/* * Copyright (c) 2019 TAOS Data, Inc. * * This program is free software: you can use, redistribute, and/or modify * it under the terms of the GNU Affero General Public License, version 3 * or later ("AGPL"), as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #define _DEFAULT_SOURCE #include "sync.h" #include "syncAppendEntries.h" #include "syncAppendEntriesReply.h" #include "syncCommit.h" #include "syncElection.h" #include "syncEnv.h" #include "syncIndexMgr.h" #include "syncInt.h" #include "syncMessage.h" #include "syncPipeline.h" #include "syncRaftCfg.h" #include "syncRaftLog.h" #include "syncRaftStore.h" #include "syncReplication.h" #include "syncRequestVote.h" #include "syncRequestVoteReply.h" #include "syncRespMgr.h" #include "syncSnapshot.h" #include "syncTimeout.h" #include "syncUtil.h" #include "syncVoteMgr.h" #include "tglobal.h" #include "tref.h" static void syncNodeEqPingTimer(void* param, void* tmrId); static void syncNodeEqElectTimer(void* param, void* tmrId); static void syncNodeEqHeartbeatTimer(void* param, void* tmrId); static int32_t syncNodeAppendNoop(SSyncNode* ths); static void syncNodeEqPeerHeartbeatTimer(void* param, void* tmrId); static bool syncIsConfigChanged(const SSyncCfg* pOldCfg, const SSyncCfg* pNewCfg); static int32_t syncHbTimerInit(SSyncNode* pSyncNode, SSyncTimer* pSyncTimer, SRaftId destId); static int32_t syncHbTimerStart(SSyncNode* pSyncNode, SSyncTimer* pSyncTimer); static int32_t syncHbTimerStop(SSyncNode* pSyncNode, SSyncTimer* pSyncTimer); static int32_t syncNodeUpdateNewConfigIndex(SSyncNode* ths, SSyncCfg* pNewCfg); static bool syncNodeInConfig(SSyncNode* pSyncNode, const SSyncCfg* config); static void syncNodeDoConfigChange(SSyncNode* pSyncNode, SSyncCfg* newConfig, SyncIndex lastConfigChangeIndex); static bool syncNodeIsOptimizedOneReplica(SSyncNode* ths, SRpcMsg* pMsg); static bool syncNodeCanChange(SSyncNode* pSyncNode); static int32_t syncNodeLeaderTransfer(SSyncNode* pSyncNode); static int32_t syncNodeLeaderTransferTo(SSyncNode* pSyncNode, SNodeInfo newLeader); static int32_t syncDoLeaderTransfer(SSyncNode* ths, SRpcMsg* pRpcMsg, SSyncRaftEntry* pEntry); static ESyncStrategy syncNodeStrategy(SSyncNode* pSyncNode); int64_t syncOpen(SSyncInfo* pSyncInfo) { SSyncNode* pSyncNode = syncNodeOpen(pSyncInfo); if (pSyncNode == NULL) { sError("vgId:%d, failed to open sync node", pSyncInfo->vgId); return -1; } pSyncNode->rid = syncNodeAdd(pSyncNode); if (pSyncNode->rid < 0) { syncNodeClose(pSyncNode); return -1; } pSyncNode->pingBaseLine = pSyncInfo->pingMs; pSyncNode->pingTimerMS = pSyncInfo->pingMs; pSyncNode->electBaseLine = pSyncInfo->electMs; pSyncNode->hbBaseLine = pSyncInfo->heartbeatMs; pSyncNode->heartbeatTimerMS = pSyncInfo->heartbeatMs; pSyncNode->msgcb = pSyncInfo->msgcb; return pSyncNode->rid; } int32_t syncStart(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { sError("failed to acquire rid:%" PRId64 " of tsNodeReftId for pSyncNode", rid); return -1; } if (syncNodeRestore(pSyncNode) < 0) { sError("vgId:%d, failed to restore sync log buffer since %s", pSyncNode->vgId, terrstr()); goto _err; } if (syncNodeStart(pSyncNode) < 0) { sError("vgId:%d, failed to start sync node since %s", pSyncNode->vgId, terrstr()); goto _err; } syncNodeRelease(pSyncNode); return 0; _err: syncNodeRelease(pSyncNode); return -1; } void syncStop(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode != NULL) { pSyncNode->isStart = false; syncNodeRelease(pSyncNode); syncNodeRemove(rid); } } void syncPreStop(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode != NULL) { syncNodePreClose(pSyncNode); syncNodeRelease(pSyncNode); } } void syncPostStop(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode != NULL) { syncNodePostClose(pSyncNode); syncNodeRelease(pSyncNode); } } static bool syncNodeCheckNewConfig(SSyncNode* pSyncNode, const SSyncCfg* pCfg) { if (!syncNodeInConfig(pSyncNode, pCfg)) return false; return abs(pCfg->replicaNum - pSyncNode->replicaNum) <= 1; } int32_t syncReconfig(int64_t rid, SSyncCfg* pNewCfg) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) return -1; if (!syncNodeCheckNewConfig(pSyncNode, pNewCfg)) { syncNodeRelease(pSyncNode); terrno = TSDB_CODE_SYN_NEW_CONFIG_ERROR; sError("vgId:%d, failed to reconfig since invalid new config", pSyncNode->vgId); return -1; } syncNodeUpdateNewConfigIndex(pSyncNode, pNewCfg); syncNodeDoConfigChange(pSyncNode, pNewCfg, SYNC_INDEX_INVALID); if (pSyncNode->state == TAOS_SYNC_STATE_LEADER) { syncNodeStopHeartbeatTimer(pSyncNode); for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { syncHbTimerInit(pSyncNode, &pSyncNode->peerHeartbeatTimerArr[i], pSyncNode->replicasId[i]); } syncNodeStartHeartbeatTimer(pSyncNode); // syncNodeReplicate(pSyncNode); } syncNodeRelease(pSyncNode); return 0; } int32_t syncProcessMsg(int64_t rid, SRpcMsg* pMsg) { int32_t code = -1; if (!syncIsInit()) return code; SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) return code; switch (pMsg->msgType) { case TDMT_SYNC_HEARTBEAT: code = syncNodeOnHeartbeat(pSyncNode, pMsg); break; case TDMT_SYNC_HEARTBEAT_REPLY: code = syncNodeOnHeartbeatReply(pSyncNode, pMsg); break; case TDMT_SYNC_TIMEOUT: code = syncNodeOnTimeout(pSyncNode, pMsg); break; case TDMT_SYNC_TIMEOUT_ELECTION: code = syncNodeOnTimeout(pSyncNode, pMsg); break; case TDMT_SYNC_CLIENT_REQUEST: code = syncNodeOnClientRequest(pSyncNode, pMsg, NULL); break; case TDMT_SYNC_REQUEST_VOTE: code = syncNodeOnRequestVote(pSyncNode, pMsg); break; case TDMT_SYNC_REQUEST_VOTE_REPLY: code = syncNodeOnRequestVoteReply(pSyncNode, pMsg); break; case TDMT_SYNC_APPEND_ENTRIES: code = syncNodeOnAppendEntries(pSyncNode, pMsg); break; case TDMT_SYNC_APPEND_ENTRIES_REPLY: code = syncNodeOnAppendEntriesReply(pSyncNode, pMsg); break; case TDMT_SYNC_SNAPSHOT_SEND: code = syncNodeOnSnapshot(pSyncNode, pMsg); break; case TDMT_SYNC_SNAPSHOT_RSP: code = syncNodeOnSnapshotRsp(pSyncNode, pMsg); break; case TDMT_SYNC_LOCAL_CMD: code = syncNodeOnLocalCmd(pSyncNode, pMsg); break; default: terrno = TSDB_CODE_MSG_NOT_PROCESSED; code = -1; } syncNodeRelease(pSyncNode); if (code != 0) { sDebug("vgId:%d, failed to process sync msg:%p type:%s since 0x%x", pSyncNode->vgId, pMsg, TMSG_INFO(pMsg->msgType), terrno); } return code; } int32_t syncLeaderTransfer(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) return -1; int32_t ret = syncNodeLeaderTransfer(pSyncNode); syncNodeRelease(pSyncNode); return ret; } int32_t syncSendTimeoutRsp(int64_t rid, int64_t seq) { SSyncNode* pNode = syncNodeAcquire(rid); if (pNode == NULL) return -1; SRpcMsg rpcMsg = {0}; int32_t ret = syncRespMgrGetAndDel(pNode->pSyncRespMgr, seq, &rpcMsg.info); rpcMsg.code = TSDB_CODE_SYN_TIMEOUT; syncNodeRelease(pNode); if (ret == 1) { sInfo("send timeout response, seq:%" PRId64 " handle:%p ahandle:%p", seq, rpcMsg.info.handle, rpcMsg.info.ahandle); rpcSendResponse(&rpcMsg); return 0; } else { sError("no message handle to send timeout response, seq:%" PRId64, seq); return -1; } } SyncIndex syncMinMatchIndex(SSyncNode* pSyncNode) { SyncIndex minMatchIndex = SYNC_INDEX_INVALID; if (pSyncNode->peersNum > 0) { minMatchIndex = syncIndexMgrGetIndex(pSyncNode->pMatchIndex, &(pSyncNode->peersId[0])); } for (int32_t i = 1; i < pSyncNode->peersNum; ++i) { SyncIndex matchIndex = syncIndexMgrGetIndex(pSyncNode->pMatchIndex, &(pSyncNode->peersId[i])); if (matchIndex < minMatchIndex) { minMatchIndex = matchIndex; } } return minMatchIndex; } int32_t syncBeginSnapshot(int64_t rid, int64_t lastApplyIndex) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { sError("sync begin snapshot error"); return -1; } SyncIndex beginIndex = pSyncNode->pLogStore->syncLogBeginIndex(pSyncNode->pLogStore); SyncIndex endIndex = pSyncNode->pLogStore->syncLogEndIndex(pSyncNode->pLogStore); bool isEmpty = pSyncNode->pLogStore->syncLogIsEmpty(pSyncNode->pLogStore); if (isEmpty || !(lastApplyIndex >= beginIndex && lastApplyIndex <= endIndex)) { sNTrace(pSyncNode, "new-snapshot-index:%" PRId64 ", empty:%d, do not delete wal", lastApplyIndex, isEmpty); syncNodeRelease(pSyncNode); return 0; } int32_t code = 0; int64_t logRetention = 0; if (syncNodeIsMnode(pSyncNode)) { // mnode logRetention = tsMndLogRetention; } else { // vnode if (pSyncNode->replicaNum > 1) { // multi replicas logRetention = SYNC_VNODE_LOG_RETENTION; } } if (pSyncNode->replicaNum > 1) { if (pSyncNode->state != TAOS_SYNC_STATE_LEADER && pSyncNode->state != TAOS_SYNC_STATE_FOLLOWER) { sNTrace(pSyncNode, "new-snapshot-index:%" PRId64 " candidate or unknown state, do not delete wal", lastApplyIndex); syncNodeRelease(pSyncNode); return 0; } logRetention = TMAX(logRetention, lastApplyIndex - pSyncNode->minMatchIndex + logRetention); } _DEL_WAL: do { SSyncLogStoreData* pData = pSyncNode->pLogStore->data; SyncIndex snapshotVer = walGetSnapshotVer(pData->pWal); SyncIndex walCommitVer = walGetCommittedVer(pData->pWal); SyncIndex wallastVer = walGetLastVer(pData->pWal); if (lastApplyIndex <= walCommitVer) { SyncIndex snapshottingIndex = atomic_load_64(&pSyncNode->snapshottingIndex); if (snapshottingIndex == SYNC_INDEX_INVALID) { atomic_store_64(&pSyncNode->snapshottingIndex, lastApplyIndex); pSyncNode->snapshottingTime = taosGetTimestampMs(); code = walBeginSnapshot(pData->pWal, lastApplyIndex, logRetention); if (code == 0) { sNTrace(pSyncNode, "wal snapshot begin, index:%" PRId64 ", last apply index:%" PRId64, pSyncNode->snapshottingIndex, lastApplyIndex); } else { sNError(pSyncNode, "wal snapshot begin error since:%s, index:%" PRId64 ", last apply