(oldHeartbeats);
int index = 0;
for (ReplSetConfig::MemberIterator it = newConfig.membersBegin(); it != newConfig.membersEnd();
++it, ++index) {
const MemberConfig& newMemberConfig = *it;
MemberData newHeartbeatData;
for (auto&& oldMemberData : oldHeartbeats) {
if ((oldMemberData.getMemberId() == newMemberConfig.getId() &&
oldMemberData.getHostAndPort() == newMemberConfig.getHostAndPort()) ||
(index == selfIndex && oldMemberData.isSelf())) {
// This member existed in the old config with the same member ID and
// HostAndPort, so copy its heartbeat data over.
newHeartbeatData = oldMemberData;
break;
}
}
newHeartbeatData.setConfigIndex(index);
newHeartbeatData.setIsSelf(index == selfIndex);
newHeartbeatData.setHostAndPort(newMemberConfig.getHostAndPort());
newHeartbeatData.setMemberId(newMemberConfig.getId());
_memberData.push_back(newHeartbeatData);
}
if (selfIndex < 0) {
// It's necessary to have self member data even if self isn't in the configuration.
// We don't need data for the other nodes (which no longer know about us, or soon won't)
_memberData.clear();
// We're not in the config, we can't sync any more.
_clearSyncSource();
// We shouldn't get a sync source until we've received pings for our new config.
pingsInConfig = 0;
MemberData newHeartbeatData;
for (auto&& oldMemberData : oldHeartbeats) {
if (oldMemberData.isSelf()) {
newHeartbeatData = oldMemberData;
break;
}
}
newHeartbeatData.setConfigIndex(-1);
newHeartbeatData.setIsSelf(true);
_memberData.push_back(newHeartbeatData);
}
}
// This function installs a new config object and recreates MemberData objects
// that reflect the new config.
void TopologyCoordinator::updateConfig(const ReplSetConfig& newConfig, int selfIndex, Date_t now) {
invariant(_role != Role::kCandidate);
invariant(selfIndex < newConfig.getNumMembers());
// Reset term on startup.
if (!_rsConfig.isInitialized()) {
_term = OpTime::kInitialTerm;
LOGV2_DEBUG(21820,
1,
"Updated term in topology coordinator to {term} due to new config",
"Updated term in topology coordinator due to new config",
"term"_attr = _term);
}
_updateHeartbeatDataForReconfig(newConfig, selfIndex, now);
_rsConfig = newConfig;
_selfIndex = selfIndex;
if (_selfIndex >= 0) {
// If selfIndex is -1, we are removed from the current config and clear our _memberData.
// Do not repopulate it.
_memberData.at(_selfIndex).setConfigVersion(_rsConfig.getConfigVersion());
_memberData.at(_selfIndex).setConfigTerm(_rsConfig.getConfigTerm());
}
_forceSyncSourceIndex = -1;
if (_role == Role::kLeader) {
if (_selfIndex == -1) {
LOGV2(21821, "Could not remain primary because no longer a member of the replica set");
} else if (!_selfConfig().isElectable()) {
LOGV2(21822, "Could not remain primary because no longer electable");
} else {
// Don't stepdown if you don't have to.
_currentPrimaryIndex = _selfIndex;
return;
}
_role = Role::kFollower;
_setLeaderMode(LeaderMode::kNotLeader);
}
// By this point we know we are in Role::kFollower
_currentPrimaryIndex = -1; // force secondaries to re-detect who the primary is
}
std::string TopologyCoordinator::_getHbmsg(Date_t now) const {
// ignore messages over 2 minutes old
if ((now - _hbmsgTime) > Seconds{120}) {
return "";
}
return _hbmsg;
}
void TopologyCoordinator::setMyHeartbeatMessage(const Date_t now, const std::string& message) {
_hbmsgTime = now;
_hbmsg = message;
}
const MemberConfig& TopologyCoordinator::_selfConfig() const {
return _rsConfig.getMemberAt(_selfIndex);
}
const MemberData& TopologyCoordinator::_selfMemberData() const {
return _memberData[_selfMemberDataIndex()];
}
MemberData& TopologyCoordinator::_selfMemberData() {
return _memberData[_selfMemberDataIndex()];
}
int TopologyCoordinator::_selfMemberDataIndex() const {
invariant(!_memberData.empty());
if (_selfIndex >= 0)
return _selfIndex;
// If there is no config or we're not in the config, the first-and-only entry should be for
// self.
return 0;
}
TopologyCoordinator::UnelectableReasonMask TopologyCoordinator::_getUnelectableReason(
int index) const {
invariant(index != _selfIndex);
const MemberConfig& memberConfig = _rsConfig.getMemberAt(index);
const MemberData& hbData = _memberData.at(index);
UnelectableReasonMask result = None;
if (memberConfig.isArbiter()) {
result |= ArbiterIAm;
}
if (memberConfig.getPriority() <= 0) {
result |= NoPriority;
}
if (hbData.getState() != MemberState::RS_SECONDARY) {
result |= NotSecondary;
}
if (hbData.up() && hbData.isUnelectable()) {
result |= StepDownPeriodActive;
}
invariant(result || memberConfig.isElectable());
return result;
}
TopologyCoordinator::UnelectableReasonMask TopologyCoordinator::_getMyUnelectableReason(
const Date_t now, StartElectionReasonEnum reason) const {
UnelectableReasonMask result = None;
const OpTime lastApplied = getMyLastAppliedOpTime();
if (lastApplied.isNull()) {
result |= NoData;
}
if (!_aMajoritySeemsToBeUp()) {
result |= CannotSeeMajority;
}
if (_selfIndex == -1) {
result |= NotInitialized;
return result;
}
if (_selfConfig().isArbiter()) {
result |= ArbiterIAm;
}
if (_selfConfig().getPriority() <= 0) {
result |= NoPriority;
}
if (_stepDownUntil > now) {
result |= StepDownPeriodActive;
}
// Cannot be electable unless secondary or already primary
if (!getMemberState().secondary() && !_iAmPrimary()) {
result |= NotSecondary;
}
if (reason == StartElectionReasonEnum::kPriorityTakeover &&
!_amIFreshEnoughForPriorityTakeover()) {
result |= NotCloseEnoughToLatestForPriorityTakeover;
}
if (reason == StartElectionReasonEnum::kCatchupTakeover &&
!_amIFreshEnoughForCatchupTakeover()) {
result |= NotFreshEnoughForCatchupTakeover;
}
return result;
}
std::string TopologyCoordinator::_getUnelectableReasonString(const UnelectableReasonMask ur) const {
invariant(ur);
str::stream ss;
bool hasWrittenToStream = false;
if (ur & NoData) {
ss << "node has no applied oplog entries";
hasWrittenToStream = true;
}
if (ur & CannotSeeMajority) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "I cannot see a majority";
}
if (ur & ArbiterIAm) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "member is an arbiter";
}
