/* * 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 "syncTimeout.h" #include "syncElection.h" #include "syncRaftCfg.h" #include "syncRaftLog.h" #include "syncReplication.h" #include "syncRespMgr.h" #include "syncUtil.h" static void syncNodeCleanConfigIndex(SSyncNode* ths) { int32_t newArrIndex = 0; SyncIndex newConfigIndexArr[MAX_CONFIG_INDEX_COUNT] = {0}; SSnapshot snapshot = {0}; ths->pFsm->FpGetSnapshotInfo(ths->pFsm, &snapshot); if (snapshot.lastApplyIndex != SYNC_INDEX_INVALID) { for (int32_t i = 0; i < ths->pRaftCfg->configIndexCount; ++i) { if (ths->pRaftCfg->configIndexArr[i] < snapshot.lastConfigIndex) { // pass } else { // save newConfigIndexArr[newArrIndex] = ths->pRaftCfg->configIndexArr[i]; ++newArrIndex; } } int32_t oldCnt = ths->pRaftCfg->configIndexCount; ths->pRaftCfg->configIndexCount = newArrIndex; memcpy(ths->pRaftCfg->configIndexArr, newConfigIndexArr, sizeof(newConfigIndexArr)); int32_t code = raftCfgPersist(ths->pRaftCfg); if (code != 0) { sNFatal(ths, "failed to persist cfg"); } else { sNTrace(ths, "clean config index arr, old-cnt:%d, new-cnt:%d", oldCnt, ths->pRaftCfg->configIndexCount); } } } static int32_t syncNodeTimerRoutine(SSyncNode* ths) { ths->tmrRoutineNum++; if (ths->tmrRoutineNum % 60 == 0 && ths->replicaNum > 1) { sNInfo(ths, "timer routines"); } else { sNTrace(ths, "timer routines"); } // timer replicate syncNodeReplicate(ths); // clean mnode index if (syncNodeIsMnode(ths)) { syncNodeCleanConfigIndex(ths); } int64_t timeNow = taosGetTimestampMs(); if (atomic_load_64(&ths->snapshottingIndex) != SYNC_INDEX_INVALID) { // end timeout wal snapshot if (timeNow - ths->snapshottingTime > SYNC_DEL_WAL_MS && atomic_load_64(&ths->snapshottingIndex) != SYNC_INDEX_INVALID) { SSyncLogStoreData* pData = ths->pLogStore->data; int32_t code = walEndSnapshot(pData->pWal); if (code != 0) { sNError(ths, "timer wal snapshot end error since:%s", terrstr()); return -1; } else { sNTrace(ths, "wal snapshot end, index:%" PRId64, atomic_load_64(&ths->snapshottingIndex)); atomic_store_64(&ths->snapshottingIndex, SYNC_INDEX_INVALID); } } } if (!syncNodeIsMnode(ths)) { syncRespClean(ths->pSyncRespMgr); } return 0; } int32_t syncNodeOnTimeout(SSyncNode* ths, const SRpcMsg* pRpc) { int32_t ret = 0; SyncTimeout* pMsg = pRpc->pCont; syncLogRecvTimer(ths, pMsg, ""); if (pMsg->timeoutType == SYNC_TIMEOUT_PING) { if (atomic_load_64(&ths->pingTimerLogicClockUser) <= pMsg->logicClock) { ++(ths->pingTimerCounter); // syncNodePingAll(ths); // syncNodePingPeers(ths); syncNodeTimerRoutine(ths); } } else if (pMsg->timeoutType == SYNC_TIMEOUT_ELECTION) { if (atomic_load_64(&ths->electTimerLogicClock) <= pMsg->logicClock) { ++(ths->electTimerCounter); syncNodeElect(ths); } } else if (pMsg->timeoutType == SYNC_TIMEOUT_HEARTBEAT) { if (atomic_load_64(&ths->heartbeatTimerLogicClockUser) <= pMsg->logicClock) { ++(ths->heartbeatTimerCounter); sTrace("vgId:%d, sync timer, type:replicate count:%" PRIu64 ", lc-user:%" PRIu64, ths->vgId, ths->heartbeatTimerCounter, ths->heartbeatTimerLogicClockUser); // syncNodeReplicate(ths, true); } } else { sError("vgId:%d, recv unknown timer-type:%d", ths->vgId, pMsg->timeoutType); } return ret; }