index:%" PRId64, terrstr(terrno), pSyncNode->snapshottingIndex, lastApplyIndex); atomic_store_64(&pSyncNode->snapshottingIndex, SYNC_INDEX_INVALID); } } else { sNTrace(pSyncNode, "snapshotting for %" PRId64 ", do not delete wal for new-snapshot-index:%" PRId64, snapshottingIndex, lastApplyIndex); } } } while (0); syncNodeRelease(pSyncNode); return code; } int32_t syncEndSnapshot(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { sError("sync end snapshot error"); return -1; } int32_t code = 0; if (atomic_load_64(&pSyncNode->snapshottingIndex) != SYNC_INDEX_INVALID) { SSyncLogStoreData* pData = pSyncNode->pLogStore->data; code = walEndSnapshot(pData->pWal); if (code != 0) { sNError(pSyncNode, "wal snapshot end error since:%s", terrstr()); syncNodeRelease(pSyncNode); return -1; } else { sNTrace(pSyncNode, "wal snapshot end, index:%" PRId64, atomic_load_64(&pSyncNode->snapshottingIndex)); atomic_store_64(&pSyncNode->snapshottingIndex, SYNC_INDEX_INVALID); } } syncNodeRelease(pSyncNode); return code; } int32_t syncStepDown(int64_t rid, SyncTerm newTerm) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { sError("sync step down error"); return -1; } syncNodeStepDown(pSyncNode, newTerm); syncNodeRelease(pSyncNode); return 0; } bool syncNodeIsReadyForRead(SSyncNode* pSyncNode) { if (pSyncNode == NULL) { terrno = TSDB_CODE_SYN_INTERNAL_ERROR; sError("sync ready for read error"); return false; } if (pSyncNode->state != TAOS_SYNC_STATE_LEADER) { terrno = TSDB_CODE_SYN_NOT_LEADER; return false; } if (!pSyncNode->restoreFinish) { terrno = TSDB_CODE_SYN_RESTORING; return false; } return true; } bool syncIsReadyForRead(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { sError("sync ready for read error"); return false; } bool ready = syncNodeIsReadyForRead(pSyncNode); syncNodeRelease(pSyncNode); return ready; } bool syncSnapshotSending(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { return false; } bool b = syncNodeSnapshotSending(pSyncNode); syncNodeRelease(pSyncNode); return b; } bool syncSnapshotRecving(int64_t rid) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { return false; } bool b = syncNodeSnapshotRecving(pSyncNode); syncNodeRelease(pSyncNode); return b; } int32_t syncNodeLeaderTransfer(SSyncNode* pSyncNode) { if (pSyncNode->peersNum == 0) { sDebug("vgId:%d, only one replica, cannot leader transfer", pSyncNode->vgId); terrno = TSDB_CODE_SYN_ONE_REPLICA; return -1; } int32_t ret = 0; if (pSyncNode->state == TAOS_SYNC_STATE_LEADER && pSyncNode->replicaNum > 1) { SNodeInfo newLeader = (pSyncNode->peersNodeInfo)[0]; if (pSyncNode->peersNum == 2) { SyncIndex matchIndex0 = syncIndexMgrGetIndex(pSyncNode->pMatchIndex, &(pSyncNode->peersId[0])); SyncIndex matchIndex1 = syncIndexMgrGetIndex(pSyncNode->pMatchIndex, &(pSyncNode->peersId[1])); if (matchIndex1 > matchIndex0) { newLeader = (pSyncNode->peersNodeInfo)[1]; } } ret = syncNodeLeaderTransferTo(pSyncNode, newLeader); } return ret; } int32_t syncNodeLeaderTransferTo(SSyncNode* pSyncNode, SNodeInfo newLeader) { if (pSyncNode->replicaNum == 1) { sDebug("vgId:%d, only one replica, cannot leader transfer", pSyncNode->vgId); terrno = TSDB_CODE_SYN_ONE_REPLICA; return -1; } sNTrace(pSyncNode, "begin leader transfer to %s:%u", newLeader.nodeFqdn, newLeader.nodePort); SRpcMsg rpcMsg = {0}; (void)syncBuildLeaderTransfer(&rpcMsg, pSyncNode->vgId); SyncLeaderTransfer* pMsg = rpcMsg.pCont; pMsg->newLeaderId.addr = SYNC_ADDR(&newLeader); pMsg->newLeaderId.vgId = pSyncNode->vgId; pMsg->newNodeInfo = newLeader; int32_t ret = syncNodePropose(pSyncNode, &rpcMsg, false, NULL); rpcFreeCont(rpcMsg.pCont); return ret; } SSyncState syncGetState(int64_t rid) { SSyncState state = {.state = TAOS_SYNC_STATE_ERROR}; SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode != NULL) { state.state = pSyncNode->state; state.restored = pSyncNode->restoreFinish; if (pSyncNode->vgId != 1) { state.canRead = syncNodeIsReadyForRead(pSyncNode); } else { state.canRead = state.restored; } syncNodeRelease(pSyncNode); } return state; } SyncIndex syncNodeGetSnapshotConfigIndex(SSyncNode* pSyncNode, SyncIndex snapshotLastApplyIndex) { ASSERT(pSyncNode->raftCfg.configIndexCount >= 1); SyncIndex lastIndex = (pSyncNode->raftCfg.configIndexArr)[0]; for (int32_t i = 0; i < pSyncNode->raftCfg.configIndexCount; ++i) { if ((pSyncNode->raftCfg.configIndexArr)[i] > lastIndex && (pSyncNode->raftCfg.configIndexArr)[i] <= snapshotLastApplyIndex) { lastIndex = (pSyncNode->raftCfg.configIndexArr)[i]; } } sTrace("vgId:%d, sync get last config index, index:%" PRId64 " lcindex:%" PRId64, pSyncNode->vgId, snapshotLastApplyIndex, lastIndex); return lastIndex; } void syncGetRetryEpSet(int64_t rid, SEpSet* pEpSet) { pEpSet->numOfEps = 0; SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) return; for (int32_t i = 0; i < pSyncNode->raftCfg.cfg.replicaNum; ++i) { SEp* pEp = &pEpSet->eps[i]; tstrncpy(pEp->fqdn, pSyncNode->raftCfg.cfg.nodeInfo[i].nodeFqdn, TSDB_FQDN_LEN); pEp->port = (pSyncNode->raftCfg.cfg.nodeInfo)[i].nodePort; pEpSet->numOfEps++; sDebug("vgId:%d, sync get retry epset, index:%d %s:%d", pSyncNode->vgId, i, pEp->fqdn, pEp->port); } if (pEpSet->numOfEps > 0) { pEpSet->inUse = (pSyncNode->raftCfg.cfg.myIndex + 1) % pEpSet->numOfEps; } sInfo("vgId:%d, sync get retry epset numOfEps:%d inUse:%d", pSyncNode->vgId, pEpSet->numOfEps, pEpSet->inUse); syncNodeRelease(pSyncNode); } int32_t syncPropose(int64_t rid, SRpcMsg* pMsg, bool isWeak, int64_t* seq) { SSyncNode* pSyncNode = syncNodeAcquire(rid); if (pSyncNode == NULL) { sError("sync propose error"); return -1; } int32_t ret = syncNodePropose(pSyncNode, pMsg, isWeak, seq); syncNodeRelease(pSyncNode); return ret; } int32_t syncNodePropose(SSyncNode* pSyncNode, SRpcMsg* pMsg, bool isWeak, int64_t* seq) { if (pSyncNode->state != TAOS_SYNC_STATE_LEADER) { terrno = TSDB_CODE_SYN_NOT_LEADER; sNError(pSyncNode, "sync propose not leader, type:%s", TMSG_INFO(pMsg->msgType)); return -1; } // not restored, vnode enable if (!pSyncNode->restoreFinish && pSyncNode->vgId != 1) { terrno = TSDB_CODE_SYN_PROPOSE_NOT_READY; sNError(pSyncNode, "failed to sync propose since not ready, type:%s, last:%" PRId64 ", cmt:%" PRId64, TMSG_INFO(pMsg->msgType), syncNodeGetLastIndex(pSyncNode), pSyncNode->commitIndex); return -1; } // heartbeat timeout if (syncNodeHeartbeatReplyTimeout(pSyncNode)) { terrno = TSDB_CODE_SYN_PROPOSE_NOT_READY; sNError(pSyncNode, "failed to sync propose since hearbeat timeout, type:%s, last:%" PRId64 ", cmt:%" PRId64, TMSG_INFO(pMsg->msgType), syncNodeGetLastIndex(pSyncNode), pSyncNode->commitIndex); return -1; } // optimized one replica if (syncNodeIsOptimizedOneReplica(pSyncNode, pMsg)) { SyncIndex retIndex; int32_t code = syncNodeOnClientRequest(pSyncNode, pMsg, &retIndex); if (code == 0) { pMsg->info.conn.applyIndex = retIndex; pMsg->info.conn.applyTerm = raftStoreGetTerm(pSyncNode); sTrace("vgId:%d, propose optimized msg, index:%" PRId64 " type:%s", pSyncNode->vgId, retIndex, TMSG_INFO(pMsg->msgType)); return 1; } else { terrno = TSDB_CODE_SYN_INTERNAL_ERROR; sError("vgId:%d, failed to propose optimized msg, index:%" PRId64 " type:%s", pSyncNode->vgId, retIndex, TMSG_INFO(pMsg->msgType)); return -1; } } else { SRespStub stub = {.createTime = taosGetTimestampMs(), .rpcMsg = *pMsg}; uint64_t seqNum = syncRespMgrAdd(pSyncNode->pSyncRespMgr, &stub); SRpcMsg rpcMsg = {0}; int32_t code = syncBuildClientRequest(&rpcMsg, pMsg, seqNum, isWeak, pSyncNode->vgId); if (code != 0) { sError("vgId:%d, failed to propose msg while serialize since %s", pSyncNode->vgId, terrstr()); (void)syncRespMgrDel(pSyncNode->pSyncRespMgr, seqNum); return -1; } sNTrace(pSyncNode, "propose msg, type:%s", TMSG_INFO(pMsg->msgType)); code = (*pSyncNode->syncEqMsg)(pSyncNode->msgcb, &rpcMsg); if (code != 0) { sError("vgId:%d, failed to propose msg while enqueue since %s", pSyncNode->vgId, terrstr()); (void)syncRespMgrDel(pSyncNode->pSyncRespMgr, seqNum); } if (seq != NULL) *seq = seqNum; return code; } } static int32_t syncHbTimerInit(SSyncNode* pSyncNode, SSyncTimer* pSyncTimer, SRaftId destId) { pSyncTimer->pTimer = NULL; pSyncTimer->counter = 0; pSyncTimer->timerMS = pSyncNode->hbBaseLine; pSyncTimer->timerCb = syncNodeEqPeerHeartbeatTimer; pSyncTimer->destId = destId; pSyncTimer->timeStamp = taosGetTimestampMs(); atomic_store_64(&pSyncTimer->logicClock, 0); return 0; } static int32_t syncHbTimerStart(SSyncNode* pSyncNode, SSyncTimer* pSyncTimer) { int32_t ret = 0; int64_t tsNow = taosGetTimestampMs(); if (syncIsInit()) { SSyncHbTimerData* pData = syncHbTimerDataAcquire(pSyncTimer->hbDataRid); if (pData == NULL) { pData = taosMemoryMalloc(sizeof(SSyncHbTimerData)); pData->rid = syncHbTimerDataAdd(pData); } pSyncTimer->hbDataRid = pData->rid; pSyncTimer->timeStamp = tsNow; pData->syncNodeRid = pSyncNode->rid; pData->pTimer = pSyncTimer; pData->destId = pSyncTimer->destId; pData->logicClock = pSyncTimer->logicClock; pData->execTime = tsNow + pSyncTimer->timerMS; taosTmrReset(pSyncTimer->timerCb, pSyncTimer->timerMS / HEARTBEAT_TICK_NUM, (void*)(pData->rid), syncEnv()->pTimerManager, &pSyncTimer->pTimer); } else { sError("vgId:%d, start ctrl hb timer error, sync env is stop", pSyncNode->vgId); } return ret; } static int32_t syncHbTimerStop(SSyncNode* pSyncNode, SSyncTimer* pSyncTimer) { int32_t ret = 0; atomic_add_fetch_64(&pSyncTimer->logicClock, 1); taosTmrStop(pSyncTimer->pTimer); pSyncTimer->pTimer = NULL; syncHbTimerDataRemove(pSyncTimer->hbDataRid); pSyncTimer->hbDataRid = -1; return ret; } int32_t syncNodeLogStoreRestoreOnNeed(SSyncNode* pNode) { ASSERTS(pNode->pLogStore != NULL, "log store not created"); ASSERTS(pNode->pFsm != NULL, "pFsm not registered"); ASSERTS(pNode->pFsm->FpGetSnapshotInfo != NULL, "FpGetSnapshotInfo not registered"); SSnapshot snapshot = {0}; pNode->pFsm->FpGetSnapshotInfo(pNode->pFsm, &snapshot); SyncIndex commitIndex = snapshot.lastApplyIndex; SyncIndex firstVer = pNode->pLogStore->syncLogBeginIndex(pNode->pLogStore); SyncIndex lastVer = pNode->pLogStore->syncLogLastIndex(pNode->pLogStore); if (lastVer < commitIndex || firstVer > commitIndex + 1) { if (pNode->pLogStore->syncLogRestoreFromSnapshot(pNode->pLogStore, commitIndex)) { sError("vgId:%d, failed to restore log store from snapshot since %s. lastVer:%" PRId64 ", snapshotVer:%" PRId64, pNode->vgId, terrstr(), lastVer, commitIndex); return -1; } } return 0; } // open/close -------------- SSyncNode* syncNodeOpen(SSyncInfo* pSyncInfo) { SSyncNode* pSyncNode = taosMemoryCalloc(1, sizeof(SSyncNode)); if (pSyncNode == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; goto _error; } if (!taosDirExist((char*)(pSyncInfo->path))) { if (taosMkDir(pSyncInfo->path) != 0) { terrno = TAOS_SYSTEM_ERROR(errno); sError("failed to create dir:%s since %s", pSyncInfo->path, terrstr()); goto _error; } } memcpy(pSyncNode->path, pSyncInfo->path, sizeof(pSyncNode->path)); snprintf(pSyncNode->raftStorePath, sizeof(pSyncNode->raftStorePath), "%s%sraft_store.json", pSyncInfo->path, TD_DIRSEP); snprintf(pSyncNode->configPath, sizeof(pSyncNode->configPath), "%s%sraft_config.json", pSyncInfo->path, TD_DIRSEP); if (!taosCheckExistFile(pSyncNode->configPath)) { // create a new raft config file sInfo("vgId:%d, create a new raft config file", pSyncNode->vgId); pSyncNode->raftCfg.isStandBy = pSyncInfo->isStandBy; pSyncNode->raftCfg.snapshotStrategy = pSyncInfo->snapshotStrategy; pSyncNode->raftCfg.lastConfigIndex = SYNC_INDEX_INVALID; pSyncNode->raftCfg.batchSize = pSyncInfo->batchSize; pSyncNode->raftCfg.cfg = pSyncInfo->syncCfg; pSyncNode->raftCfg.configIndexCount = 1; pSyncNode->raftCfg.configIndexArr[0] = -1; if (syncWriteCfgFile(pSyncNode) != 0) { sError("vgId:%d, failed to create sync cfg file", pSyncNode->vgId); goto _error; } } else { // update syncCfg by raft_config.json if (syncReadCfgFile(pSyncNode) != 0) { sError("vgId:%d, failed to read sync cfg file", pSyncNode->vgId); goto _error; } if (pSyncInfo->syncCfg.replicaNum > 0 && syncIsConfigChanged(&pSyncNode->raftCfg.cfg, &pSyncInfo->syncCfg)) { sInfo("vgId:%d, use sync config from input options and write to cfg file", pSyncNode->vgId); pSyncNode->raftCfg.cfg = pSyncInfo->syncCfg; if (syncWriteCfgFile(pSyncNode) != 0) { sError("vgId:%d, failed to write sync cfg file", pSyncNode->vgId); goto _error; } } else { sInfo("vgId:%d, use sync config from sync cfg file", pSyncNode->vgId); pSyncInfo->syncCfg = pSyncNode->raftCfg.cfg; } } // init by SSyncInfo pSyncNode->vgId = pSyncInfo->vgId; SSyncCfg* pCfg = &pSyncNode->raftCfg.cfg; bool updated = false; sInfo("vgId:%d, start to open sync node, replica:%d selfIndex:%d", pSyncNode->vgId, pCfg->replicaNum, pCfg->myIndex); for (int32_t i = 0; i < pCfg->replicaNum; ++i) { SNodeInfo* pNode = &pCfg->nodeInfo[i]; if (tmsgUpdateDnodeInfo(&pNode->nodeId, &pNode->clusterId, pNode->nodeFqdn, &pNode->nodePort)) { updated = true; } sInfo("vgId:%d, index:%d ep:%s:%u dnode:%d cluster:%" PRId64, pSyncNode->vgId, i, pNode->nodeFqdn, pNode->nodePort, pNode->nodeId, pNode->clusterId); } if (updated) { sInfo("vgId:%d, save config info since dnode info changed", pSyncNode->vgId); if (syncWriteCfgFile(pSyncNode) != 0) { sError("vgId:%d, failed to write sync cfg file on dnode info updated", pSyncNode->vgId); goto _error; } } pSyncNode->pWal = pSyncInfo->pWal; pSyncNode->msgcb = pSyncInfo->msgcb; pSyncNode->syncSendMSg = pSyncInfo->syncSendMSg; pSyncNode->syncEqMsg = pSyncInfo->syncEqMsg; pSyncNode->syncEqCtrlMsg = pSyncInfo->syncEqCtrlMsg; // create raft log ring buffer pSyncNode->pLogBuf = syncLogBufferCreate(); if (pSyncNode->pLogBuf == NULL) { sError("failed to init sync log buffer since %s. vgId:%d", terrstr(), pSyncNode->vgId); goto _error; } // init internal pSyncNode->myNodeInfo = pSyncNode->raftCfg.cfg.nodeInfo[pSyncNode->raftCfg.cfg.myIndex]; if (!syncUtilNodeInfo2RaftId(&pSyncNode->myNodeInfo, pSyncNode->vgId, &pSyncNode->myRaftId)) { sError("vgId:%d, failed to determine my raft member id", pSyncNode->vgId); goto _error; } // init peersNum, peers, peersId pSyncNode->peersNum = pSyncNode->raftCfg.cfg.replicaNum - 1; int32_t j = 0; for (int32_t i = 0; i < pSyncNode->raftCfg.cfg.replicaNum; ++i) { if (i != pSyncNode->raftCfg.cfg.myIndex) { pSyncNode->peersNodeInfo[j] = pSyncNode->raftCfg.cfg.nodeInfo[i]; syncUtilNodeInfo2EpSet(&pSyncNode->peersNodeInfo[j], &pSyncNode->peersEpset[j]); j++; } } for (int32_t i = 0; i < pSyncNode->peersNum; ++i) { if (!syncUtilNodeInfo2RaftId(&pSyncNode->peersNodeInfo[i], pSyncNode->vgId, &pSyncNode->peersId[i])) { sError("vgId:%d, failed to determine raft member id, peer:%d", pSyncNode->vgId, i); goto _error; } } // init replicaNum, replicasId pSyncNode->replicaNum = pSyncNode->raftCfg.cfg.replicaNum; for (int32_t i = 0; i < pSyncNode->raftCfg.cfg.replicaNum; ++i) { if (!syncUtilNodeInfo2RaftId(&pSyncNode->raftCfg.cfg.nodeInfo[i], pSyncNode->vgId, &pSyncNode->replicasId[i])) { sError("vgId:%d, failed to determine raft member id, replica:%d", pSyncNode->vgId, i); goto _error; } } // init raft algorithm pSyncNode->pFsm = pSyncInfo->pFsm; pSyncInfo->pFsm = NULL; pSyncNode->quorum = syncUtilQuorum(pSyncNode->raftCfg.cfg.replicaNum); pSyncNode->leaderCache = EMPTY_RAFT_ID; // init life cycle outside // TLA+ Spec // InitHistoryVars == /\ elections = {} // /\ allLogs = {} // /\ voterLog = [i \in Server |-> [j \in {} |-> <<>>]] // InitServerVars == /\ currentTerm = [i \in Server |-> 1] // /\ state = [i \in Server |-> Follower] // /\ votedFor = [i \in Server |-> Nil] // InitCandidateVars == /\ votesResponded = [i \in Server |-> {}] // /\ votesGranted = [i \in Server |-> {}] // \* The values nextIndex[i][i] and matchIndex[i][i] are never read, since the // \* leader does not send itself messages. It's still easier to include these // \* in the functions. // InitLeaderVars == /\ nextIndex = [i \in Server |-> [j \in Server |-> 1]] // /\ matchIndex = [i \in Server |-> [j \in Server |-> 0]] // InitLogVars == /\ log = [i \in Server |-> << >>] // /\ commitIndex = [i \in Server |-> 0] // Init == /\ messages = [m \in {} |-> 0] // /\ InitHistoryVars // /\ InitServerVars // /\ InitCandidateVars // /\ InitLeaderVars // /\ InitLogVars // // init TLA+ server vars pSyncNode->state = TAOS_SYNC_STATE_FOLLOWER; if (raftStoreOpen(pSyncNode) != 0) { sError("vgId:%d, failed to open raft store at path %s", pSyncNode->vgId, pSyncNode->raftStorePath); goto _error; } // init TLA+ candidate vars pSyncNode->pVotesGranted = voteGrantedCreate(pSyncNode); if (pSyncNode->pVotesGranted == NULL) { sError("vgId:%d, failed to create VotesGranted", pSyncNode->vgId); goto _error; } pSyncNode->pVotesRespond = votesRespondCreate(pSyncNode); if (pSyncNode->pVotesRespond == NULL) { sError("vgId:%d, failed to create VotesRespond", pSyncNode->vgId); goto _error; } // init TLA+ leader vars pSyncNode->pNextIndex = syncIndexMgrCreate(pSyncNode); if (pSyncNode->pNextIndex == NULL) { sError("vgId:%d, failed to create SyncIndexMgr", pSyncNode->vgId); goto _error; } pSyncNode->pMatchIndex = syncIndexMgrCreate(pSyncNode); if (pSyncNode->pMatchIndex == NULL) { sError("vgId:%d, failed to create SyncIndexMgr", pSyncNode->vgId); goto _error; } // init TLA+ log vars pSyncNode->pLogStore = logStoreCreate(pSyncNode); if (pSyncNode->pLogStore == NULL) { sError("vgId:%d, failed to create SyncLogStore", pSyncNode->vgId); goto _error; } SyncIndex commitIndex = SYNC_INDEX_INVALID; if (pSyncNode->pFsm != NULL && pSyncNode->pFsm->FpGetSnapshotInfo != NULL) { SSnapshot snapshot = {0}; pSyncNode->pFsm->FpGetSnapshotInfo(pSyncNode->pFsm, &snapshot); if (snapshot.lastApplyIndex > commitIndex) { commitIndex = snapshot.lastApplyIndex; sNTrace(pSyncNode, "reset commit index by snapshot"); } } pSyncNode->commitIndex = commitIndex; sInfo("vgId:%d, sync node commitIndex initialized as %" PRId64, pSyncNode->vgId, pSyncNode->commitIndex); // restore log store on need if (syncNodeLogStoreRestoreOnNeed(pSyncNode) < 0) { sError("vgId:%d, failed to restore log store since %s.", pSyncNode->vgId, terrstr()); goto _error; } // timer ms init pSyncNode->pingBaseLine = PING_TIMER_MS; pSyncNode->electBaseLine = tsElectInterval; pSyncNode->hbBaseLine = tsHeartbeatInterval; // init ping timer pSyncNode->pPingTimer = NULL; pSyncNode->pingTimerMS = pSyncNode->pingBaseLine; atomic_store_64(&pSyncNode->pingTimerLogicClock, 0); atomic_store_64(&pSyncNode->pingTimerLogicClockUser, 0); pSyncNode->FpPingTimerCB = syncNodeEqPingTimer; pSyncNode->pingTimerCounter = 0; // init elect timer pSyncNode->pElectTimer = NULL; pSyncNode->electTimerMS = syncUtilElectRandomMS(pSyncNode->electBaseLine, 2 * pSyncNode->electBaseLine); atomic_store_64(&pSyncNode->electTimerLogicClock, 0); pSyncNode->FpElectTimerCB = syncNodeEqElectTimer; pSyncNode->electTimerCounter = 0; // init heartbeat timer pSyncNode->pHeartbeatTimer = NULL; pSyncNode->heartbeatTimerMS = pSyncNode->hbBaseLine; atomic_store_64(&pSyncNode->heartbeatTimerLogicClock, 0); atomic_store_64(&pSyncNode->heartbeatTimerLogicClockUser, 0); pSyncNode->FpHeartbeatTimerCB = syncNodeEqHeartbeatTimer; pSyncNode->heartbeatTimerCounter = 0; // init peer heartbeat timer for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { syncHbTimerInit(pSyncNode, &(pSyncNode->peerHeartbeatTimerArr[i]), (pSyncNode->replicasId)[i]); } // tools pSyncNode->pSyncRespMgr = syncRespMgrCreate(pSyncNode, SYNC_RESP_TTL_MS); if (pSyncNode->pSyncRespMgr == NULL) { sError("vgId:%d, failed to create SyncRespMgr", pSyncNode->vgId); goto _error; } // restore state pSyncNode->restoreFinish = false; // snapshot senders for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { SSyncSnapshotSender* pSender = snapshotSenderCreate(pSyncNode, i); if (pSender == NULL) return NULL; pSyncNode->senders[i] = pSender; sSDebug(pSender, "snapshot sender create while open sync node, data:%p", pSender); } // snapshot receivers pSyncNode->pNewNodeReceiver = snapshotReceiverCreate(pSyncNode, EMPTY_RAFT_ID); if (pSyncNode->pNewNodeReceiver == NULL) return NULL; sRDebug(pSyncNode->pNewNodeReceiver, "snapshot receiver create while open sync node, data:%p", pSyncNode->pNewNodeReceiver); // is config changing pSyncNode->changing = false; // replication mgr if (syncNodeLogReplInit(pSyncNode) < 0) { sError("vgId:%d, failed to init repl mgr since %s.", pSyncNode->vgId, terrstr()); goto _error; } // peer state if (syncNodePeerStateInit(pSyncNode) < 0) { sError("vgId:%d, failed to init peer stat since %s.", pSyncNode->vgId, terrstr()); goto _error; } // // min match index pSyncNode->minMatchIndex = SYNC_INDEX_INVALID; // start in syncNodeStart // start raft // syncNodeBecomeFollower(pSyncNode); int64_t timeNow = taosGetTimestampMs(); pSyncNode->startTime = timeNow; pSyncNode->leaderTime = timeNow; pSyncNode->lastReplicateTime = timeNow; // snapshotting atomic_store_64(&pSyncNode->snapshottingIndex, SYNC_INDEX_INVALID); // init log buffer if (syncLogBufferInit(pSyncNode->pLogBuf, pSyncNode) < 0) { sError("vgId:%d, failed to init sync log buffer since %s", pSyncNode->vgId, terrstr()); goto _error; } pSyncNode->isStart = true; pSyncNode->electNum = 0; pSyncNode->becomeLeaderNum = 0; pSyncNode->configChangeNum = 0; pSyncNode->hbSlowNum = 0; pSyncNode->hbrSlowNum = 0; pSyncNode->tmrRoutineNum = 0; sNInfo(pSyncNode, "sync open, node:%p electInterval:%d heartbeatInterval:%d heartbeatTimeout:%d", pSyncNode, tsElectInterval, tsHeartbeatInterval, tsHeartbeatTimeout); return pSyncNode; _error: if (pSyncInfo->pFsm) { taosMemoryFree(pSyncInfo->pFsm); pSyncInfo->pFsm = NULL; } syncNodeClose(pSyncNode); pSyncNode = NULL; return NULL; } void syncNodeMaybeUpdateCommitBySnapshot(SSyncNode* pSyncNode) { if (pSyncNode->pFsm != NULL && pSyncNode->pFsm->FpGetSnapshotInfo != NULL) { SSnapshot snapshot = {0}; pSyncNode->pFsm->FpGetSnapshotInfo(pSyncNode->pFsm, &snapshot); if (snapshot.lastApplyIndex > pSyncNode->commitIndex) { pSyncNode->commitIndex = snapshot.lastApplyIndex; } } } int32_t syncNodeRestore(SSyncNode* pSyncNode) { ASSERTS(pSyncNode->pLogStore != NULL, "log store not created"); ASSERTS(pSyncNode->pLogBuf != NULL, "ring log buffer not created"); SyncIndex lastVer = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); SyncIndex commitIndex = pSyncNode->pLogStore->syncLogCommitIndex(pSyncNode->pLogStore); SyncIndex endIndex = pSyncNode->pLogBuf->endIndex; if (lastVer != -1 && endIndex != lastVer + 1) { terrno = TSDB_CODE_WAL_LOG_INCOMPLETE; sError("vgId:%d, failed to restore sync node since %s. expected lastLogIndex:%" PRId64 ", lastVer:%" PRId64 "", pSyncNode->vgId, terrstr(), endIndex - 1, lastVer); return -1; } ASSERT(endIndex == lastVer + 1); pSyncNode->commitIndex = TMAX(pSyncNode->commitIndex, commitIndex); sInfo("vgId:%d, restore sync until commitIndex:%" PRId64, pSyncNode->vgId, pSyncNode->commitIndex); if (syncLogBufferCommit(pSyncNode->pLogBuf, pSyncNode, pSyncNode->commitIndex) < 0) { return -1; } return 0; } int32_t syncNodeStart(SSyncNode* pSyncNode) { // start raft if (pSyncNode->replicaNum == 1) { raftStoreNextTerm(pSyncNode); syncNodeBecomeLeader(pSyncNode, "one replica start"); // Raft 3.6.2 Committing entries from previous terms syncNodeAppendNoop(pSyncNode); } else { syncNodeBecomeFollower(pSyncNode, "first start"); } int32_t ret = 0; ret = syncNodeStartPingTimer(pSyncNode); if (ret != 0) { sError("vgId:%d, failed to start ping timer since %s", pSyncNode->vgId, terrstr()); } return ret; } int32_t syncNodeStartStandBy(SSyncNode* pSyncNode) { // state change pSyncNode->state = TAOS_SYNC_STATE_FOLLOWER; syncNodeStopHeartbeatTimer(pSyncNode); // reset elect timer, long enough int32_t electMS = TIMER_MAX_MS; int32_t ret = syncNodeRestartElectTimer(pSyncNode, electMS); if (ret < 0) { sError("vgId:%d, failed to restart elect timer since %s", pSyncNode->vgId, terrstr()); return -1; } ret = syncNodeStartPingTimer(pSyncNode); if (ret < 0) { sError("vgId:%d, failed to start ping timer since %s", pSyncNode->vgId, terrstr()); return -1; } return ret; } void syncNodePreClose(SSyncNode* pSyncNode) { ASSERT(pSyncNode != NULL); ASSERT(pSyncNode->pFsm != NULL); ASSERT(pSyncNode->pFsm->FpApplyQueueItems != NULL); // stop elect timer syncNodeStopElectTimer(pSyncNode); // stop heartbeat timer syncNodeStopHeartbeatTimer(pSyncNode); // stop ping timer syncNodeStopPingTimer(pSyncNode); // clean rsp syncRespCleanRsp(pSyncNode->pSyncRespMgr); } void syncNodePostClose(SSyncNode* pSyncNode) { if (pSyncNode->pNewNodeReceiver != NULL) { if (snapshotReceiverIsStart(pSyncNode->pNewNodeReceiver)) { snapshotReceiverStop(pSyncNode->pNewNodeReceiver); } sDebug("vgId:%d, snapshot receiver destroy while preclose sync node, data:%p", pSyncNode->vgId, pSyncNode->pNewNodeReceiver); snapshotReceiverDestroy(pSyncNode->pNewNodeReceiver); pSyncNode->pNewNodeReceiver = NULL; } } void syncHbTimerDataFree(SSyncHbTimerData* pData) { taosMemoryFree(pData); } void syncNodeClose(SSyncNode* pSyncNode) { if (pSyncNode == NULL) return; sNInfo(pSyncNode, "sync close, node:%p", pSyncNode); syncRespCleanRsp(pSyncNode->pSyncRespMgr); syncNodeStopPingTimer(pSyncNode); syncNodeStopElectTimer(pSyncNode); syncNodeStopHeartbeatTimer(pSyncNode); syncNodeLogReplDestroy(pSyncNode); syncRespMgrDestroy(pSyncNode->pSyncRespMgr); pSyncNode->pSyncRespMgr = NULL; voteGrantedDestroy(pSyncNode->pVotesGranted); pSyncNode->pVotesGranted = NULL; votesRespondDestory(pSyncNode->pVotesRespond); pSyncNode->pVotesRespond = NULL; syncIndexMgrDestroy(pSyncNode->pNextIndex); pSyncNode->pNextIndex = NULL; syncIndexMgrDestroy(pSyncNode->pMatchIndex); pSyncNode->pMatchIndex = NULL; logStoreDestory(pSyncNode->pLogStore); pSyncNode->pLogStore = NULL; syncLogBufferDestroy(pSyncNode->pLogBuf); pSyncNode->pLogBuf = NULL; for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { if (pSyncNode->senders[i] != NULL) { sDebug("vgId:%d, snapshot sender destroy while close, data:%p", pSyncNode->vgId, pSyncNode->senders[i]); if (snapshotSenderIsStart(pSyncNode->senders[i])) { snapshotSenderStop(pSyncNode->senders[i], false); } snapshotSenderDestroy(pSyncNode->senders[i]); pSyncNode->senders[i] = NULL; } } if (pSyncNode->pNewNodeReceiver != NULL) { if (snapshotReceiverIsStart(pSyncNode->pNewNodeReceiver)) { snapshotReceiverStop(pSyncNode->pNewNodeReceiver); } sDebug("vgId:%d, snapshot receiver destroy while close, data:%p", pSyncNode->vgId, pSyncNode->pNewNodeReceiver); snapshotReceiverDestroy(pSyncNode->pNewNodeReceiver); pSyncNode->pNewNodeReceiver = NULL; } if (pSyncNode->pFsm != NULL) { taosMemoryFree(pSyncNode->pFsm); } raftStoreClose(pSyncNode); taosMemoryFree(pSyncNode); } ESyncStrategy syncNodeStrategy(SSyncNode* pSyncNode) { return pSyncNode->raftCfg.snapshotStrategy; } // timer control -------------- int32_t syncNodeStartPingTimer(SSyncNode* pSyncNode) { int32_t ret = 0; if (syncIsInit()) { taosTmrReset(pSyncNode->FpPingTimerCB, pSyncNode->pingTimerMS, pSyncNode, syncEnv()->pTimerManager, &pSyncNode->pPingTimer); atomic_store_64(&pSyncNode->pingTimerLogicClock, pSyncNode->pingTimerLogicClockUser); } else { sError("vgId:%d, start ping timer error, sync env is stop", pSyncNode->vgId); } return ret; } int32_t syncNodeStopPingTimer(SSyncNode* pSyncNode) { int32_t ret = 0; atomic_add_fetch_64(&pSyncNode->pingTimerLogicClockUser, 1); taosTmrStop(pSyncNode->pPingTimer); pSyncNode->pPingTimer = NULL; return ret; } int32_t syncNodeStartElectTimer(SSyncNode* pSyncNode, int32_t ms) { int32_t ret = 0; if (syncIsInit()) { pSyncNode->electTimerMS = ms; int64_t execTime = taosGetTimestampMs() + ms; atomic_store_64(&(pSyncNode->electTimerParam.executeTime), execTime); atomic_store_64(&(pSyncNode->electTimerParam.logicClock), pSyncNode->electTimerLogicClock); pSyncNode->electTimerParam.pSyncNode = pSyncNode; pSyncNode->electTimerParam.pData = NULL; taosTmrReset(pSyncNode->FpElectTimerCB, pSyncNode->electTimerMS, (void*)(pSyncNode->rid), syncEnv()->pTimerManager, &pSyncNode->pElectTimer); } else { sError("vgId:%d, start elect timer error, sync env is stop", pSyncNode->vgId); } return ret; } int32_t syncNodeStopElectTimer(SSyncNode* pSyncNode) { int32_t ret = 0; atomic_add_fetch_64(&pSyncNode->electTimerLogicClock, 1); taosTmrStop(pSyncNode->pElectTimer); pSyncNode->pElectTimer = NULL; return ret; } int32_t syncNodeRestartElectTimer(SSyncNode* pSyncNode, int32_t ms) { int32_t ret = 0; syncNodeStopElectTimer(pSyncNode); syncNodeStartElectTimer(pSyncNode, ms); return ret; } void syncNodeResetElectTimer(SSyncNode* pSyncNode) { int32_t electMS; if (pSyncNode->raftCfg.isStandBy) { electMS = TIMER_MAX_MS; } else { electMS = syncUtilElectRandomMS(pSyncNode->electBaseLine, 2 * pSyncNode->electBaseLine); } (void)syncNodeRestartElectTimer(pSyncNode, electMS); sNTrace(pSyncNode, "reset elect timer, min:%d, max:%d, ms:%d", pSyncNode->electBaseLine, 2 * pSyncNode->electBaseLine, electMS); } static int32_t syncNodeDoStartHeartbeatTimer(SSyncNode* pSyncNode) { int32_t ret = 0; if (syncIsInit()) { taosTmrReset(pSyncNode->FpHeartbeatTimerCB, pSyncNode->heartbeatTimerMS, pSyncNode, syncEnv()->pTimerManager, &pSyncNode->pHeartbeatTimer); atomic_store_64(&pSyncNode->heartbeatTimerLogicClock, pSyncNode->heartbeatTimerLogicClockUser); } else { sError("vgId:%d, start heartbeat timer error, sync env is stop", pSyncNode->vgId); } sNTrace(pSyncNode, "start heartbeat timer, ms:%d", pSyncNode->heartbeatTimerMS); return ret; } int32_t syncNodeStartHeartbeatTimer(SSyncNode* pSyncNode) { int32_t ret = 0; #if 0 pSyncNode->heartbeatTimerMS = pSyncNode->hbBaseLine; ret = syncNodeDoStartHeartbeatTimer(pSyncNode); #endif for (int32_t i = 0; i < pSyncNode->peersNum; ++i) { SSyncTimer* pSyncTimer = syncNodeGetHbTimer(pSyncNode, &(pSyncNode->peersId[i])); if (pSyncTimer != NULL) { syncHbTimerStart(pSyncNode, pSyncTimer); } } return ret; } int32_t syncNodeStopHeartbeatTimer(SSyncNode* pSyncNode) { int32_t ret = 0; #if 0 atomic_add_fetch_64(&pSyncNode->heartbeatTimerLogicClockUser, 1); taosTmrStop(pSyncNode->pHeartbeatTimer); pSyncNode->pHeartbeatTimer = NULL; #endif for (int32_t i = 0; i < pSyncNode->peersNum; ++i) { SSyncTimer* pSyncTimer = syncNodeGetHbTimer(pSyncNode, &(pSyncNode->peersId[i])); if (pSyncTimer != NULL) { syncHbTimerStop(pSyncNode, pSyncTimer); } } return ret; } int32_t syncNodeRestartHeartbeatTimer(SSyncNode* pSyncNode) { syncNodeStopHeartbeatTimer(pSyncNode); syncNodeStartHeartbeatTimer(pSyncNode); return 0; } int32_t syncNodeSendMsgById(const SRaftId* destRaftId, SSyncNode* pNode, SRpcMsg* pMsg) { SEpSet* epSet = NULL; for (int32_t i = 0; i < pNode->peersNum; ++i) { if (destRaftId->addr == pNode->peersId[i].addr) { epSet = &pNode->peersEpset[i]; break; } } int32_t code = -1; if (pNode->syncSendMSg != NULL && epSet != NULL) { syncUtilMsgHtoN(pMsg->pCont); pMsg->info.noResp = 1; code = pNode->syncSendMSg(epSet, pMsg); } if (code < 0) { sError("vgId:%d, sync send msg by id error, epset:%p dnode:%d addr:%" PRId64 " err:0x%x", pNode->vgId, epSet, DID(destRaftId), destRaftId->addr, terrno); rpcFreeCont(pMsg->pCont); terrno = TSDB_CODE_SYN_INTERNAL_ERROR; } return code; } inline bool syncNodeInConfig(SSyncNode* pNode, const SSyncCfg* pCfg) { bool b1 = false; bool b2 = false; for (int32_t i = 0; i < pCfg->replicaNum; ++i) { if (strcmp(pCfg->nodeInfo[i].nodeFqdn, pNode->myNodeInfo.nodeFqdn) == 0 && pCfg->nodeInfo[i].nodePort == pNode->myNodeInfo.nodePort) { b1 = true; break; } } for (int32_t i = 0; i < pCfg->replicaNum; ++i) { SRaftId raftId = { .addr = SYNC_ADDR(&pCfg->nodeInfo[i]), .vgId = pNode->vgId, }; if (syncUtilSameId(&raftId, &pNode->myRaftId)) { b2 = true; break; } } ASSERT(b1 == b2); return b1; } static bool syncIsConfigChanged(const SSyncCfg* pOldCfg, const SSyncCfg* pNewCfg) { if (pOldCfg->replicaNum != pNewCfg->replicaNum) return true; if (pOldCfg->myIndex != pNewCfg->myIndex) return true; for (int32_t i = 0; i < pOldCfg->replicaNum; ++i) { const SNodeInfo* pOldInfo = &pOldCfg->nodeInfo[i]; const SNodeInfo* pNewInfo = &pNewCfg->nodeInfo[i]; if (strcmp(pOldInfo->nodeFqdn, pNewInfo->nodeFqdn) != 0) return true; if (pOldInfo->nodePort != pNewInfo->nodePort) return true; } return false; } void syncNodeDoConfigChange(SSyncNode* pSyncNode, SSyncCfg* pNewConfig, SyncIndex lastConfigChangeIndex) { SSyncCfg oldConfig = pSyncNode->raftCfg.cfg; if (!syncIsConfigChanged(&oldConfig, pNewConfig)) { sInfo("vgId:1, sync not reconfig since not changed"); return; } pSyncNode->raftCfg.cfg = *pNewConfig; pSyncNode->raftCfg.lastConfigIndex = lastConfigChangeIndex; pSyncNode->configChangeNum++; bool IamInOld = syncNodeInConfig(pSyncNode, &oldConfig); bool IamInNew = syncNodeInConfig(pSyncNode, pNewConfig); bool isDrop = false; bool isAdd = false; if (IamInOld && !IamInNew) { isDrop = true; } else { isDrop = false; } if (!IamInOld && IamInNew) { isAdd = true; } else { isAdd = false; } // log begin config change sNInfo(pSyncNode, "begin do config change, from %d to %d, replicas:%d", pSyncNode->vgId, oldConfig.replicaNum, pNewConfig->replicaNum); if (IamInNew) { pSyncNode->raftCfg.isStandBy = 0; // change isStandBy to normal } if (isDrop) { pSyncNode->raftCfg.isStandBy = 1; // set standby } // add last config index syncAddCfgIndex(pSyncNode, lastConfigChangeIndex); if (IamInNew) { //----------------------------------------- int32_t ret = 0; // save snapshot senders int32_t oldReplicaNum = pSyncNode->replicaNum; SRaftId oldReplicasId[TSDB_MAX_REPLICA]; memcpy(oldReplicasId, pSyncNode->replicasId, sizeof(oldReplicasId)); SSyncSnapshotSender* oldSenders[TSDB_MAX_REPLICA]; for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { oldSenders[i] = pSyncNode->senders[i]; sSTrace(oldSenders[i], "snapshot sender save old"); } // init internal pSyncNode->myNodeInfo = pSyncNode->raftCfg.cfg.nodeInfo[pSyncNode->raftCfg.cfg.myIndex]; syncUtilNodeInfo2RaftId(&pSyncNode->myNodeInfo, pSyncNode->vgId, &pSyncNode->myRaftId); // init peersNum, peers, peersId pSyncNode->peersNum = pSyncNode->raftCfg.cfg.replicaNum - 1; int32_t j = 0; for (int32_t i = 0; i < pSyncNode->raftCfg.cfg.replicaNum; ++i) { if (i != pSyncNode->raftCfg.cfg.myIndex) { pSyncNode->peersNodeInfo[j] = pSyncNode->raftCfg.cfg.nodeInfo[i]; syncUtilNodeInfo2EpSet(&pSyncNode->peersNodeInfo[j], &pSyncNode->peersEpset[j]); j++; } } for (int32_t i = 0; i < pSyncNode->peersNum; ++i) { syncUtilNodeInfo2RaftId(&pSyncNode->peersNodeInfo[i], pSyncNode->vgId, &pSyncNode->peersId[i]); } // init replicaNum, replicasId pSyncNode->replicaNum = pSyncNode->raftCfg.cfg.replicaNum; for (int32_t i = 0; i < pSyncNode->raftCfg.cfg.replicaNum; ++i) { syncUtilNodeInfo2RaftId(&pSyncNode->raftCfg.cfg.nodeInfo[i], pSyncNode->vgId, &pSyncNode->replicasId[i]); } // update quorum first pSyncNode->quorum = syncUtilQuorum(pSyncNode->raftCfg.cfg.replicaNum); syncIndexMgrUpdate(pSyncNode->pNextIndex, pSyncNode); syncIndexMgrUpdate(pSyncNode->pMatchIndex, pSyncNode); voteGrantedUpdate(pSyncNode->pVotesGranted, pSyncNode); votesRespondUpdate(pSyncNode->pVotesRespond, pSyncNode); // reset snapshot senders // clear new for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { pSyncNode->senders[i] = NULL; } // reset new for (int32_t i = 0; i < pSyncNode->replicaNum; ++i) { // reset sender bool reset = false; for (int32_t j = 0; j < TSDB_MAX_REPLICA; ++j) { if (syncUtilSameId(&(pSyncNode->replicasId)[i], &oldReplicasId[j]) && oldSenders[j] != NULL) { sNTrace(pSyncNode, "snapshot sender reset for:%" PRId64 ", newIndex:%d, dnode:%d, %p", (pSyncNode->replicasId)[i].addr, i, DID(&pSyncNode->replicasId[i]), oldSenders[j]); pSyncNode->senders[i] = oldSenders[j]; oldSenders[j] = NULL; reset = true; // reset replicaIndex int32_t oldreplicaIndex = pSyncNode->senders[i]->replicaIndex; pSyncNode->senders[i]->replicaIndex = i; sNTrace(pSyncNode, "snapshot sender udpate replicaIndex from %d to %d, dnode:%d, %p, reset:%d", oldreplicaIndex, i, DID(&pSyncNode->replicasId[i]), pSyncNode->senders[i], reset); break; } } } // create new for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { if (pSyncNode->senders[i] == NULL) { pSyncNode->senders[i] = snapshotSenderCreate(pSyncNode, i); if (pSyncNode->senders[i] == NULL) { // will be created later while send snapshot sSError(pSyncNode->senders[i], "snapshot sender create failed while reconfig"); } else { sSDebug(pSyncNode->senders[i], "snapshot sender create while reconfig, data:%p", pSyncNode->senders[i]); } } else { sSDebug(pSyncNode->senders[i], "snapshot sender already exist, data:%p", pSyncNode->senders[i]); } } // free old for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { if (oldSenders[i] != NULL) { sSDebug(oldSenders[i], "snapshot sender destroy old, data:%p replica-index:%d", oldSenders[i], i); snapshotSenderDestroy(oldSenders[i]); oldSenders[i] = NULL; } } // persist cfg syncWriteCfgFile(pSyncNode); // change isStandBy to normal (election timeout) if (pSyncNode->state == TAOS_SYNC_STATE_LEADER) { syncNodeBecomeLeader(pSyncNode, ""); // Raft 3.6.2 Committing entries from previous terms syncNodeAppendNoop(pSyncNode); // syncMaybeAdvanceCommitIndex(pSyncNode); } else { syncNodeBecomeFollower(pSyncNode, ""); } } else { // persist cfg syncWriteCfgFile(pSyncNode); sNInfo(pSyncNode, "do not config change from %d to %d", oldConfig.replicaNum, pNewConfig->replicaNum); } _END: // log end config change sNInfo(pSyncNode, "end do config change, from %d to %d", oldConfig.replicaNum, pNewConfig->replicaNum); } // raft state change -------------- void syncNodeUpdateTerm(SSyncNode* pSyncNode, SyncTerm term) { if (term > raftStoreGetTerm(pSyncNode)) { raftStoreSetTerm(pSyncNode, term); char tmpBuf[64]; snprintf(tmpBuf, sizeof(tmpBuf), "update term to %" PRId64, term); syncNodeBecomeFollower(pSyncNode, tmpBuf); raftStoreClearVote(pSyncNode); } } void syncNodeUpdateTermWithoutStepDown(SSyncNode* pSyncNode, SyncTerm term) { if (term > raftStoreGetTerm(pSyncNode)) { raftStoreSetTerm(pSyncNode, term); } } void syncNodeStepDown(SSyncNode* pSyncNode, SyncTerm newTerm) { SyncTerm currentTerm = raftStoreGetTerm(pSyncNode); if (currentTerm > newTerm) { sNTrace(pSyncNode, "step down, ignore, new-term:%" PRId64 ", current-term:%" PRId64, newTerm, currentTerm); return; } do { sNTrace(pSyncNode, "step down, new-term:%" PRId64 ", current-term:%" PRId64, newTerm, currentTerm); } while (0); if (currentTerm < newTerm) { raftStoreSetTerm(pSyncNode, newTerm); char tmpBuf[64]; snprintf(tmpBuf, sizeof(tmpBuf), "step down, update