/* * 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 "mndSubscribe.h" #include "mndConsumer.h" #include "mndDb.h" #include "mndDnode.h" #include "mndMnode.h" #include "mndOffset.h" #include "mndScheduler.h" #include "mndShow.h" #include "mndStb.h" #include "mndTopic.h" #include "mndTrans.h" #include "mndUser.h" #include "mndVgroup.h" #include "tcompare.h" #include "tname.h" #define MND_SUBSCRIBE_VER_NUMBER 1 #define MND_SUBSCRIBE_RESERVE_SIZE 64 #define MND_SUBSCRIBE_REBALANCE_CNT 3 static SSdbRaw *mndSubActionEncode(SMqSubscribeObj *); static SSdbRow *mndSubActionDecode(SSdbRaw *pRaw); static int32_t mndSubActionInsert(SSdb *pSdb, SMqSubscribeObj *); static int32_t mndSubActionDelete(SSdb *pSdb, SMqSubscribeObj *); static int32_t mndSubActionUpdate(SSdb *pSdb, SMqSubscribeObj *pOldSub, SMqSubscribeObj *pNewSub); static int32_t mndProcessRebalanceReq(SNodeMsg *pMsg); static int32_t mndProcessSubscribeInternalRsp(SNodeMsg *pMsg); static int32_t mndSetSubRedoLogs(SMnode *pMnode, STrans *pTrans, SMqSubscribeObj *pSub) { SSdbRaw *pRedoRaw = mndSubActionEncode(pSub); if (pRedoRaw == NULL) return -1; if (mndTransAppendRedolog(pTrans, pRedoRaw) != 0) return -1; if (sdbSetRawStatus(pRedoRaw, SDB_STATUS_READY) != 0) return -1; return 0; } static int32_t mndSetSubCommitLogs(SMnode *pMnode, STrans *pTrans, SMqSubscribeObj *pSub) { SSdbRaw *pCommitRaw = mndSubActionEncode(pSub); if (pCommitRaw == NULL) return -1; if (mndTransAppendCommitlog(pTrans, pCommitRaw) != 0) return -1; if (sdbSetRawStatus(pCommitRaw, SDB_STATUS_READY) != 0) return -1; return 0; } int32_t mndInitSubscribe(SMnode *pMnode) { SSdbTable table = {.sdbType = SDB_SUBSCRIBE, .keyType = SDB_KEY_BINARY, .encodeFp = (SdbEncodeFp)mndSubActionEncode, .decodeFp = (SdbDecodeFp)mndSubActionDecode, .insertFp = (SdbInsertFp)mndSubActionInsert, .updateFp = (SdbUpdateFp)mndSubActionUpdate, .deleteFp = (SdbDeleteFp)mndSubActionDelete}; mndSetMsgHandle(pMnode, TDMT_VND_MQ_VG_CHANGE_RSP, mndProcessSubscribeInternalRsp); mndSetMsgHandle(pMnode, TDMT_MND_MQ_DO_REBALANCE, mndProcessRebalanceReq); return sdbSetTable(pMnode->pSdb, table); } static SMqSubscribeObj *mndCreateSub(SMnode *pMnode, const SMqTopicObj *pTopic, const char *subKey) { SMqSubscribeObj *pSub = tNewSubscribeObj(subKey); if (pSub == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } pSub->dbUid = pTopic->dbUid; pSub->subType = pTopic->subType; pSub->withTbName = pTopic->withTbName; pSub->withSchema = pTopic->withSchema; pSub->withTag = pTopic->withTag; ASSERT(pSub->unassignedVgs->size == 0); ASSERT(taosHashGetSize(pSub->consumerHash) == 0); if (mndSchedInitSubEp(pMnode, pTopic, pSub) < 0) { tDeleteSubscribeObj(pSub); taosMemoryFree(pSub); return NULL; } ASSERT(pSub->unassignedVgs->size > 0); ASSERT(taosHashGetSize(pSub->consumerHash) == 0); return pSub; } static int32_t mndBuildSubChangeReq(void **pBuf, int32_t *pLen, const SMqSubscribeObj *pSub, const SMqRebOutputVg *pRebVg) { SMqRebVgReq req = {0}; req.oldConsumerId = pRebVg->oldConsumerId; req.newConsumerId = pRebVg->newConsumerId; req.vgId = pRebVg->pVgEp->vgId; req.qmsg = pRebVg->pVgEp->qmsg; req.subType = pSub->subType; req.withTbName = pSub->withTbName; req.withSchema = pSub->withSchema; req.withTag = pSub->withTag; strncpy(req.subKey, pSub->key, TSDB_SUBSCRIBE_KEY_LEN); int32_t tlen = sizeof(SMsgHead) + tEncodeSMqRebVgReq(NULL, &req); void *buf = taosMemoryMalloc(tlen); if (buf == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return -1; } SMsgHead *pMsgHead = (SMsgHead *)buf; pMsgHead->contLen = htonl(tlen); pMsgHead->vgId = htonl(pRebVg->pVgEp->vgId); void *abuf = POINTER_SHIFT(buf, sizeof(SMsgHead)); tEncodeSMqRebVgReq(&abuf, &req); *pBuf = buf; *pLen = tlen; return 0; } static int32_t mndPersistSubChangeVgReq(SMnode *pMnode, STrans *pTrans, const SMqSubscribeObj *pSub, const SMqRebOutputVg *pRebVg) { ASSERT(pRebVg->oldConsumerId != pRebVg->newConsumerId); void *buf; int32_t tlen; if (mndBuildSubChangeReq(&buf, &tlen, pSub, pRebVg) < 0) { return -1; } int32_t vgId = pRebVg->pVgEp->vgId; SVgObj *pVgObj = mndAcquireVgroup(pMnode, vgId); if (pVgObj == NULL) { taosMemoryFree(buf); return -1; } STransAction action = {0}; action.epSet = mndGetVgroupEpset(pMnode, pVgObj); action.pCont = buf; action.contLen = tlen; action.msgType = TDMT_VND_MQ_VG_CHANGE; mndReleaseVgroup(pMnode, pVgObj); if (mndTransAppendRedoAction(pTrans, &action) != 0) { taosMemoryFree(buf); return -1; } return 0; } static int32_t mndSplitSubscribeKey(const char *key, char *topic, char *cgroup) { int32_t i = 0; while (key[i] != TMQ_SEPARATOR) { i++; } memcpy(cgroup, key, i); cgroup[i] = 0; strcpy(topic, &key[i + 1]); return 0; } static SMqRebInfo *mndGetOrCreateRebSub(SHashObj *pHash, const char *key) { SMqRebInfo *pRebSub = taosHashGet(pHash, key, strlen(key) + 1); if (pRebSub == NULL) { pRebSub = tNewSMqRebSubscribe(key); if (pRebSub == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } taosHashPut(pHash, key, strlen(key) + 1, pRebSub, sizeof(SMqRebInfo)); } return pRebSub; } static int32_t mndDoRebalance(SMnode *pMnode, const SMqRebInputObj *pInput, SMqRebOutputObj *pOutput) { int32_t totalVgNum = pOutput->pSub->vgNum; mInfo("mq rebalance subscription: %s, vgNum: %d", pOutput->pSub->key, pOutput->pSub->vgNum); // 1. build temporary hash(vgId -> SMqRebOutputVg) to store modified vg SHashObj *pHash = taosHashInit(64, taosGetDefaultHashFunction(TSDB_DATA_TYPE_INT), false, HASH_NO_LOCK); // 2. check and get actual removed consumers, put their vg into hash int32_t removedNum = taosArrayGetSize(pInput->pRebInfo->removedConsumers); int32_t actualRemoved = 0; for (int32_t i = 0; i < removedNum; i++) { int64_t consumerId = *(int64_t *)taosArrayGet(pInput->pRebInfo->removedConsumers, i); ASSERT(consumerId > 0); SMqConsumerEp *pConsumerEp = taosHashGet(pOutput->pSub->consumerHash, &consumerId, sizeof(int64_t)); ASSERT(pConsumerEp); if (pConsumerEp) { ASSERT(consumerId == pConsumerEp->consumerId); actualRemoved++; int32_t consumerVgNum = taosArrayGetSize(pConsumerEp->vgs); for (int32_t j = 0; j < consumerVgNum; j++) { SMqVgEp *pVgEp = taosArrayGetP(pConsumerEp->vgs, j); SMqRebOutputVg outputVg = { .oldConsumerId = consumerId, .newConsumerId = -1, .pVgEp = pVgEp, }; taosHashPut(pHash, &pVgEp->vgId, sizeof(int32_t), &outputVg, sizeof(SMqRebOutputVg)); } taosHashRemove(pOutput->pSub->consumerHash, &consumerId, sizeof(int64_t)); // put into removed taosArrayPush(pOutput->removedConsumers, &consumerId); } } ASSERT(removedNum == actualRemoved); // if previously no consumer, there are vgs not assigned { int32_t consumerVgNum = taosArrayGetSize(pOutput->pSub->unassignedVgs); for (int32_t i = 0; i < consumerVgNum; i++) { SMqVgEp *pVgEp = *(SMqVgEp **)taosArrayPop(pOutput->pSub->unassignedVgs); SMqRebOutputVg rebOutput = { .oldConsumerId = -1, .newConsumerId = -1, .pVgEp = pVgEp, }; taosHashPut(pHash, &pVgEp->vgId, sizeof(int32_t), &rebOutput, sizeof(SMqRebOutputVg)); } } // 3. calc vg number of each consumer int32_t afterRebConsumerNum = pInput->oldConsumerNum + taosArrayGetSize(pInput->pRebInfo->newConsumers) - taosArrayGetSize(pInput->pRebInfo->removedConsumers); int32_t minVgCnt = 0; int32_t imbConsumerNum = 0; // calc num if (afterRebConsumerNum) { minVgCnt = totalVgNum / afterRebConsumerNum; imbConsumerNum = totalVgNum % afterRebConsumerNum; } // 4. first scan: remove consumer more than wanted, put to remove hash int32_t imbCnt = 0; void *pIter = NULL; while (1) { pIter = taosHashIterate(pOutput->pSub->consumerHash, pIter); if (pIter == NULL) break; SMqConsumerEp *pConsumerEp = (SMqConsumerEp *)pIter; ASSERT(pConsumerEp->consumerId > 0); int32_t consumerVgNum = taosArrayGetSize(pConsumerEp->vgs); // all old consumers still existing are touched // TODO optimize: touch only consumer whose vgs changed taosArrayPush(pOutput->touchedConsumers, &pConsumerEp->consumerId); if (consumerVgNum > minVgCnt) { if (imbCnt < imbConsumerNum) { if (consumerVgNum == minVgCnt + 1) { continue; } else { // pop until equal minVg + 1 while (taosArrayGetSize(pConsumerEp->vgs) > minVgCnt + 1) { SMqVgEp *pVgEp = *(SMqVgEp **)taosArrayPop(pConsumerEp->vgs); SMqRebOutputVg outputVg = { .oldConsumerId = pConsumerEp->consumerId, .newConsumerId = -1, .pVgEp = pVgEp, }; taosHashPut(pHash, &pVgEp->vgId, sizeof(int32_t), &outputVg, sizeof(SMqRebOutputVg)); } imbCnt++; } } else { // pop until equal minVg while (taosArrayGetSize(pConsumerEp->vgs) > minVgCnt) { SMqVgEp *pVgEp = *(SMqVgEp **)taosArrayPop(pConsumerEp->vgs); SMqRebOutputVg outputVg = { .oldConsumerId = pConsumerEp->consumerId, .newConsumerId = -1, .pVgEp = pVgEp, }; taosHashPut(pHash, &pVgEp->vgId, sizeof(int32_t), &outputVg, sizeof(SMqRebOutputVg)); } } } } // 5. add new consumer into sub { int32_t consumerNum = taosArrayGetSize(pInput->pRebInfo->newConsumers); for (int32_t i = 0; i < consumerNum; i++) { int64_t consumerId = *(int64_t *)taosArrayGet(pInput->pRebInfo->newConsumers, i); ASSERT(consumerId > 0); SMqConsumerEp newConsumerEp; newConsumerEp.consumerId = consumerId; newConsumerEp.vgs = taosArrayInit(0, sizeof(void *)); taosHashPut(pOutput->pSub->consumerHash, &consumerId, sizeof(int64_t), &newConsumerEp, sizeof(SMqConsumerEp)); taosArrayPush(pOutput->newConsumers, &consumerId); } } // 6. second scan: find consumer do not have enough vg, extract from temporary hash and assign to new consumer. // All related vg should be put into rebVgs SMqRebOutputVg *pRebVg = NULL; void *pRemovedIter = NULL; pIter = NULL; while (1) { pIter = taosHashIterate(pOutput->pSub->consumerHash, pIter); if (pIter == NULL) break; SMqConsumerEp *pConsumerEp = (SMqConsumerEp *)pIter; ASSERT(pConsumerEp->consumerId > 0); // push until equal minVg while (taosArrayGetSize(pConsumerEp->vgs) < minVgCnt) { // iter hash and find one vg pRemovedIter = taosHashIterate(pHash, pRemovedIter); ASSERT(pRemovedIter); pRebVg = (SMqRebOutputVg *)pRemovedIter; // push taosArrayPush(pConsumerEp->vgs, &pRebVg->pVgEp); pRebVg->newConsumerId = pConsumerEp->consumerId; taosArrayPush(pOutput->rebVgs, pRebVg); } } // 7. handle unassigned vg if (taosHashGetSize(pOutput->pSub->consumerHash) != 0) { // if has consumer, assign all left vg while (1) { pRemovedIter = taosHashIterate(pHash, pRemovedIter); if (pRemovedIter == NULL) break; pIter = taosHashIterate(pOutput->pSub->consumerHash, pIter); ASSERT(pIter); pRebVg = (SMqRebOutputVg *)pRemovedIter; SMqConsumerEp *pConsumerEp = (SMqConsumerEp *)pIter; ASSERT(pConsumerEp->consumerId > 0); taosArrayPush(pConsumerEp->vgs, &pRebVg->pVgEp); pRebVg->newConsumerId = pConsumerEp->consumerId; taosArrayPush(pOutput->rebVgs, pRebVg); } } else { // if all consumer is removed, put all vg into unassigned pIter = NULL; SMqRebOutputVg *pRebOutput = NULL; while (1) { pIter = taosHashIterate(pHash, pIter); if (pIter == NULL) break; pRebOutput = (SMqRebOutputVg *)pIter; ASSERT(pRebOutput->newConsumerId == -1); taosArrayPush(pOutput->pSub->unassignedVgs, &pRebOutput->pVgEp); taosArrayPush(pOutput->rebVgs, pRebOutput); } } // 8. TODO generate logs mInfo("rebalance calculation completed, rebalanced vg:"); for (int32_t i = 0; i < taosArrayGetSize(pOutput->rebVgs); i++) { SMqRebOutputVg *pOutputRebVg = taosArrayGet(pOutput->rebVgs, i); mInfo("vg: %d moved from consumer %ld to consumer %ld", pOutputRebVg->pVgEp->vgId, pOutputRebVg->oldConsumerId, pOutputRebVg->newConsumerId); } // 9. clear taosHashCleanup(pHash); return 0; } static int32_t mndPersistRebResult(SMnode *pMnode, SNodeMsg *pMsg, const SMqRebOutputObj *pOutput) { STrans *pTrans = mndTransCreate(pMnode, TRN_POLICY_RETRY, TRN_TYPE_REBALANCE, &pMsg->rpcMsg); if (pTrans == NULL) { return -1; } // make txn: // 1. redo action: action to all vg const SArray *rebVgs = pOutput->rebVgs; int32_t vgNum = taosArrayGetSize(rebVgs); for (int32_t i = 0; i < vgNum; i++) { SMqRebOutputVg *pRebVg = taosArrayGet(rebVgs, i); if (mndPersistSubChangeVgReq(pMnode, pTrans, pOutput->pSub, pRebVg) < 0) { goto REB_FAIL; } } // 2. redo log: subscribe and vg assignment // subscribe if (mndSetSubRedoLogs(pMnode, pTrans, pOutput->pSub) != 0) { goto REB_FAIL; } // 3. commit log: consumer to update status and epoch // 3.1 set