if (ur & NoPriority) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "member has zero priority";
}
if (ur & StepDownPeriodActive) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "I am still waiting for stepdown period to end at "
<< dateToISOStringLocal(_stepDownUntil);
}
if (ur & NotSecondary) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "member is not currently a secondary";
}
if (ur & NotCloseEnoughToLatestForPriorityTakeover) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "member is not caught up enough to the most up-to-date member to call for priority "
"takeover - must be within "
<< gPriorityTakeoverFreshnessWindowSeconds << " seconds";
}
if (ur & NotFreshEnoughForCatchupTakeover) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "member is either not the most up-to-date member or not ahead of the primary, and "
"therefore cannot call for catchup takeover";
}
if (ur & NotInitialized) {
if (hasWrittenToStream) {
ss << "; ";
}
hasWrittenToStream = true;
ss << "node is not a member of a valid replica set configuration";
}
if (!hasWrittenToStream) {
LOGV2_FATAL(26011,
"Invalid UnelectableReasonMask value 0x{value}",
"Invalid UnelectableReasonMask value",
"value"_attr = unsignedHex(ur));
}
ss << " (mask 0x" << unsignedHex(ur) << ")";
return ss;
}
Milliseconds TopologyCoordinator::_getPing(const HostAndPort& host) {
return _pings[host].getMillis();
}
void TopologyCoordinator::setPing_forTest(const HostAndPort& host, const Milliseconds ping) {
PingStats& pingStats = _pings[host];
pingStats.set_forTest(ping);
}
void TopologyCoordinator::_setElectionTime(const Timestamp& newElectionTime) {
_electionTime = newElectionTime;
}
bool TopologyCoordinator::isSteppingDownUnconditionally() const {
return _leaderMode == LeaderMode::kSteppingDown;
}
bool TopologyCoordinator::isSteppingDown() const {
return isSteppingDownUnconditionally() || _leaderMode == LeaderMode::kAttemptingStepDown;
}
void TopologyCoordinator::_setLeaderMode(TopologyCoordinator::LeaderMode newMode) {
// Invariants for valid state transitions.
switch (_leaderMode) {
case LeaderMode::kNotLeader:
invariant(newMode == LeaderMode::kLeaderElect);
break;
case LeaderMode::kLeaderElect:
invariant(newMode == LeaderMode::kNotLeader || // TODO(SERVER-30852): remove this case
newMode == LeaderMode::kWritablePrimary ||
newMode == LeaderMode::kAttemptingStepDown ||
newMode == LeaderMode::kSteppingDown);
break;
case LeaderMode::kWritablePrimary:
invariant(newMode == LeaderMode::kNotLeader || // TODO(SERVER-30852): remove this case
newMode == LeaderMode::kAttemptingStepDown ||
newMode == LeaderMode::kSteppingDown);
break;
case LeaderMode::kAttemptingStepDown:
invariant(newMode == LeaderMode::kNotLeader ||
newMode == LeaderMode::kWritablePrimary ||
newMode == LeaderMode::kSteppingDown || newMode == LeaderMode::kLeaderElect);
break;
case LeaderMode::kSteppingDown:
invariant(newMode == LeaderMode::kNotLeader);
break;
}
_leaderMode = std::move(newMode);
}
MemberState TopologyCoordinator::getMemberState() const {
if (_selfIndex == -1) {
if (_rsConfig.isInitialized()) {
return MemberState::RS_REMOVED;
}
return MemberState::RS_STARTUP;
}
if (_rsConfig.getConfigServer()) {
if (!_options.clusterRole.has(ClusterRole::ConfigServer) &&
!skipShardingConfigurationChecks) {
return MemberState::RS_REMOVED;
} else {
invariant(_storageEngineSupportsReadCommitted != ReadCommittedSupport::kUnknown);
if (_storageEngineSupportsReadCommitted == ReadCommittedSupport::kNo) {
return MemberState::RS_REMOVED;
}
}
} else {
if (_options.clusterRole.has(ClusterRole::ConfigServer) &&
!skipShardingConfigurationChecks) {
return MemberState::RS_REMOVED;
}
}
if (_role == Role::kLeader) {
invariant(_currentPrimaryIndex == _selfIndex);
invariant(_leaderMode != LeaderMode::kNotLeader);
return MemberState::RS_PRIMARY;
}
const MemberConfig& myConfig = _selfConfig();
if (myConfig.isArbiter()) {
return MemberState::RS_ARBITER;
}
if (((_maintenanceModeCalls > 0) || (_hasOnlyAuthErrorUpHeartbeats(_memberData, _selfIndex))) &&
(_followerMode == MemberState::RS_SECONDARY)) {
return MemberState::RS_RECOVERING;
}
return _followerMode;
}
std::vector<MemberData> TopologyCoordinator::getMemberData() const {
return _memberData;
}
bool TopologyCoordinator::canAcceptWrites() const {
return _leaderMode == LeaderMode::kWritablePrimary;
}
void TopologyCoordinator::setElectionInfo(OID electionId, Timestamp electionOpTime) {
invariant(_role == Role::kLeader);
_electionTime = electionOpTime;
_electionId = electionId;
}
void TopologyCoordinator::processWinElection(OID electionId, Timestamp electionOpTime) {
invariant(_role == Role::kCandidate);
invariant(_leaderMode == LeaderMode::kNotLeader);
_role = Role::kLeader;
_setLeaderMode(LeaderMode::kLeaderElect);
setElectionInfo(electionId, electionOpTime);
_currentPrimaryIndex = _selfIndex;
_clearSyncSource();
_forceSyncSourceIndex = -1;
// Prevent last committed optime from updating until we finish draining.
_firstOpTimeOfMyTerm =
OpTime(Timestamp(std::numeric_limits<int>::max(), 0), std::numeric_limits<int>::max());
}
void TopologyCoordinator::processLoseElection() {
invariant(_role == Role::kCandidate);
invariant(_leaderMode == LeaderMode::kNotLeader);
const HostAndPort syncSourceAddress = getSyncSourceAddress();
_electionTime = Timestamp(0, 0);
_electionId = OID();
_role = Role::kFollower;
}
bool TopologyCoordinator::tryToStartStepDown(
long long termAtStart, Date_t now, Date_t waitUntil, Date_t stepDownUntil, bool force) {
if (_role != Role::kLeader || _leaderMode == LeaderMode::kSteppingDown ||
_term != termAtStart) {
uasserted(ErrorCodes::PrimarySteppedDown,
"While waiting for secondaries to catch up before stepping down, "
"this node decided to step down for other reasons");
}
invariant(_leaderMode == LeaderMode::kAttemptingStepDown);
if (now >= stepDownUntil) {
uasserted(ErrorCodes::ExceededTimeLimit,
"By the time we were ready to step down, we were already past the "
"time we were supposed to step down until");
}
if (!_canCompleteStepDownAttempt(now, waitUntil, force)) {
// Stepdown attempt failed.