term to %" PRId64, newTerm); syncNodeBecomeFollower(pSyncNode, tmpBuf); raftStoreClearVote(pSyncNode); } else { if (pSyncNode->state != TAOS_SYNC_STATE_FOLLOWER) { syncNodeBecomeFollower(pSyncNode, "step down"); } } } void syncNodeLeaderChangeRsp(SSyncNode* pSyncNode) { syncRespCleanRsp(pSyncNode->pSyncRespMgr); } void syncNodeBecomeFollower(SSyncNode* pSyncNode, const char* debugStr) { // maybe clear leader cache if (pSyncNode->state == TAOS_SYNC_STATE_LEADER) { pSyncNode->leaderCache = EMPTY_RAFT_ID; } pSyncNode->hbSlowNum = 0; // state change pSyncNode->state = TAOS_SYNC_STATE_FOLLOWER; syncNodeStopHeartbeatTimer(pSyncNode); // trace log sNTrace(pSyncNode, "become follower %s", debugStr); // send rsp to client syncNodeLeaderChangeRsp(pSyncNode); // call back if (pSyncNode->pFsm != NULL && pSyncNode->pFsm->FpBecomeFollowerCb != NULL) { pSyncNode->pFsm->FpBecomeFollowerCb(pSyncNode->pFsm); } // min match index pSyncNode->minMatchIndex = SYNC_INDEX_INVALID; // reset log buffer syncLogBufferReset(pSyncNode->pLogBuf, pSyncNode); // reset elect timer syncNodeResetElectTimer(pSyncNode); } // TLA+ Spec // \* Candidate i transitions to leader. // BecomeLeader(i) == // /\ state[i] = Candidate // /\ votesGranted[i] \in Quorum // /\ state' = [state EXCEPT ![i] = Leader] // /\ nextIndex' = [nextIndex EXCEPT ![i] = // [j \in Server |-> Len(log[i]) + 1]] // /\ matchIndex' = [matchIndex EXCEPT ![i] = // [j \in Server |-> 0]] // /\ elections' = elections \cup // {[eterm |-> currentTerm[i], // eleader |-> i, // elog |-> log[i], // evotes |-> votesGranted[i], // evoterLog |-> voterLog[i]]} // /\ UNCHANGED <> // void syncNodeBecomeLeader(SSyncNode* pSyncNode, const char* debugStr) { pSyncNode->leaderTime = taosGetTimestampMs(); pSyncNode->becomeLeaderNum++; pSyncNode->hbrSlowNum = 0; // reset restoreFinish pSyncNode->restoreFinish = false; // state change pSyncNode->state = TAOS_SYNC_STATE_LEADER; // set leader cache pSyncNode->leaderCache = pSyncNode->myRaftId; for (int32_t i = 0; i < pSyncNode->pNextIndex->replicaNum; ++i) { SyncIndex lastIndex; SyncTerm lastTerm; int32_t code = syncNodeGetLastIndexTerm(pSyncNode, &lastIndex, &lastTerm); ASSERT(code == 0); pSyncNode->pNextIndex->index[i] = lastIndex + 1; } for (int32_t i = 0; i < pSyncNode->pMatchIndex->replicaNum; ++i) { // maybe overwrite myself, no harm // just do it! pSyncNode->pMatchIndex->index[i] = SYNC_INDEX_INVALID; } // init peer mgr syncNodePeerStateInit(pSyncNode); #if 0 // update sender private term SSyncSnapshotSender* pMySender = syncNodeGetSnapshotSender(pSyncNode, &(pSyncNode->myRaftId)); if (pMySender != NULL) { for (int32_t i = 0; i < pSyncNode->pMatchIndex->replicaNum; ++i) { if (pSyncNode->senders[i]->privateTerm > pMySender->privateTerm) { pMySender->privateTerm = pSyncNode->senders[i]->privateTerm; } } (pMySender->privateTerm) += 100; } #endif // close receiver if (snapshotReceiverIsStart(pSyncNode->pNewNodeReceiver)) { snapshotReceiverStop(pSyncNode->pNewNodeReceiver); } // stop elect timer syncNodeStopElectTimer(pSyncNode); // start heartbeat timer syncNodeStartHeartbeatTimer(pSyncNode); // send heartbeat right now syncNodeHeartbeatPeers(pSyncNode); // call back if (pSyncNode->pFsm != NULL && pSyncNode->pFsm->FpBecomeLeaderCb != NULL) { pSyncNode->pFsm->FpBecomeLeaderCb(pSyncNode->pFsm); } // min match index pSyncNode->minMatchIndex = SYNC_INDEX_INVALID; // reset log buffer syncLogBufferReset(pSyncNode->pLogBuf, pSyncNode); // trace log sNInfo(pSyncNode, "become leader %s", debugStr); } void syncNodeCandidate2Leader(SSyncNode* pSyncNode) { ASSERT(pSyncNode->state == TAOS_SYNC_STATE_CANDIDATE); bool granted = voteGrantedMajority(pSyncNode->pVotesGranted); if (!granted) { sError("vgId:%d, not granted by majority.", pSyncNode->vgId); return; } syncNodeBecomeLeader(pSyncNode, "candidate to leader"); sNTrace(pSyncNode, "state change syncNodeCandidate2Leader"); int32_t ret = syncNodeAppendNoop(pSyncNode); if (ret < 0) { sError("vgId:%d, failed to append noop entry since %s", pSyncNode->vgId, terrstr()); } SyncIndex lastIndex = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); ASSERT(lastIndex >= 0); sInfo("vgId:%d, become leader. term:%" PRId64 ", commit index:%" PRId64 ", last index:%" PRId64 "", pSyncNode->vgId, raftStoreGetTerm(pSyncNode), pSyncNode->commitIndex, lastIndex); } bool syncNodeIsMnode(SSyncNode* pSyncNode) { return (pSyncNode->vgId == 1); } int32_t syncNodePeerStateInit(SSyncNode* pSyncNode) { for (int32_t i = 0; i < TSDB_MAX_REPLICA; ++i) { pSyncNode->peerStates[i].lastSendIndex = SYNC_INDEX_INVALID; pSyncNode->peerStates[i].lastSendTime = 0; } return 0; } void syncNodeFollower2Candidate(SSyncNode* pSyncNode) { ASSERT(pSyncNode->state == TAOS_SYNC_STATE_FOLLOWER); pSyncNode->state = TAOS_SYNC_STATE_CANDIDATE; SyncIndex lastIndex = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); sInfo("vgId:%d, become candidate from follower. term:%" PRId64 ", commit index:%" PRId64 ", last index:%" PRId64, pSyncNode->vgId, raftStoreGetTerm(pSyncNode), pSyncNode->commitIndex, lastIndex); sNTrace(pSyncNode, "follower to candidate"); } void syncNodeLeader2Follower(SSyncNode* pSyncNode) { ASSERT(pSyncNode->state == TAOS_SYNC_STATE_LEADER); syncNodeBecomeFollower(pSyncNode, "leader to follower"); SyncIndex lastIndex = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); sInfo("vgId:%d, become follower from leader. term:%" PRId64 ", commit index:%" PRId64 ", last index:%" PRId64, pSyncNode->vgId, raftStoreGetTerm(pSyncNode), pSyncNode->commitIndex, lastIndex); sNTrace(pSyncNode, "leader to follower"); } void syncNodeCandidate2Follower(SSyncNode* pSyncNode) { ASSERT(pSyncNode->state == TAOS_SYNC_STATE_CANDIDATE); syncNodeBecomeFollower(pSyncNode, "candidate to follower"); SyncIndex lastIndex = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); sInfo("vgId:%d, become follower from candidate. term:%" PRId64 ", commit index:%" PRId64 ", last index:%" PRId64, pSyncNode->vgId, raftStoreGetTerm(pSyncNode), pSyncNode->commitIndex, lastIndex); sNTrace(pSyncNode, "candidate to follower"); } // just called by syncNodeVoteForSelf // need assert void syncNodeVoteForTerm(SSyncNode* pSyncNode, SyncTerm term, SRaftId* pRaftId) { ASSERT(term == raftStoreGetTerm(pSyncNode)); bool voted = raftStoreHasVoted(pSyncNode); ASSERT(!voted); raftStoreVote(pSyncNode, pRaftId); } // simulate get vote from outside void syncNodeVoteForSelf(SSyncNode* pSyncNode, SyncTerm currentTerm) { syncNodeVoteForTerm(pSyncNode, currentTerm, &pSyncNode->myRaftId); SRpcMsg rpcMsg = {0}; int32_t ret = syncBuildRequestVoteReply(&rpcMsg, pSyncNode->vgId); if (ret != 0) return; SyncRequestVoteReply* pMsg = rpcMsg.pCont; pMsg->srcId = pSyncNode->myRaftId; pMsg->destId = pSyncNode->myRaftId; pMsg->term = currentTerm; pMsg->voteGranted = true; voteGrantedVote(pSyncNode->pVotesGranted, pMsg); votesRespondAdd(pSyncNode->pVotesRespond, pMsg); rpcFreeCont(rpcMsg.pCont); } // return if has a snapshot bool syncNodeHasSnapshot(SSyncNode* pSyncNode) { bool ret = false; SSnapshot snapshot = {.data = NULL, .lastApplyIndex = -1, .lastApplyTerm = 0, .lastConfigIndex = -1}; if (pSyncNode->pFsm->FpGetSnapshotInfo != NULL) { pSyncNode->pFsm->FpGetSnapshotInfo(pSyncNode->pFsm, &snapshot); if (snapshot.lastApplyIndex >= SYNC_INDEX_BEGIN) { ret = true; } } return ret; } // return max(logLastIndex, snapshotLastIndex) // if no snapshot and log, return -1 SyncIndex syncNodeGetLastIndex(const SSyncNode* pSyncNode) { SSnapshot snapshot = {.data = NULL, .lastApplyIndex = -1, .lastApplyTerm = 0, .lastConfigIndex = -1}; if (pSyncNode->pFsm->FpGetSnapshotInfo != NULL) { pSyncNode->pFsm->FpGetSnapshotInfo(pSyncNode->pFsm, &snapshot); } SyncIndex logLastIndex = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); SyncIndex lastIndex = logLastIndex > snapshot.lastApplyIndex ? logLastIndex : snapshot.lastApplyIndex; return lastIndex; } // return the last term of snapshot and log // if error, return SYNC_TERM_INVALID (by syncLogLastTerm) SyncTerm syncNodeGetLastTerm(SSyncNode* pSyncNode) { SyncTerm lastTerm = 0; if (syncNodeHasSnapshot(pSyncNode)) { // has snapshot SSnapshot snapshot = {.data = NULL, .lastApplyIndex = -1, .lastApplyTerm = 0, .lastConfigIndex = -1}; if (pSyncNode->pFsm->FpGetSnapshotInfo != NULL) { pSyncNode->pFsm->FpGetSnapshotInfo(pSyncNode->pFsm, &snapshot); } SyncIndex logLastIndex = pSyncNode->pLogStore->syncLogLastIndex(pSyncNode->pLogStore); if (logLastIndex > snapshot.lastApplyIndex) { lastTerm = pSyncNode->pLogStore->syncLogLastTerm(pSyncNode->pLogStore); } else { lastTerm = snapshot.lastApplyTerm; } } else { // no snapshot lastTerm = pSyncNode->pLogStore->syncLogLastTerm(pSyncNode->pLogStore); } return lastTerm; } // get last index and term along with snapshot int32_t syncNodeGetLastIndexTerm(SSyncNode* pSyncNode, SyncIndex* pLastIndex, SyncTerm* pLastTerm) { *pLastIndex = syncNodeGetLastIndex(pSyncNode); *pLastTerm = syncNodeGetLastTerm(pSyncNode); return 0; } // return append-entries first try index SyncIndex syncNodeSyncStartIndex(SSyncNode* pSyncNode) { SyncIndex syncStartIndex = syncNodeGetLastIndex(pSyncNode) + 1; return syncStartIndex; } // if index > 0, return index - 1 // else, return -1 SyncIndex syncNodeGetPreIndex(SSyncNode* pSyncNode, SyncIndex index) { SyncIndex preIndex = index - 1; if (preIndex < SYNC_INDEX_INVALID) { preIndex = SYNC_INDEX_INVALID; } return preIndex; } // if index < 0, return SYNC_TERM_INVALID // if index == 0, return 0 // if index > 0, return preTerm // if error, return SYNC_TERM_INVALID SyncTerm