touched consumer int32_t consumerNum = taosArrayGetSize(pOutput->touchedConsumers); for (int32_t i = 0; i < consumerNum; i++) { int64_t consumerId = *(int64_t *)taosArrayGet(pOutput->touchedConsumers, i); SMqConsumerObj *pConsumerOld = mndAcquireConsumer(pMnode, consumerId); SMqConsumerObj *pConsumerNew = tNewSMqConsumerObj(pConsumerOld->consumerId, pConsumerOld->cgroup); pConsumerNew->updateType = CONSUMER_UPDATE__TOUCH; mndReleaseConsumer(pMnode, pConsumerOld); if (mndSetConsumerCommitLogs(pMnode, pTrans, pConsumerNew) != 0) { goto REB_FAIL; } } // 3.2 set new consumer consumerNum = taosArrayGetSize(pOutput->newConsumers); for (int32_t i = 0; i < consumerNum; i++) { int64_t consumerId = *(int64_t *)taosArrayGet(pOutput->newConsumers, i); ASSERT(consumerId > 0); SMqConsumerObj *pConsumerOld = mndAcquireConsumer(pMnode, consumerId); SMqConsumerObj *pConsumerNew = tNewSMqConsumerObj(pConsumerOld->consumerId, pConsumerOld->cgroup); pConsumerNew->updateType = CONSUMER_UPDATE__ADD; char *topic = taosMemoryCalloc(1, TSDB_TOPIC_FNAME_LEN); char cgroup[TSDB_CGROUP_LEN]; mndSplitSubscribeKey(pOutput->pSub->key, topic, cgroup); taosArrayPush(pConsumerNew->rebNewTopics, &topic); mndReleaseConsumer(pMnode, pConsumerOld); if (mndSetConsumerCommitLogs(pMnode, pTrans, pConsumerNew) != 0) { goto REB_FAIL; } } // 3.3 set removed consumer consumerNum = taosArrayGetSize(pOutput->removedConsumers); for (int32_t i = 0; i < consumerNum; i++) { int64_t consumerId = *(int64_t *)taosArrayGet(pOutput->removedConsumers, i); ASSERT(consumerId > 0); SMqConsumerObj *pConsumerOld = mndAcquireConsumer(pMnode, consumerId); SMqConsumerObj *pConsumerNew = tNewSMqConsumerObj(pConsumerOld->consumerId, pConsumerOld->cgroup); pConsumerNew->updateType = CONSUMER_UPDATE__REMOVE; char *topic = taosMemoryCalloc(1, TSDB_TOPIC_FNAME_LEN); char cgroup[TSDB_CGROUP_LEN]; mndSplitSubscribeKey(pOutput->pSub->key, topic, cgroup); taosArrayPush(pConsumerNew->rebRemovedTopics, &topic); mndReleaseConsumer(pMnode, pConsumerOld); if (mndSetConsumerCommitLogs(pMnode, pTrans, pConsumerNew) != 0) { goto REB_FAIL; } } // 4. TODO commit log: modification log // 5. set cb mndTransSetCb(pTrans, MQ_REB_TRANS_START_FUNC, MQ_REB_TRANS_STOP_FUNC, NULL, 0); // 6. execution if (mndTransPrepare(pMnode, pTrans) != 0) goto REB_FAIL; mndTransDrop(pTrans); return 0; REB_FAIL: mndTransDrop(pTrans); return -1; } static int32_t mndProcessRebalanceReq(SNodeMsg *pMsg) { SMnode *pMnode = pMsg->pNode; SMqDoRebalanceMsg *pReq = pMsg->rpcMsg.pCont; void *pIter = NULL; mInfo("mq rebalance start"); while (1) { pIter = taosHashIterate(pReq->rebSubHash, pIter); if (pIter == NULL) break; SMqRebInputObj rebInput = {0}; SMqRebOutputObj rebOutput = {0}; rebOutput.newConsumers = taosArrayInit(0, sizeof(void *)); rebOutput.removedConsumers = taosArrayInit(0, sizeof(void *)); rebOutput.touchedConsumers = taosArrayInit(0, sizeof(void *)); rebOutput.rebVgs = taosArrayInit(0, sizeof(SMqRebOutputVg)); SMqRebInfo *pRebInfo = (SMqRebInfo *)pIter; SMqSubscribeObj *pSub = mndAcquireSubscribeByKey(pMnode, pRebInfo->key); rebInput.pRebInfo = pRebInfo; if (pSub == NULL) { // split sub key and extract topic char topic[TSDB_TOPIC_FNAME_LEN]; char cgroup[TSDB_CGROUP_LEN]; mndSplitSubscribeKey(pRebInfo->key, topic, cgroup); SMqTopicObj *pTopic = mndAcquireTopic(pMnode, topic); ASSERT(pTopic); taosRLockLatch(&pTopic->lock); rebOutput.pSub = mndCreateSub(pMnode, pTopic, pRebInfo->key); ASSERT(taosHashGetSize(rebOutput.pSub->consumerHash) == 0); taosRUnLockLatch(&pTopic->lock); mndReleaseTopic(pMnode, pTopic); rebInput.oldConsumerNum = 0; } else { taosRLockLatch(&pSub->lock); rebInput.oldConsumerNum = taosHashGetSize(pSub->consumerHash); rebOutput.pSub = tCloneSubscribeObj(pSub); taosRUnLockLatch(&pSub->lock); mndReleaseSubscribe(pMnode, pSub); } // TODO replace assert with error check ASSERT(mndDoRebalance(pMnode, &rebInput, &rebOutput) == 0); // if add more consumer to balanced subscribe, // possibly no vg is changed /*ASSERT(taosArrayGetSize(rebOutput.rebVgs) != 0);*/ // TODO replace assert with error check if (mndPersistRebResult(pMnode, pMsg, &rebOutput) < 0) { mError("persist rebalance output error, possibly vnode splitted or dropped"); } } // reset flag mInfo("mq rebalance completed successfully"); taosHashCleanup(pReq->rebSubHash); mndRebEnd(); return 0; } void mndCleanupSubscribe(SMnode *pMnode) {} static SSdbRaw *mndSubActionEncode(SMqSubscribeObj *pSub) { terrno = TSDB_CODE_OUT_OF_MEMORY; void *buf = NULL; int32_t tlen = tEncodeSubscribeObj(NULL, pSub); int32_t size = sizeof(int32_t) + tlen + MND_SUBSCRIBE_RESERVE_SIZE; SSdbRaw *pRaw = sdbAllocRaw(SDB_SUBSCRIBE, MND_SUBSCRIBE_VER_NUMBER, size); if (pRaw == NULL) goto SUB_ENCODE_OVER; buf = taosMemoryMalloc(tlen); if (buf == NULL) goto SUB_ENCODE_OVER; void *abuf = buf; tEncodeSubscribeObj(&abuf, pSub); int32_t dataPos = 0; SDB_SET_INT32(pRaw, dataPos, tlen, SUB_ENCODE_OVER); SDB_SET_BINARY(pRaw, dataPos, buf, tlen, SUB_ENCODE_OVER); SDB_SET_RESERVE(pRaw, dataPos, MND_SUBSCRIBE_RESERVE_SIZE, SUB_ENCODE_OVER); SDB_SET_DATALEN(pRaw, dataPos, SUB_ENCODE_OVER); terrno = TSDB_CODE_SUCCESS; SUB_ENCODE_OVER: taosMemoryFreeClear(buf); if (terrno != TSDB_CODE_SUCCESS) { mError("subscribe:%s, failed to encode to raw:%p since %s", pSub->key, pRaw, terrstr()); sdbFreeRaw(pRaw); return NULL; } mTrace("subscribe:%s, encode to raw:%p, row:%p", pSub->key, pRaw, pSub); return pRaw; } static SSdbRow *mndSubActionDecode(SSdbRaw *pRaw) { terrno = TSDB_CODE_OUT_OF_MEMORY; void *buf = NULL; int8_t sver = 0; if (sdbGetRawSoftVer(pRaw, &sver) != 0) goto SUB_DECODE_OVER; if (sver != MND_SUBSCRIBE_VER_NUMBER) { terrno = TSDB_CODE_SDB_INVALID_DATA_VER; goto SUB_DECODE_OVER; } int32_t size = sizeof(SMqSubscribeObj); SSdbRow *pRow = sdbAllocRow(size); if (pRow == NULL) goto SUB_DECODE_OVER; SMqSubscribeObj *pSub = sdbGetRowObj(pRow); if (pSub == NULL) goto SUB_DECODE_OVER; int32_t dataPos = 0; int32_t tlen; SDB_GET_INT32(pRaw, dataPos, &tlen, SUB_DECODE_OVER); buf = taosMemoryMalloc(tlen); if (buf == NULL) goto