// Check waitUntil after at least one stepdown attempt, so that stepdown could succeed even
// if secondaryCatchUpPeriodSecs == 0.
if (now >= waitUntil) {
uasserted(ErrorCodes::ExceededTimeLimit,
str::stream() << "No electable secondaries caught up as of "
<< dateToISOStringLocal(now)
<< ". Please use the replSetStepDown command with the argument "
<< "{force: true} to force node to step down.");
}
// Stepdown attempt failed, but in a way that can be retried
return false;
}
// Stepdown attempt success!
_stepDownUntil = stepDownUntil;
prepareForUnconditionalStepDown();
return true;
}
bool TopologyCoordinator::_canCompleteStepDownAttempt(Date_t now, Date_t waitUntil, bool force) {
const bool forceNow = force && (now >= waitUntil);
if (forceNow) {
return true;
}
return isSafeToStepDown();
}
bool TopologyCoordinator::_isCaughtUpAndElectable(int memberIndex, OpTime lastApplied) {
if (_getUnelectableReason(memberIndex)) {
return false;
}
return (_memberData.at(memberIndex).getLastAppliedOpTime() >= lastApplied);
}
bool TopologyCoordinator::isSafeToStepDown() {
if (!_rsConfig.isInitialized() || _selfIndex < 0) {
return false;
}
OpTime lastApplied = getMyLastAppliedOpTime();
// No need to wait for secondaries to catch up if this node has not yet written in the current
// term.
if (lastApplied.getTerm() != _term) {
return true;
}
auto tagStatus = _rsConfig.findCustomWriteMode(ReplSetConfig::kMajorityWriteConcernModeName);
invariant(tagStatus.isOK());
// Check if a majority of nodes have reached the last applied optime.
if (!haveTaggedNodesReachedOpTime(lastApplied, tagStatus.getValue(), false)) {
return false;
}
// Now check that we also have at least one caught up node that is electable.
for (int memberIndex = 0; memberIndex < _rsConfig.getNumMembers(); memberIndex++) {
// ignore your self
if (memberIndex == _selfIndex) {
continue;
}
if (_isCaughtUpAndElectable(memberIndex, lastApplied)) {
return true;
}
}
return false;
}
int TopologyCoordinator::chooseElectionHandoffCandidate() {
OpTime lastApplied = getMyLastAppliedOpTime();
int bestCandidateIndex = -1;
int highestPriority = -1;
for (int memberIndex = 0; memberIndex < _rsConfig.getNumMembers(); memberIndex++) {
// Skip your own member index.
if (memberIndex == _selfIndex) {
continue;
}
// Skip this node if it is not eligible to become primary. This includes nodes with
// priority 0.
if (!_isCaughtUpAndElectable(memberIndex, lastApplied)) {
continue;
}
// Only update best if priority is strictly greater. This guarantees that
// we will pick the member with the lowest index in case of a tie. Note that
// member priority is always a non-negative number.
auto memberPriority = _rsConfig.getMemberAt(memberIndex).getPriority();
if (memberPriority > highestPriority) {
bestCandidateIndex = memberIndex;
highestPriority = memberPriority;
}
}
// This is the most suitable node.
return bestCandidateIndex;
}
void TopologyCoordinator::setFollowerMode(MemberState::MS newMode) {
invariant(_role == Role::kFollower);
switch (newMode) {
case MemberState::RS_RECOVERING:
case MemberState::RS_ROLLBACK:
case MemberState::RS_SECONDARY:
case MemberState::RS_STARTUP2:
_followerMode = newMode;
break;
default:
MONGO_UNREACHABLE;
}
}
bool TopologyCoordinator::isElectableNodeInSingleNodeReplicaSet() const {
auto isSingleNode = _rsConfig.getNumMembers() == 1 && _selfIndex == 0;
// Single node replset must be electable.
invariant(!isSingleNode || _rsConfig.getMemberAt(_selfIndex).isElectable());
return (getMemberState() == MemberState::RS_SECONDARY) && isSingleNode;
}
void TopologyCoordinator::finishUnconditionalStepDown() {
invariant(_leaderMode == LeaderMode::kSteppingDown);
int remotePrimaryIndex = -1;
for (std::vector<MemberData>::const_iterator it = _memberData.begin(); it != _memberData.end();
++it) {
const int itIndex = indexOfIterator(_memberData, it);
if (itIndex == _selfIndex) {
continue;
}
if (it->getState().primary() && it->up()) {
if (remotePrimaryIndex != -1) {
// two other nodes think they are primary (asynchronously polled)
// -- wait for things to settle down.
remotePrimaryIndex = -1;
LOGV2_WARNING(21838, "Two remote primaries (transiently)");
break;
}
remotePrimaryIndex = itIndex;
}
}
_stepDownSelfAndReplaceWith(remotePrimaryIndex);
}
void TopologyCoordinator::_stepDownSelfAndReplaceWith(int newPrimary) {
invariant(_role == Role::kLeader);
invariant(_selfIndex != -1);
invariant(_selfIndex != newPrimary);
invariant(_selfIndex == _currentPrimaryIndex);
_currentPrimaryIndex = newPrimary;
_role = Role::kFollower;
_setLeaderMode(LeaderMode::kNotLeader);
}
bool TopologyCoordinator::updateLastCommittedOpTimeAndWallTime() {
// If we're not primary or we're stepping down due to learning of a new term then we must not
// advance the commit point. If we are stepping down due to a user request, however, then it
// is safe to advance the commit point, and in fact we must since the stepdown request may be
// waiting for the commit point to advance enough to be able to safely complete the step down.
if (!_iAmPrimary() || _leaderMode == LeaderMode::kSteppingDown) {
return false;
}
// Whether we use the applied or durable OpTime for the commit point is decided here.