syncNodeGetPreTerm(SSyncNode* pSyncNode, SyncIndex index) { if (index < SYNC_INDEX_BEGIN) { return SYNC_TERM_INVALID; } if (index == SYNC_INDEX_BEGIN) { return 0; } SyncTerm preTerm = 0; SyncIndex preIndex = index - 1; SSyncRaftEntry* pPreEntry = NULL; SLRUCache* pCache = pSyncNode->pLogStore->pCache; LRUHandle* h = taosLRUCacheLookup(pCache, &preIndex, sizeof(preIndex)); int32_t code = 0; if (h) { pPreEntry = (SSyncRaftEntry*)taosLRUCacheValue(pCache, h); code = 0; pSyncNode->pLogStore->cacheHit++; sNTrace(pSyncNode, "hit cache index:%" PRId64 ", bytes:%u, %p", preIndex, pPreEntry->bytes, pPreEntry); } else { pSyncNode->pLogStore->cacheMiss++; sNTrace(pSyncNode, "miss cache index:%" PRId64, preIndex); code = pSyncNode->pLogStore->syncLogGetEntry(pSyncNode->pLogStore, preIndex, &pPreEntry); } SSnapshot snapshot = {.data = NULL, .lastApplyIndex = SYNC_INDEX_INVALID, .lastApplyTerm = SYNC_TERM_INVALID, .lastConfigIndex = SYNC_INDEX_INVALID}; if (code == 0) { ASSERT(pPreEntry != NULL); preTerm = pPreEntry->term; if (h) { taosLRUCacheRelease(pCache, h, false); } else { syncEntryDestroy(pPreEntry); } return preTerm; } else { if (pSyncNode->pFsm->FpGetSnapshotInfo != NULL) { pSyncNode->pFsm->FpGetSnapshotInfo(pSyncNode->pFsm, &snapshot); if (snapshot.lastApplyIndex == preIndex) { return snapshot.lastApplyTerm; } } } sNError(pSyncNode, "sync node get pre term error, index:%" PRId64 ", snap-index:%" PRId64 ", snap-term:%" PRId64, index, snapshot.lastApplyIndex, snapshot.lastApplyTerm); return SYNC_TERM_INVALID; } // get pre index and term of "index" int32_t syncNodeGetPreIndexTerm(SSyncNode* pSyncNode, SyncIndex index, SyncIndex* pPreIndex, SyncTerm* pPreTerm) { *pPreIndex = syncNodeGetPreIndex(pSyncNode, index); *pPreTerm = syncNodeGetPreTerm(pSyncNode, index); return 0; } static void syncNodeEqPingTimer(void* param, void* tmrId) { if (!syncIsInit()) return; SSyncNode* pNode = param; if (atomic_load_64(&pNode->pingTimerLogicClockUser) <= atomic_load_64(&pNode->pingTimerLogicClock)) { SRpcMsg rpcMsg = {0}; int32_t code = syncBuildTimeout(&rpcMsg, SYNC_TIMEOUT_PING, atomic_load_64(&pNode->pingTimerLogicClock), pNode->pingTimerMS, pNode); if (code != 0) { sError("failed to build ping msg"); rpcFreeCont(rpcMsg.pCont); return; } // sTrace("enqueue ping msg"); code = pNode->syncEqMsg(pNode->msgcb, &rpcMsg); if (code != 0) { sError("failed to sync enqueue ping msg since %s", terrstr()); rpcFreeCont(rpcMsg.pCont); return; } taosTmrReset(syncNodeEqPingTimer, pNode->pingTimerMS, pNode, syncEnv()->pTimerManager, &pNode->pPingTimer); } } static void syncNodeEqElectTimer(void* param, void* tmrId) { if (!syncIsInit()) return; int64_t rid = (int64_t)param; SSyncNode* pNode = syncNodeAcquire(rid); if (pNode == NULL) return; if (pNode->syncEqMsg == NULL) { syncNodeRelease(pNode); return; } int64_t tsNow = taosGetTimestampMs(); if (tsNow < pNode->electTimerParam.executeTime) { syncNodeRelease(pNode); return; } SRpcMsg rpcMsg = {0}; int32_t code = syncBuildTimeout(&rpcMsg, SYNC_TIMEOUT_ELECTION, pNode->electTimerParam.logicClock, pNode->electTimerMS, pNode); if (code != 0) { sError("failed to build elect msg"); syncNodeRelease(pNode); return; } SyncTimeout* pTimeout = rpcMsg.pCont; sNTrace(pNode, "enqueue elect msg lc:%" PRId64, pTimeout->logicClock); code = pNode->syncEqMsg(pNode->msgcb, &rpcMsg); if (code != 0) { sError("failed to sync enqueue elect msg since %s", terrstr()); rpcFreeCont(rpcMsg.pCont); syncNodeRelease(pNode); return; } syncNodeRelease(pNode); } static void syncNodeEqHeartbeatTimer(void* param, void* tmrId) { if (!syncIsInit()) return; SSyncNode* pNode = param; if (pNode->replicaNum > 1) { if (atomic_load_64(&pNode->heartbeatTimerLogicClockUser) <= atomic_load_64(&pNode->heartbeatTimerLogicClock)) { SRpcMsg rpcMsg = {0}; int32_t code = syncBuildTimeout(&rpcMsg, SYNC_TIMEOUT_HEARTBEAT, atomic_load_64(&pNode->heartbeatTimerLogicClock), pNode->heartbeatTimerMS, pNode); if (code != 0) { sError("failed to build heartbeat msg"); return; } sTrace("vgId:%d, enqueue heartbeat timer", pNode->vgId); code = pNode->syncEqMsg(pNode->msgcb, &rpcMsg); if (code != 0) { sError("failed to enqueue heartbeat msg since %s", terrstr()); rpcFreeCont(rpcMsg.pCont); return; } taosTmrReset(syncNodeEqHeartbeatTimer, pNode->heartbeatTimerMS, pNode, syncEnv()->pTimerManager, &pNode->pHeartbeatTimer); } else { sTrace("==syncNodeEqHeartbeatTimer== heartbeatTimerLogicClock:%" PRId64 ", heartbeatTimerLogicClockUser:%" PRId64, pNode->heartbeatTimerLogicClock, pNode->heartbeatTimerLogicClockUser); } } } static void syncNodeEqPeerHeartbeatTimer(void* param, void* tmrId) { int64_t hbDataRid = (int64_t)param; int64_t tsNow = taosGetTimestampMs(); SSyncHbTimerData* pData = syncHbTimerDataAcquire(hbDataRid); if (pData == NULL) { sError("hb timer get pData NULL, %" PRId64, hbDataRid); return; } SSyncNode* pSyncNode = syncNodeAcquire(pData->syncNodeRid); if (pSyncNode == NULL) { syncHbTimerDataRelease(pData); sError("hb timer get pSyncNode NULL"); return; } SSyncTimer* pSyncTimer = pData->pTimer; if (!pSyncNode->isStart) { syncNodeRelease(pSyncNode); syncHbTimerDataRelease(pData); sError("vgId:%d, hb timer sync node already stop", pSyncNode->vgId); return; } if (pSyncNode->state != TAOS_SYNC_STATE_LEADER) { syncNodeRelease(pSyncNode); syncHbTimerDataRelease(pData); sError("vgId:%d, hb timer sync node not leader", pSyncNode->vgId); return; } // sTrace("vgId:%d, eq peer hb timer", pSyncNode->vgId); if (pSyncNode->replicaNum > 1) { int64_t timerLogicClock = atomic_load_64(&pSyncTimer->logicClock); int64_t msgLogicClock = atomic_load_64(&pData->logicClock); if (timerLogicClock == msgLogicClock) { if (tsNow > pData->execTime) { pData->execTime += pSyncTimer->timerMS; SRpcMsg rpcMsg = {0}; (void)syncBuildHeartbeat(&rpcMsg, pSyncNode->vgId); pSyncNode->minMatchIndex = syncMinMatchIndex(pSyncNode); SyncHeartbeat* pSyncMsg = rpcMsg.pCont; pSyncMsg->srcId = pSyncNode->myRaftId; pSyncMsg->destId = pData->destId; pSyncMsg->term = raftStoreGetTerm(pSyncNode); pSyncMsg->commitIndex = pSyncNode->commitIndex; pSyncMsg->minMatchIndex = pSyncNode->minMatchIndex; pSyncMsg->privateTerm = 0; pSyncMsg->timeStamp = tsNow; // update reset time int64_t timerElapsed = tsNow - pSyncTimer->timeStamp; pSyncTimer->timeStamp = tsNow; // send msg syncLogSendHeartbeat(pSyncNode, pSyncMsg, false, timerElapsed, pData->execTime); syncNodeSendHeartbeat(pSyncNode, &pSyncMsg->destId, &rpcMsg); } else { } if (syncIsInit()) { // sTrace("vgId:%d, reset peer hb timer", pSyncNode->vgId); taosTmrReset(syncNodeEqPeerHeartbeatTimer, pSyncTimer->timerMS / HEARTBEAT_TICK_NUM, (void*)hbDataRid, syncEnv()->pTimerManager, &pSyncTimer->pTimer); } else { sError("sync env is stop, reset peer hb timer error"); } } else { sTrace("vgId:%d, do not send hb, timerLogicClock:%" PRId64 ", msgLogicClock:%" PRId64 "", pSyncNode->vgId, timerLogicClock, msgLogicClock); } } syncHbTimerDataRelease(pData); syncNodeRelease(pSyncNode); } static void deleteCacheEntry(const void* key, size_t keyLen, void* value) { taosMemoryFree(value); } int32_t syncCacheEntry(SSyncLogStore* pLogStore, SSyncRaftEntry* pEntry, LRUHandle** h) { SSyncLogStoreData* pData = pLogStore->data; sNTrace(pData->pSyncNode, "in cache index:%" PRId64 ", bytes:%u, %p", pEntry->index, pEntry->bytes, pEntry); int32_t code = 0; int32_t entryLen = sizeof(*pEntry) + pEntry->dataLen; LRUStatus status = taosLRUCacheInsert(pLogStore->pCache, &pEntry->index, sizeof(pEntry->index), pEntry, entryLen, deleteCacheEntry, h, TAOS_LRU_PRIORITY_LOW); if (status != TAOS_LRU_STATUS_OK) { code = -1; } return code; } int32_t syncNodeAppend(SSyncNode* ths, SSyncRaftEntry* pEntry) { if (pEntry->dataLen < sizeof(SMsgHead)) { sError("vgId:%d, cannot append an invalid client request with no msg head. type:%s, dataLen:%d", ths->vgId, TMSG_INFO(pEntry->originalRpcType), pEntry->dataLen); syncEntryDestroy(pEntry); return -1; } // append to log buffer if (syncLogBufferAppend(ths->pLogBuf, ths, pEntry) < 0) { sError("vgId:%d, failed to enqueue sync log buffer, index:%" PRId64, ths->vgId, pEntry->index); ASSERT(terrno != 0); (void)syncFsmExecute(ths, ths->pFsm, ths->state, raftStoreGetTerm(ths), pEntry, terrno); syncEntryDestroy(pEntry); return -1; } // proceed match index, with replicating on needed SyncIndex matchIndex = syncLogBufferProceed(ths->pLogBuf, ths, NULL); sTrace("vgId:%d, append raft entry. index:%" PRId64 ", term:%" PRId64 " pBuf: [%" PRId64 " %" PRId64 " %" PRId64 ", %" PRId64 ")", ths->vgId, pEntry->index, pEntry->term, ths->pLogBuf->startIndex, ths->pLogBuf->commitIndex, ths->pLogBuf->matchIndex, ths->pLogBuf->endIndex); // multi replica if (ths->replicaNum > 1) { return 0; } // single replica (void)syncNodeUpdateCommitIndex(ths, matchIndex); if (syncLogBufferCommit(ths->pLogBuf, ths, ths->commitIndex) < 0) { sError("vgId:%d, failed to commit until commitIndex:%" PRId64 "", ths->vgId, ths->commitIndex); return -1; } return 0; } bool syncNodeHeartbeatReplyTimeout(SSyncNode* pSyncNode) { if (pSyncNode->replicaNum == 1) { return false; } int32_t toCount = 0; int64_t tsNow = taosGetTimestampMs(); for (int32_t i = 0; i < pSyncNode->peersNum; ++i) { int64_t recvTime = syncIndexMgrGetRecvTime(pSyncNode->pMatchIndex, &(pSyncNode->peersId[i])); if (recvTime == 0 || recvTime == -1) { continue; } if (tsNow - recvTime > tsHeartbeatTimeout) { toCount++; } } bool b = (toCount >= pSyncNode->quorum ? true : false); return b; } bool syncNodeSnapshotSending(SSyncNode* pSyncNode) { if (pSyncNode == NULL) return false; bool b = false; for (int32_t i = 0; i < pSyncNode->replicaNum; ++i) { if (pSyncNode->senders[i] != NULL && pSyncNode->senders[i]->start) { b = true; break; } } return b; } bool syncNodeSnapshotRecving(SSyncNode* pSyncNode) { if (pSyncNode == NULL) return false; if (pSyncNode->pNewNodeReceiver == NULL) return false; if (pSyncNode->pNewNodeReceiver->start) return true; return false; } static int32_t syncNodeAppendNoop(SSyncNode* ths) { SyncIndex index = syncLogBufferGetEndIndex(ths->pLogBuf); SyncTerm term = raftStoreGetTerm(ths); SSyncRaftEntry* pEntry = syncEntryBuildNoop(term, index, ths->vgId); if (pEntry == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return -1; } int32_t ret = syncNodeAppend(ths, pEntry); return 0; } static int32_t syncNodeAppendNoopOld(SSyncNode* ths) { int32_t ret = 0; SyncIndex index = ths->pLogStore->syncLogWriteIndex(ths->pLogStore); SyncTerm term = raftStoreGetTerm(ths); SSyncRaftEntry* pEntry = syncEntryBuildNoop(term, index, ths->vgId); ASSERT(pEntry != NULL); LRUHandle* h = NULL; if (ths->state == TAOS_SYNC_STATE_LEADER) { int32_t code = ths->pLogStore->syncLogAppendEntry(ths->pLogStore, pEntry, false); if (code != 0) { sError("append noop error"); return -1; } syncCacheEntry(ths->pLogStore, pEntry, &h); } if (h) { taosLRUCacheRelease(ths->pLogStore->pCache, h, false); } else { syncEntryDestroy(pEntry); } return ret; } int32_t syncNodeOnHeartbeat(SSyncNode* ths, const SRpcMsg* pRpcMsg) { SyncHeartbeat* pMsg = pRpcMsg->pCont; bool resetElect = false; const STraceId* trace = &pRpcMsg->info.traceId; char tbuf[40] = {0}; TRACE_TO_STR(trace, tbuf); int64_t tsMs = taosGetTimestampMs(); int64_t timeDiff = tsMs - pMsg->timeStamp; syncLogRecvHeartbeat(ths, pMsg, timeDiff, tbuf); SRpcMsg rpcMsg = {0}; (void)syncBuildHeartbeatReply(&rpcMsg, ths->vgId); SyncTerm currentTerm = raftStoreGetTerm(ths); SyncHeartbeatReply* pMsgReply = rpcMsg.pCont; pMsgReply->destId = pMsg->srcId; pMsgReply->srcId = ths->myRaftId; pMsgReply->term = currentTerm; pMsgReply->privateTerm = 8864; // magic number pMsgReply->startTime = ths->startTime; pMsgReply->timeStamp = tsMs; if (pMsg->term == currentTerm && ths->state != TAOS_SYNC_STATE_LEADER) { syncIndexMgrSetRecvTime(ths->pNextIndex, &(pMsg->srcId), tsMs); resetElect = true; ths->minMatchIndex = pMsg->minMatchIndex; if (ths->state == TAOS_SYNC_STATE_FOLLOWER) { SRpcMsg rpcMsgLocalCmd = {0}; (void)syncBuildLocalCmd(&rpcMsgLocalCmd, ths->vgId); SyncLocalCmd* pSyncMsg = rpcMsgLocalCmd.pCont; pSyncMsg->cmd = SYNC_LOCAL_CMD_FOLLOWER_CMT; pSyncMsg->commitIndex = pMsg->commitIndex; pSyncMsg->currentTerm = pMsg->term; SyncIndex fcIndex = pSyncMsg->commitIndex; if (ths->syncEqMsg != NULL && ths->msgcb != NULL) { int32_t code = ths->syncEqMsg(ths->msgcb, &rpcMsgLocalCmd); if (code != 0) { sError("vgId:%d, sync enqueue fc-commit msg error, code:%d", ths->vgId, code); rpcFreeCont(rpcMsgLocalCmd.pCont); } else { sTrace("vgId:%d, sync enqueue fc-commit msg, fc-index:%" PRId64, ths->vgId, fcIndex); } } } } if (pMsg->term >= currentTerm && ths->state != TAOS_SYNC_STATE_FOLLOWER) { SRpcMsg rpcMsgLocalCmd = {0}; (void)syncBuildLocalCmd(&rpcMsgLocalCmd, ths->vgId); SyncLocalCmd* pSyncMsg = rpcMsgLocalCmd.pCont; pSyncMsg->cmd = SYNC_LOCAL_CMD_STEP_DOWN; pSyncMsg->currentTerm = pMsg->term; pSyncMsg->commitIndex = pMsg->commitIndex; if (ths->syncEqMsg != NULL && ths->msgcb != NULL) { int32_t code = ths->syncEqMsg(ths->msgcb, &rpcMsgLocalCmd); if (code != 0) { sError("vgId:%d, sync enqueue step-down msg error, code:%d", ths->vgId, code); rpcFreeCont(rpcMsgLocalCmd.pCont); } else { sTrace("vgId:%d, sync enqueue step-down msg, new-term:%" PRId64, ths->vgId, pSyncMsg->currentTerm); } } } // reply syncNodeSendMsgById(&pMsgReply->destId, ths, &rpcMsg); if (resetElect) syncNodeResetElectTimer(ths); return 0; } int32_t syncNodeOnHeartbeatReply(SSyncNode* ths, const SRpcMsg* pRpcMsg) { const STraceId* trace = &pRpcMsg->info.traceId; char tbuf[40] = {0}; TRACE_TO_STR(trace, tbuf); SyncHeartbeatReply* pMsg = pRpcMsg->pCont; SSyncLogReplMgr* pMgr = syncNodeGetLogReplMgr(ths, &pMsg->srcId); if (pMgr == NULL) { sError("vgId:%d, failed to get log repl mgr for the peer at addr 0x016%" PRIx64 "", ths->vgId, pMsg->srcId.addr); return -1; } int64_t tsMs = taosGetTimestampMs(); syncLogRecvHeartbeatReply(ths, pMsg, tsMs - pMsg->timeStamp, tbuf); syncIndexMgrSetRecvTime(ths->pMatchIndex, &pMsg->srcId, tsMs); return syncLogReplProcessHeartbeatReply(pMgr, ths, pMsg); } int32_t syncNodeOnHeartbeatReplyOld(SSyncNode* ths, const SRpcMsg* pRpcMsg) { SyncHeartbeatReply* pMsg = pRpcMsg->pCont; const STraceId* trace = &pRpcMsg->info.traceId; char tbuf[40] = {0}; TRACE_TO_STR(trace, tbuf); int64_t tsMs = taosGetTimestampMs(); int64_t timeDiff = tsMs - pMsg->timeStamp; syncLogRecvHeartbeatReply(ths, pMsg, timeDiff, tbuf); // update last reply time, make decision whether the other node is alive or not syncIndexMgrSetRecvTime(ths->pMatchIndex, &pMsg->srcId, tsMs); return 0; } int32_t syncNodeOnLocalCmd(SSyncNode* ths, const SRpcMsg* pRpcMsg) { SyncLocalCmd* pMsg = pRpcMsg->pCont; syncLogRecvLocalCmd(ths, pMsg, ""); if (pMsg->cmd == SYNC_LOCAL_CMD_STEP_DOWN) { syncNodeStepDown(ths, pMsg->currentTerm); } else if (pMsg->cmd == SYNC_LOCAL_CMD_FOLLOWER_CMT) { if (syncLogBufferIsEmpty(ths->pLogBuf)) { sError("vgId:%d, sync log buffer is empty.", ths->vgId); return 0; } SyncTerm matchTerm = syncLogBufferGetLastMatchTerm(ths->pLogBuf); if (pMsg->currentTerm == matchTerm) { (void)syncNodeUpdateCommitIndex(ths, pMsg->commitIndex); } if (syncLogBufferCommit(ths->pLogBuf, ths, ths->commitIndex) < 0) { sError("vgId:%d, failed to commit raft log since %s. commit index:%" PRId64 "", ths->vgId, terrstr(), ths->commitIndex); } } else { sError("error local cmd"); } return 0; } // TLA+ Spec // ClientRequest(i, v) == // /\ state[i] = Leader // /\ LET entry == [term |-> currentTerm[i], // value |-> v] // newLog == Append(log[i], entry) // IN log' = [log EXCEPT ![i] = newLog] // /\ UNCHANGED <> // int32_t syncNodeOnClientRequest(SSyncNode* ths, SRpcMsg* pMsg, SyncIndex* pRetIndex) { sNTrace(ths, "on client request"); int32_t code = 0; SyncIndex index = syncLogBufferGetEndIndex(ths->pLogBuf); SyncTerm term = raftStoreGetTerm(ths); SSyncRaftEntry* pEntry = NULL; if (pMsg->msgType == TDMT_SYNC_CLIENT_REQUEST) { pEntry = syncEntryBuildFromClientRequest(pMsg->pCont, term, index); } else { pEntry = syncEntryBuildFromRpcMsg(pMsg, term, index); } if (pEntry == NULL) { sError("vgId:%d, failed to process client request since %s.", ths->vgId, terrstr()); return -1; } if (ths->state == TAOS_SYNC_STATE_LEADER) { if (pRetIndex) { (*pRetIndex) = index; } int32_t code = syncNodeAppend(ths, pEntry); return code; } else { syncEntryDestroy(pEntry); pEntry = NULL; return -1; } } const char* syncStr(ESyncState state) { switch (state) { case TAOS_SYNC_STATE_FOLLOWER: return "follower"; case TAOS_SYNC_STATE_CANDIDATE: return "candidate"; case TAOS_SYNC_STATE_LEADER: return "leader"; case TAOS_SYNC_STATE_ERROR: return "error"; case TAOS_SYNC_STATE_OFFLINE: return "offline"; default: return "unknown"; } } int32_t syncNodeUpdateNewConfigIndex(SSyncNode* ths, SSyncCfg* pNewCfg) { for (int32_t i = 0; i < pNewCfg->replicaNum; ++i) { SRaftId raftId = { .addr = SYNC_ADDR(&pNewCfg->nodeInfo[i]), .vgId = ths->vgId, }; if (syncUtilSameId(&(ths->myRaftId), &raftId)) { pNewCfg->myIndex = i; return 0; } } return -1; } bool syncNodeIsOptimizedOneReplica(SSyncNode* ths, SRpcMsg* pMsg) { return (ths->replicaNum == 1 && syncUtilUserCommit(pMsg->msgType) && ths->vgId != 1); } bool syncNodeInRaftGroup(SSyncNode* ths, SRaftId* pRaftId) { for (int32_t i = 0; i < ths->replicaNum; ++i) { if (syncUtilSameId(&((ths->replicasId)[i]), pRaftId)) { return true; } } return false; } SSyncSnapshotSender* syncNodeGetSnapshotSender(SSyncNode* ths, SRaftId* pDestId) { SSyncSnapshotSender* pSender = NULL; for (int32_t i = 0; i < ths->replicaNum; ++i) { if (syncUtilSameId(pDestId, &((ths->replicasId)[i]))) { pSender = (ths->senders)[i]; } } return pSender; } SSyncTimer* syncNodeGetHbTimer(SSyncNode* ths, SRaftId* pDestId) { SSyncTimer* pTimer = NULL; for (int32_t i = 0; i < ths->replicaNum; ++i) { if (syncUtilSameId(pDestId, &((ths->replicasId)[i]))) { pTimer = &((ths->peerHeartbeatTimerArr)[i]); } } return pTimer; } SPeerState* syncNodeGetPeerState(SSyncNode* ths, const SRaftId* pDestId) { SPeerState* pState = NULL; for (int32_t i = 0; i < ths->replicaNum; ++i) { if (syncUtilSameId(pDestId, &((ths->replicasId)[i]))) { pState = &((ths->peerStates)[i]); } } return pState; } bool syncNodeNeedSendAppendEntries(SSyncNode* ths, const SRaftId* pDestId, const SyncAppendEntries* pMsg) { SPeerState* pState = syncNodeGetPeerState(ths, pDestId); if (pState == NULL) { sError("vgId:%d, replica maybe dropped", ths->vgId); return false; } SyncIndex sendIndex = pMsg->prevLogIndex + 1; int64_t tsNow = taosGetTimestampMs(); if (pState->lastSendIndex == sendIndex && tsNow - pState->lastSendTime < SYNC_APPEND_ENTRIES_TIMEOUT_MS) { return false; } return true; } bool syncNodeCanChange(SSyncNode* pSyncNode) { if (pSyncNode->changing) { sError("sync cannot change"); return false; } if ((pSyncNode->commitIndex >= SYNC_INDEX_BEGIN)) { SyncIndex lastIndex = syncNodeGetLastIndex(pSyncNode); if (pSyncNode->commitIndex != lastIndex) { sError("sync cannot change2"); return false; } } for (int32_t i = 0; i < pSyncNode->peersNum; ++i) { SSyncSnapshotSender* pSender = syncNodeGetSnapshotSender(pSyncNode, &(pSyncNode->peersId)[i]); if (pSender != NULL && pSender->start) { sError("sync cannot change3"); return false; } } return true; }