SUB_DECODE_OVER; SDB_GET_BINARY(pRaw, dataPos, buf, tlen, SUB_DECODE_OVER); SDB_GET_RESERVE(pRaw, dataPos, MND_SUBSCRIBE_RESERVE_SIZE, SUB_DECODE_OVER); if (tDecodeSubscribeObj(buf, pSub) == NULL) { goto SUB_DECODE_OVER; } terrno = TSDB_CODE_SUCCESS; SUB_DECODE_OVER: taosMemoryFreeClear(buf); if (terrno != TSDB_CODE_SUCCESS) { mError("subscribe:%s, failed to decode from raw:%p since %s", pSub->key, pRaw, terrstr()); taosMemoryFreeClear(pRow); return NULL; } return pRow; } static int32_t mndSubActionInsert(SSdb *pSdb, SMqSubscribeObj *pSub) { mTrace("subscribe:%s, perform insert action", pSub->key); return 0; } static int32_t mndSubActionDelete(SSdb *pSdb, SMqSubscribeObj *pSub) { mTrace("subscribe:%s, perform delete action", pSub->key); tDeleteSubscribeObj(pSub); return 0; } static int32_t mndSubActionUpdate(SSdb *pSdb, SMqSubscribeObj *pOldSub, SMqSubscribeObj *pNewSub) { mTrace("subscribe:%s, perform update action", pOldSub->key); taosWLockLatch(&pOldSub->lock); SHashObj *tmp = pOldSub->consumerHash; pOldSub->consumerHash = pNewSub->consumerHash; pNewSub->consumerHash = tmp; SArray *tmp1 = pOldSub->unassignedVgs; pOldSub->unassignedVgs = pNewSub->unassignedVgs; pNewSub->unassignedVgs = tmp1; taosWUnLockLatch(&pOldSub->lock); return 0; } int32_t mndMakeSubscribeKey(char *key, const char *cgroup, const char *topicName) { int32_t tlen = strlen(cgroup); memcpy(key, cgroup, tlen); key[tlen] = TMQ_SEPARATOR; strcpy(key + tlen + 1, topicName); return 0; } SMqSubscribeObj *mndAcquireSubscribe(SMnode *pMnode, const char *cgroup, const char *topicName) { SSdb *pSdb = pMnode->pSdb; char key[TSDB_SUBSCRIBE_KEY_LEN]; mndMakeSubscribeKey(key, cgroup, topicName); SMqSubscribeObj *pSub = sdbAcquire(pSdb, SDB_SUBSCRIBE, key); if (pSub == NULL) { terrno = TSDB_CODE_MND_SUBSCRIBE_NOT_EXIST; } return pSub; } SMqSubscribeObj *mndAcquireSubscribeByKey(SMnode *pMnode, const char *key) { SSdb *pSdb = pMnode->pSdb; SMqSubscribeObj *pSub = sdbAcquire(pSdb, SDB_SUBSCRIBE, key); if (pSub == NULL) { terrno = TSDB_CODE_MND_SUBSCRIBE_NOT_EXIST; } return pSub; } void mndReleaseSubscribe(SMnode *pMnode, SMqSubscribeObj *pSub) { SSdb *pSdb = pMnode->pSdb; sdbRelease(pSdb, pSub); } static int32_t mndProcessSubscribeInternalRsp(SNodeMsg *pRsp) { mndTransProcessRsp(pRsp); return 0; } static int32_t mndSetDropSubCommitLogs(SMnode *pMnode, STrans *pTrans, SMqSubscribeObj *pSub) { SSdbRaw *pCommitRaw = mndSubActionEncode(pSub); if (pCommitRaw == NULL) return -1; if (mndTransAppendCommitlog(pTrans, pCommitRaw) != 0) return -1; if (sdbSetRawStatus(pCommitRaw, SDB_STATUS_DROPPED) != 0) return -1; return 0; } int32_t mndDropSubByDB(SMnode *pMnode, STrans *pTrans, SDbObj *pDb) { int32_t code = -1; SSdb *pSdb = pMnode->pSdb; void *pIter = NULL; SMqSubscribeObj *pSub = NULL; while (1) { pIter = sdbFetch(pSdb, SDB_SUBSCRIBE, pIter, (void **)&pSub); if (pIter == NULL) break; if (pSub->dbUid != pDb->uid) { sdbRelease(pSdb, pSub); continue; } if (mndSetDropSubCommitLogs(pMnode, pTrans, pSub) < 0) { goto END; } } code = 0; END: return code; }