const bool useDurableOpTime = _rsConfig.getWriteConcernMajorityShouldJournal();
std::vector<OpTimeAndWallTime> votingNodesOpTimesAndWallTimes;
for (const auto& memberData : _memberData) {
int memberIndex = memberData.getConfigIndex();
invariant(memberIndex >= 0);
const auto& memberConfig = _rsConfig.getMemberAt(memberIndex);
if (memberConfig.isVoter()) {
const OpTimeAndWallTime durableOpTime = {memberData.getLastDurableOpTime(),
memberData.getLastDurableWallTime()};
const OpTimeAndWallTime appliedOpTime = {memberData.getLastAppliedOpTime(),
memberData.getLastAppliedWallTime()};
const OpTimeAndWallTime opTime = useDurableOpTime ? durableOpTime : appliedOpTime;
votingNodesOpTimesAndWallTimes.push_back(opTime);
}
}
invariant(votingNodesOpTimesAndWallTimes.size() > 0);
if (votingNodesOpTimesAndWallTimes.size() <
static_cast<unsigned long>(_rsConfig.getWriteMajority())) {
return false;
}
std::sort(votingNodesOpTimesAndWallTimes.begin(), votingNodesOpTimesAndWallTimes.end());
// need the majority to have this OpTime
OpTimeAndWallTime committedOpTime =
votingNodesOpTimesAndWallTimes[votingNodesOpTimesAndWallTimes.size() -
_rsConfig.getWriteMajority()];
const bool fromSyncSource = false;
return advanceLastCommittedOpTimeAndWallTime(committedOpTime, fromSyncSource);
}
bool TopologyCoordinator::advanceLastCommittedOpTimeAndWallTime(OpTimeAndWallTime committedOpTime,
bool fromSyncSource,
bool forInitiate) {
if (forInitiate) {
// Force update in the replSetInitiate case.
LOGV2_INFO(5872100,
"Updating commit point for initiate",
"_lastCommittedOpTimeAndWallTime"_attr = committedOpTime);
_lastCommittedOpTimeAndWallTime = committedOpTime;
return true;
}
if (_selfIndex == -1) {
// The config hasn't been installed or we are not in the config. This could happen
// on heartbeats before installing a config.
return false;
}
// This check is performed to ensure primaries do not commit an OpTime from a previous term.
if (_iAmPrimary() && committedOpTime.opTime < _firstOpTimeOfMyTerm) {
LOGV2_DEBUG(21823,
1,
"Ignoring older committed snapshot from before I became primary, optime: "
"{committedOpTime}, firstOpTimeOfMyTerm: {firstOpTimeOfMyTerm}",
"Ignoring older committed snapshot from before I became primary",
"committedOpTime"_attr = committedOpTime.opTime,
"firstOpTimeOfMyTerm"_attr = _firstOpTimeOfMyTerm);
return false;
}
// Arbiters don't have data so they always advance their commit point via heartbeats.
if (!_selfConfig().isArbiter() &&
getMyLastAppliedOpTime().getTerm() != committedOpTime.opTime.getTerm()) {
if (fromSyncSource) {
committedOpTime = std::min(committedOpTime, getMyLastAppliedOpTimeAndWallTime());
} else {
LOGV2_DEBUG(21824,
1,
"Ignoring commit point with different term than my lastApplied, since it "
"may "
"not be on the same oplog branch as mine. optime: {committedOpTime}, my "
"last applied: {myLastAppliedOpTimeAndWallTime}",
"Ignoring commit point with different term than my lastApplied, since it "
"may not be on the same oplog branch as mine",
"committedOpTime"_attr = committedOpTime,
"myLastAppliedOpTimeAndWallTime"_attr =
getMyLastAppliedOpTimeAndWallTime());
return false;
}
}
if (committedOpTime.opTime == _lastCommittedOpTimeAndWallTime.opTime) {
return false; // Hasn't changed, so ignore it.
}
if (committedOpTime.opTime < _lastCommittedOpTimeAndWallTime.opTime) {
LOGV2_DEBUG(21825,
1,
"Ignoring older committed snapshot optime: {committedOpTime}, "
"currentCommittedOpTime: {currentCommittedOpTime}",
"Ignoring older committed snapshot optime",
"committedOpTime"_attr = committedOpTime,
"currentCommittedOpTime"_attr = _lastCommittedOpTimeAndWallTime);
return false;
}
if (committedOpTime.opTime.getTerm() != _lastCommittedOpTimeAndWallTime.opTime.getTerm()) {
LOGV2(6795400,
"Advancing committed opTime to a new term",
"newCommittedOpTime"_attr = committedOpTime.opTime,
"newCommittedWallime"_attr = committedOpTime.wallTime,
"oldTerm"_attr = _lastCommittedOpTimeAndWallTime.opTime.getTerm());
}
LOGV2_DEBUG(21826,
2,
"Updating _lastCommittedOpTimeAndWallTime to {_lastCommittedOpTimeAndWallTime}",
"Updating _lastCommittedOpTimeAndWallTime",
"_lastCommittedOpTimeAndWallTime"_attr = committedOpTime);
_lastCommittedOpTimeAndWallTime = committedOpTime;
return true;
}
OpTime TopologyCoordinator::getLastCommittedOpTime() const {
return _lastCommittedOpTimeAndWallTime.opTime;
}
OpTimeAndWallTime TopologyCoordinator::getLastCommittedOpTimeAndWallTime() const {
return _lastCommittedOpTimeAndWallTime;
}
bool TopologyCoordinator::canCompleteTransitionToPrimary(long long termWhenDrainCompleted) const {
if (termWhenDrainCompleted != _term) {
return false;
}
// Allow completing the transition to primary even when in the middle of a stepdown attempt,
// in case the stepdown attempt fails.
if (_leaderMode != LeaderMode::kLeaderElect && _leaderMode != LeaderMode::kAttemptingStepDown &&
_leaderMode != LeaderMode::kSteppingDown) {
return false;
}
return true;
}
void TopologyCoordinator::completeTransitionToPrimary(const OpTime& firstOpTimeOfTerm) {
invariant(canCompleteTransitionToPrimary(firstOpTimeOfTerm.getTerm()));
if (_leaderMode == LeaderMode::kLeaderElect) {
_setLeaderMode(LeaderMode::kWritablePrimary);
}
_firstOpTimeOfMyTerm = firstOpTimeOfTerm;
}
void TopologyCoordinator::adjustMaintenanceCountBy(int inc) {
invariant(_role == Role::kFollower);
_maintenanceModeCalls += inc;
invariant(_maintenanceModeCalls >= 0);
}
void TopologyCoordinator::resetMaintenanceCount() {
invariant(_role == Role::kFollower);
_maintenanceModeCalls = 0;
}
int TopologyCoordinator::getMaintenanceCount() const {
return _maintenanceModeCalls;
}
TopologyCoordinator::UpdateTermResult TopologyCoordinator::updateTerm(long long term, Date_t now) {
if (term <= _term) {
return TopologyCoordinator::UpdateTermResult::kAlreadyUpToDate;
}
// Don't run election if we just stood up or learned about a new term.
_electionSleepUntil = now + _rsConfig.getElectionTimeoutPeriod();
// Don't update the term just yet if we are going to step down, as we don't want to report
// that we are primary in the new term.
if (_iAmPrimary()) {
return TopologyCoordinator::UpdateTermResult::kTriggerStepDown;
}
LOGV2(21827, "Updating term", "oldTerm"_attr = _term, "newTerm"_attr = term);
_term = term;
return TopologyCoordinator::UpdateTermResult::kUpdatedTerm;
}
long long TopologyCoordinator::getTerm() const {
return _term;
}
bool TopologyCoordinator::shouldChangeSyncSource(const HostAndPort& currentSource,
const rpc::ReplSetMetadata& replMetadata,
const rpc::OplogQueryMetadata& oqMetadata,
const OpTime& lastOpTimeFetched,
Date_t now) const {
// Methodology:
// If there exists a viable sync source member other than currentSource, whose oplog has
// reached an optime greater than _options.maxSyncSourceLagSecs later than currentSource's,
// return true.
// If the currentSource has the same replication progress as we do and has no source for further
// progress, return true.
auto [initialDecision, currentSourceIndex] =
_shouldChangeSyncSourceInitialChecks(currentSource);
if (initialDecision != ChangeSyncSourceDecision::kMaybe) {
return initialDecision == ChangeSyncSourceDecision::kYes;
}
if (!replMetadata.getIsPrimary() &&
_shouldChangeSyncSourceDueToNewPrimary(currentSource, currentSourceIndex)) {
return true;
}
OpTime currentSourceOpTime =
std::max(oqMetadata.getLastOpApplied(),
_memberData.at(currentSourceIndex).getHeartbeatAppliedOpTime());
fassert(4612000, !currentSourceOpTime.isNull());
int syncSourceIndex = oqMetadata.getSyncSourceIndex();
std::string syncSourceHost = oqMetadata.getSyncSourceHost();
// Change sync source if they are not ahead of us, and don't have a sync source,
// unless they are primary.
if (_shouldChangeSyncSourceDueToSourceNotAhead(currentSource,
syncSourceIndex,
replMetadata.getIsPrimary(),
currentSourceOpTime,
lastOpTimeFetched))
return true;
if (_shouldChangeSyncSourceToBreakCycle(
currentSource, syncSourceHost, syncSourceIndex, currentSourceOpTime, lastOpTimeFetched))
return true;
if (_shouldChangeSyncSourceDueToLag(currentSource, currentSourceOpTime, lastOpTimeFetched, now))
return true;
if (_shouldChangeSyncSourceDueToBetterEligibleSource(
currentSource, currentSourceIndex, lastOpTimeFetched, now))
return true;
return false;
}
bool TopologyCoordinator::shouldChangeSyncSourceOnError(const HostAndPort& currentSource,
const OpTime& lastOpTimeFetched,
Date_t now) const {
// We change sync source on error if
// 1) A forced sync source change has been requested.
// 2) Chaining is disabled and a new primary has been detected.
// 3) A more eligible node exists. Note this covers the case where our current sync source is
// down.
auto [initialDecision, currentSourceIndex] =
_shouldChangeSyncSourceInitialChecks(currentSource);
if (initialDecision != ChangeSyncSourceDecision::kMaybe) {
return initialDecision == ChangeSyncSourceDecision::kYes;
}
if (_shouldChangeSyncSourceDueToNewPrimary(currentSource, currentSourceIndex)) {
return true;
}
if (_shouldChangeSyncSourceDueToBetterEligibleSource(
currentSource, currentSourceIndex, lastOpTimeFetched, now))
return true;
return false;
}
std::pair<TopologyCoordinator::ChangeSyncSourceDecision, int>
TopologyCoordinator::_shouldChangeSyncSourceInitialChecks(const HostAndPort& currentSource) const {
if (_selfIndex == -1) {
LOGV2(21828, "Not choosing new sync source because we are not in the config");
return {ChangeSyncSourceDecision::kNo, -1};
}
// If the user requested a sync source change, return kYes.
if (_forceSyncSourceIndex != -1) {
LOGV2(21829,
"Choosing new sync source because the user has requested to use "
"{syncSource} as a sync source",
"Choosing new sync source because the user has requested a sync source",
"syncSource"_attr = _rsConfig.getMemberAt(_forceSyncSourceIndex).getHostAndPort());
return {ChangeSyncSourceDecision::kYes, -1};
}
// While we can allow data replication across config versions, we still do not allow syncing
// from a node that is not in our config.
const int currentSourceIndex = _rsConfig.findMemberIndexByHostAndPort(currentSource);
if (currentSourceIndex == -1) {
LOGV2(21831,
"Choosing new sync source because {currentSyncSource} is not in our config",
"Choosing new sync source because current sync source is not in our config",
"currentSyncSource"_attr = currentSource.toString());
return {ChangeSyncSourceDecision::kYes, -1};
}
invariant(currentSourceIndex != _selfIndex);
return {ChangeSyncSourceDecision::kMaybe, currentSourceIndex};
}
bool TopologyCoordinator::_shouldChangeSyncSourceDueToNewPrimary(const HostAndPort& currentSource,
int currentSourceIndex) const {
// Change sync source if chaining is disabled (without overrides), we are not syncing from the
// primary, and we know who the new primary is. We do not consider chaining disabled if we are
// the primary, since we are in catchup mode.
auto chainingDisabled = !_rsConfig.isChainingAllowed() &&
!enableOverrideClusterChainingSetting.load() && _currentPrimaryIndex != _selfIndex;
auto foundNewPrimary = _currentPrimaryIndex != -1 && _currentPrimaryIndex != currentSourceIndex;
if (chainingDisabled && foundNewPrimary) {
auto newPrimary = _rsConfig.getMemberAt(_currentPrimaryIndex).getHostAndPort();
LOGV2(3962100,
"Choosing new sync source because chaining is disabled and we are aware of a new "
"primary",
"syncSource"_attr = currentSource,
"newPrimary"_attr = newPrimary);
return true;
}
return false;
}
bool TopologyCoordinator::_shouldChangeSyncSourceDueToSourceNotAhead(
const HostAndPort& currentSource,
int syncSourceIndex,
bool syncSourceIsPrimary,
const OpTime& currentSourceOpTime,
const OpTime& lastOpTimeFetched) const {
if (syncSourceIndex == -1 && currentSourceOpTime <= lastOpTimeFetched && !syncSourceIsPrimary) {
LOGV2(21832,
"Choosing new sync source. Our current sync source is not primary and does "
"not have a sync source, so we require that it is ahead of us",
"syncSource"_attr = currentSource,
"lastOpTimeFetched"_attr = lastOpTimeFetched,
"syncSourceLatestOplogOpTime"_attr = currentSourceOpTime,
"isPrimary"_attr = syncSourceIsPrimary);
return true;
}
return false;
}
bool TopologyCoordinator::_shouldChangeSyncSourceToBreakCycle(
const HostAndPort& currentSource,
const std::string& syncSourceHost,
int syncSourceIndex,
const OpTime& currentSourceOpTime,
const OpTime& lastOpTimeFetched) const {
// Change sync source if our sync source is also syncing from us when we are in primary
// catchup mode, forming a sync source selection cycle, and the sync source is not ahead
// of us. This is to prevent a deadlock situation. See SERVER-58988 for details.
const bool isSyncingFromMe = syncSourceHost == _selfMemberData().getHostAndPort().toString();
if (isSyncingFromMe && _currentPrimaryIndex == _selfIndex &&
currentSourceOpTime <= lastOpTimeFetched) {
LOGV2(5898800,
"Choosing new sync source because we are in primary catchup but our current sync "
"source is also syncing from us but is not ahead of us",
"syncSource"_attr = currentSource,
"lastOpTimeFetched"_attr = lastOpTimeFetched,
"syncSourceLatestOplogOpTime"_attr = currentSourceOpTime);
return true;
}
return false;
}
bool TopologyCoordinator::_shouldChangeSyncSourceDueToLag(const HostAndPort& currentSource,
const OpTime& currentSourceOpTime,
const OpTime& lastOpTimeFetched,
Date_t now) const {
if (MONGO_unlikely(disableMaxSyncSourceLagSecs.shouldFail())) {
LOGV2(
21833,
"disableMaxSyncSourceLagSecs fail point enabled - not checking the most recent OpTime "
"of our current sync source against the OpTimes of the other nodes in this replica set",
"currentSyncSourceOpTime"_attr = currentSourceOpTime.toString(),
"syncSource"_attr = currentSource);
} else {
unsigned int currentSourceOpTimeSecs = currentSourceOpTime.getSecs();
unsigned int currentSourceLagThresholdSecs =
currentSourceOpTimeSecs + durationCount<Seconds>(_options.maxSyncSourceLagSecs);
for (size_t i = 0; i < _memberData.size(); i++) {
const auto& member = _memberData[i];
if (currentSourceLagThresholdSecs < member.getHeartbeatAppliedOpTime().getSecs() &&
_isEligibleSyncSource(i,
now,
lastOpTimeFetched,
ReadPreference::Nearest,
true /* firstAttempt */,
true /* shouldCheckStaleness */)) {
invariant(i != (size_t)_selfIndex,
str::stream()
<< "Node " << i << " was eligible as a sync source for itself");
LOGV2(21834,
"Choosing new sync source because the most recent OpTime of our sync source "
"is more than maxSyncSourceLagSecs behind another member",
"syncSource"_attr = currentSource,
"syncSourceOpTime"_attr = currentSourceOpTime.toString(),
"maxSyncSourceLagSecs"_attr = _options.maxSyncSourceLagSecs,
"otherMember"_attr = member.getHostAndPort().toString(),
"otherMemberHearbeatAppliedOpTime"_attr =
member.getHeartbeatAppliedOpTime().toString());
return true;
}
}
}
return false;
}
bool TopologyCoordinator::_shouldChangeSyncSourceDueToBetterEligibleSource(
const HostAndPort& currentSource,
const int currentSourceIndex,
const OpTime& lastOpTimeFetched,
Date_t now) const {
// Change sync source if our current sync source is not a preferred sync source node choice due
// to non-staleness issues, such as being a non-voter when we are a voter, or being hidden, or
// any of the other conditions checked in _isEligibleSyncSource with firstAttempt=true, and
// another eligible node exists which does meet these criteria. Note that while we bypass
// staleness checks for our current node, we should not do this for a potential new node,
// because we could end up with a situation where shouldChangeSyncSource returns true, causing
// the sync source to be cleared, but then being reset to our previous sync source repeatedly
// because the new source is not actually valid. Note that _isEligibleSyncSource only checks for
// ReadPreference::Secondary*, so any choice besides those for the read preference is fine.
if (!_isEligibleSyncSource(currentSourceIndex,
now,
lastOpTimeFetched,
ReadPreference::Nearest,
true /* firstAttempt */,
false /* shouldCheckStaleness */)) {
for (size_t i = 0; i < _memberData.size(); i++) {
if (_isEligibleSyncSource(i,
now,
lastOpTimeFetched,
ReadPreference::Nearest,
true /* firstAttempt */,
true /* shouldCheckStaleness */)) {
invariant(i != (size_t)_selfIndex,
str::stream()
<< "Node " << i << " was eligible as a sync source for itself");
LOGV2(5929000,
"Choosing new sync source because our current sync source does not satisfy "
"our strict criteria for candidates, but there is another member which does "
"satisfy these criteria",
"currentSyncSource"_attr = currentSource,
"eligibleCandidateSyncSource"_attr =
_rsConfig.getMemberAt(i).getHostAndPort().toString());
return true;
}
}
}
return false;
}
bool TopologyCoordinator::shouldChangeSyncSourceDueToPingTime(const HostAndPort& currentSource,
const MemberState& memberState,
const OpTime& previousOpTimeFetched,
Date_t now,
const ReadPreference readPreference) {
// If we find an eligible sync source that is significantly closer than our current sync source,
// return true.
// Do not re-evaluate our sync source if it was set via the replSetSyncFrom command or the
// forceSyncSourceCandidate failpoint.
auto sfp = forceSyncSourceCandidate.scoped();
if (_replSetSyncFromSet || MONGO_unlikely(sfp.isActive())) {
return false;
}
// If we are in initial sync, do not re-evaluate our sync source.
const bool nodeInInitialSync = (memberState.startup() || memberState.startup2());
if (nodeInInitialSync) {
return false;
}
// If we are configured with secondaryDelaySecs, do not re-evaluate our sync source.
if (_selfIndex == -1 || _selfConfig().getSecondaryDelay() > Seconds(0)) {
return false;
}
// If we have already changed sync sources more than 'maxNumSyncSourceChangesPerHour' in the
// past hour, do not re-evaluate our sync source.
if (_recentSyncSourceChanges.changedTooOftenRecently(now)) {
return false;
}
const bool primaryOnly = (readPreference == ReadPreference::PrimaryOnly);
const bool primaryPreferredAndAlreadySyncing =
(readPreference == ReadPreference::PrimaryPreferred &&
(currentSource == getCurrentPrimaryMember()->getHostAndPort()));
if (primaryOnly || primaryPreferredAndAlreadySyncing) {
return false;
}
const auto changeSyncSourceThreshold = changeSyncSourceThresholdMillis.load();
// If the threshold is set to zero, do not consider changing sync sources due to ping time.
if (changeSyncSourceThreshold == 0LL) {
return false;
}
// If we have not yet received 5N pings (not counting ourselves), do not re-evaluate our sync
// source.
int numPingsNeeded = (_memberData.size() - 1) * 5 - pingsInConfig;
if (numPingsNeeded > 0) {
return false;
}
if (_pings.count(currentSource) == 0) {
// Ping data for our current sync source could not be found.
return false;
}
const auto syncSourcePingTime =
durationCount<Milliseconds>(_pings.at(currentSource).getMillis());
// Use ping times to look for another viable sync source that is significantly closer.
for (size_t candidateIndex = 0; candidateIndex < _memberData.size(); candidateIndex++) {
const auto candidateNode = _memberData[candidateIndex].getHostAndPort();
if (_pings.count(candidateNode) == 0) {
// Either we are the candidate node or ping data for the candidateNode could not be
// found. Continue to the next node.
continue;
}
// Only choose a new sync source if ping times indicate that the candidate is significantly
// closer than our current sync source and it is an eligible sync source.
const auto candidateSyncSourcePingTime =
durationCount<Milliseconds>(_pings.at(candidateNode).getMillis());
if (syncSourcePingTime - candidateSyncSourcePingTime <= changeSyncSourceThreshold) {
continue;
}
if (_isEligibleSyncSource(candidateIndex,
now,
previousOpTimeFetched,
readPreference,
true /* firstAttempt */,
true /* shouldCheckStaleness */)) {
LOGV2(4744901,
"Choosing new sync source because we have found another potential sync "
"source that is significantly closer than our current sync source",
"syncSourcePingTime"_attr = syncSourcePingTime,
"changeSyncSourceThreshold"_attr = changeSyncSourceThreshold,
"candidateNode"_attr = candidateNode,
"candidatePingTime"_attr = candidateSyncSourcePingTime);
numSyncSourceChangesDueToSignificantlyCloserNode.increment();
return true;
}
}
return false;
}
rpc::ReplSetMetadata TopologyCoordinator::prepareReplSetMetadata(
const OpTime& lastVisibleOpTime) const {
return rpc::ReplSetMetadata(_term,
_lastCommittedOpTimeAndWallTime,
lastVisibleOpTime,
_rsConfig.getConfigVersion(),
_rsConfig.getConfigTerm(),
_rsConfig.getReplicaSetId(),
_rsConfig.findMemberIndexByHostAndPort(getSyncSourceAddress()),
_role == Role::kLeader /* isPrimary */);
}
rpc::OplogQueryMetadata TopologyCoordinator::prepareOplogQueryMetadata(int rbid) const {
return rpc::OplogQueryMetadata(_lastCommittedOpTimeAndWallTime,
getMyLastAppliedOpTime(),
rbid,
_currentPrimaryIndex,
_rsConfig.findMemberIndexByHostAndPort(getSyncSourceAddress()),
getSyncSourceAddress().toString());
}
void TopologyCoordinator::processReplSetRequestVotes(const ReplSetRequestVotesArgs& args,
ReplSetRequestVotesResponse* response) {
response->setTerm(_term);
if (MONGO_unlikely(voteNoInElection.shouldFail())) {
LOGV2(21835, "Failpoint voteNoInElection enabled");
response->setVoteGranted(false);
response->setReason(
"forced to vote no during dry run election due to failpoint voteNoInElection set");
return;
}
if (MONGO_unlikely(voteYesInDryRunButNoInRealElection.shouldFail())) {
LOGV2(21836, "Failpoint voteYesInDryRunButNoInRealElection enabled");
if (args.isADryRun()) {
response->setVoteGranted(true);
response->setReason(
"forced to vote yes in dry run due to failpoint "
"voteYesInDryRunButNoInRealElection set");
} else {
response->setVoteGranted(false);
response->setReason(
"forced to vote no in real election due to failpoint "
"voteYesInDryRunButNoInRealElection set");
}
return;
}
if (args.getConfigVersionAndTerm() < _rsConfig.getConfigVersionAndTerm()) {
response->setVoteGranted(false);
response->setReason("candidate's config with {} is older than mine with {}"_format(
args.getConfigVersionAndTerm(), _rsConfig.getConfigVersionAndTerm()));
} else if (args.getTerm() < _term) {
response->setVoteGranted(false);
response->setReason(
"candidate's term ({}) is lower than mine ({})"_format(args.getTerm(), _term));
} else if (args.getSetName() != _rsConfig.getReplSetName()) {
response->setVoteGranted(false);
response->setReason("candidate's set name ({}) differs from mine ({})"_format(
args.getSetName(), _rsConfig.getReplSetName()));
} else if (args.getLastAppliedOpTime() < getMyLastAppliedOpTime()) {
response->setVoteGranted(false);
response->setReason(
"candidate's data is staler than mine. candidate's last applied OpTime: {}, "
"my last applied OpTime: {}"_format(args.getLastAppliedOpTime().toString(),
getMyLastAppliedOpTime().toString()));
} else if (!args.isADryRun() && _lastVote.getTerm() == args.getTerm()) {
response->setVoteGranted(false);
response->setReason("already voted for another candidate ({}) this term ({})"_format(
_rsConfig.getMemberAt(_lastVote.getCandidateIndex()).getHostAndPort(),
_lastVote.getTerm()));
} else {
bool isSameConfig = args.getConfigVersionAndTerm() == _rsConfig.getConfigVersionAndTerm();
int betterPrimary = _findHealthyPrimaryOfEqualOrGreaterPriority(args.getCandidateIndex());
// Do not grant vote if we are arbiter and can see a healthy primary of greater or equal
// priority, to prevent primary flapping when there are two nodes that can't talk to each
// other but we that can talk to both as arbiter. We only do this if the voter's config
// is same as ours, otherwise the primary information might be stale and we might not be
// arbiter in the candidate's newer config. We might also hit an invariant described in
// SERVER-46387 without the check for same config.
if (isSameConfig && _selfConfig().isArbiter() && betterPrimary >= 0) {
response->setVoteGranted(false);
response->setReason(
"can see a healthy primary ({}) of equal or greater priority"_format(
_rsConfig.getMemberAt(betterPrimary).getHostAndPort()));
} else {
if (!args.isADryRun()) {
_lastVote.setTerm(args.getTerm());
_lastVote.setCandidateIndex(args.getCandidateIndex());
LOGV2_DEBUG(5972100, 1, "Voting yes in election");
}
response->setVoteGranted(true);
}
}
LOGV2_FOR_ELECTION(23980,
0,
"Responding to vote request",
"request"_attr = args.toString(),
"response"_attr = response->toString(),
"replicaSetStatus"_attr = _getReplSetStatusString());
}
void TopologyCoordinator::loadLastVote(const LastVote& lastVote) {
_lastVote = lastVote;
}
void TopologyCoordinator::voteForMyselfV1() {
_lastVote.setTerm(_term);
_lastVote.setCandidateIndex(_selfIndex);
}
void TopologyCoordinator::setPrimaryIndex(long long primaryIndex) {
_currentPrimaryIndex = primaryIndex;
}
Status TopologyCoordinator::becomeCandidateIfElectable(const Date_t now,
StartElectionReasonEnum reason) {
if (_role == Role::kLeader) {
return {ErrorCodes::NodeNotElectable, "Not standing for election again; already primary"};
}
if (_role == Role::kCandidate) {
return {ErrorCodes::NodeNotElectable, "Not standing for election again; already candidate"};
}
const UnelectableReasonMask unelectableReason = _getMyUnelectableReason(now, reason);
if (unelectableReason) {
return {ErrorCodes::NodeNotElectable,
str::stream() << "Not standing for election because "
<< _getUnelectableReasonString(unelectableReason)};
}
// All checks passed, become a candidate and start election proceedings.
_role = Role::kCandidate;
return Status::OK();
}
void TopologyCoordinator::setStorageEngineSupportsReadCommitted(bool supported) {
_storageEngineSupportsReadCommitted =
supported ? ReadCommittedSupport::kYes : ReadCommittedSupport::kNo;
}
void TopologyCoordinator::restartHeartbeat(const Date_t now, const HostAndPort& target) {
for (auto&& member : _memberData) {
if (member.getHostAndPort() == target) {
member.restart();
member.updateLiveness(now);
return;
}
}
}
void TopologyCoordinator::incrementTopologyVersion() {
auto counter = _topologyVersion.getCounter();
_topologyVersion.setCounter(counter + 1);
}
OpTime TopologyCoordinator::latestKnownOpTime() const {
OpTime latest = getMyLastAppliedOpTime();
for (std::vector<MemberData>::const_iterator it = _memberData.begin(); it != _memberData.end();
++it) {
// Ignore self
if (it->isSelf()) {
continue;
}
// Ignore down members
if (!it->up()) {
continue;
}
// Ignore removed nodes (not in config, so not valid).
if (it->getState().removed()) {
continue;
}
OpTime optime = it->getHeartbeatAppliedOpTime();
if (optime > latest) {
latest = optime;
}
}
return latest;
}
boost::optional<OpTime> TopologyCoordinator::latestKnownOpTimeSinceHeartbeatRestart() const {
// The smallest OpTime in PV1.
OpTime latest(Timestamp(0, 0), 0);
for (size_t i = 0; i < _memberData.size(); i++) {
auto& peer = _memberData[i];
if (static_cast<int>(i) == _selfIndex) {
continue;
}
// If any heartbeat is not fresh enough, return none.
if (!peer.isUpdatedSinceRestart()) {
return boost::none;
}
// Ignore down members
if (!peer.up()) {
continue;
}
if (peer.getHeartbeatAppliedOpTime() > latest) {
latest = peer.getHeartbeatAppliedOpTime();
}
}
return latest;
}
std::map<MemberId, boost::optional<OpTime>>
TopologyCoordinator::latestKnownOpTimeSinceHeartbeatRestartPerMember() const {
std::map<MemberId, boost::optional<OpTime>> opTimesPerMember;
for (size_t i = 0; i < _memberData.size(); i++) {
auto& member = _memberData[i];
MemberId memberId = _rsConfig.getMemberAt(i).getId();
if (!member.isUpdatedSinceRestart()) {
opTimesPerMember[memberId] = boost::none;
continue;
}
if (!member.up()) {
opTimesPerMember[memberId] = boost::none;
continue;
}
opTimesPerMember[memberId] = member.getHeartbeatAppliedOpTime();
}
return opTimesPerMember;
}
Status TopologyCoordinator::checkIfCommitQuorumCanBeSatisfied(
const CommitQuorumOptions& commitQuorum) const {
if (!commitQuorum.mode.empty() && commitQuorum.mode != CommitQuorumOptions::kMajority &&
commitQuorum.mode != CommitQuorumOptions::kVotingMembers) {
StatusWith<ReplSetTagPattern> tagPatternStatus =
_rsConfig.findCustomWriteMode(commitQuorum.mode);
if (!tagPatternStatus.isOK()) {
return tagPatternStatus.getStatus();
}
ReplSetTagMatch matcher(tagPatternStatus.getValue());
for (auto&& member : _rsConfig.members()) {
for (MemberConfig::TagIterator it = member.tagsBegin(); it != member.tagsEnd(); ++it) {
if (matcher.update(*it)) {
return Status::OK();
}
}
}
// Even if all the nodes in the set had a given write it still would not satisfy this
// commit quorum.
return {ErrorCodes::UnsatisfiableCommitQuorum,
"Commit quorum cannot be satisfied with the current replica set configuration"};
}
int nodesRemaining = commitQuorum.numNodes;
if (!commitQuorum.mode.empty()) {
if (commitQuorum.mode == CommitQuorumOptions::kMajority) {
nodesRemaining = _rsConfig.getWriteMajority();
} else if (commitQuorum.mode == CommitQuorumOptions::kVotingMembers) {
nodesRemaining = _rsConfig.getWritableVotingMembersCount();
}
}
bool buildIndexesFalseNodes = false;
for (auto&& member : _rsConfig.members()) {
// Only count data-bearing nodes.
if (member.isArbiter()) {
continue;
}
// Only count nodes that build indexes.
if (!member.shouldBuildIndexes()) {
buildIndexesFalseNodes = true;
continue;
}
--nodesRemaining;
if (nodesRemaining <= 0) {
return Status::OK();
}
}
// buildIndexes:false should not be included in a commitQuorum because they never actually build
// indexes and vote to commit. Provide a helpful error message to prevent users from starting
// index builds that will never commit.
if (buildIndexesFalseNodes) {
return {ErrorCodes::UnsatisfiableCommitQuorum,
str::stream() << "Commit quorum cannot depend on buildIndexes:false nodes; "
<< "use a commit quorum that excludes these nodes"};
}
return {ErrorCodes::UnsatisfiableCommitQuorum,
"Not enough data-bearing nodes to satisfy commit quorum"};
}
} // namespace repl
} // namespace mongo
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