/* * 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 . */ #include "vnodeInt.h" typedef struct SPoolMem { int64_t size; struct SPoolMem *prev; struct SPoolMem *next; } SPoolMem; #define META_TDB_SMA_TEST static SPoolMem *openPool(); static void clearPool(SPoolMem *pPool); static void closePool(SPoolMem *pPool); static void *poolMalloc(void *arg, size_t size); static void poolFree(void *arg, void *ptr); struct SMetaDB { TXN txn; TENV *pEnv; TDB *pTbDB; TDB *pSchemaDB; TDB *pNameIdx; TDB *pStbIdx; TDB *pNtbIdx; TDB *pCtbIdx; SPoolMem *pPool; #ifdef META_TDB_SMA_TEST TDB *pSmaDB; TDB *pSmaIdx; #endif }; #pragma pack(push,1) typedef struct { tb_uid_t uid; int32_t sver; } SSchemaDbKey; #pragma pack(pop) typedef struct { char *name; tb_uid_t uid; } SNameIdxKey; typedef struct { tb_uid_t suid; tb_uid_t uid; } SCtbIdxKey; typedef struct { tb_uid_t uid; int64_t smaUid; } SSmaIdxKey; static int metaEncodeTbInfo(void **buf, STbCfg *pTbCfg); static void *metaDecodeTbInfo(void *buf, STbCfg *pTbCfg); static int metaEncodeSchema(void **buf, SSchemaWrapper *pSW); static void *metaDecodeSchema(void *buf, SSchemaWrapper *pSW); static int metaEncodeSchemaEx(void **buf, SSchemaWrapper *pSW); static void *metaDecodeSchemaEx(void *buf, SSchemaWrapper *pSW, bool isGetEx); static SSchemaWrapper *metaGetTableSchemaImpl(SMeta *pMeta, tb_uid_t uid, int32_t sver, bool isinline, bool isGetEx); static inline int metaUidCmpr(const void *arg1, int len1, const void *arg2, int len2) { tb_uid_t uid1, uid2; ASSERT(len1 == sizeof(tb_uid_t)); ASSERT(len2 == sizeof(tb_uid_t)); uid1 = ((tb_uid_t *)arg1)[0]; uid2 = ((tb_uid_t *)arg2)[0]; if (uid1 < uid2) { return -1; } if (uid1 == uid2) { return 0; } else { return 1; } } static inline int metaSchemaKeyCmpr(const void *arg1, int len1, const void *arg2, int len2) { int c; SSchemaDbKey *pKey1 = (SSchemaDbKey *)arg1; SSchemaDbKey *pKey2 = (SSchemaDbKey *)arg2; c = metaUidCmpr(arg1, sizeof(tb_uid_t), arg2, sizeof(tb_uid_t)); if (c) return c; if (pKey1->sver > pKey2->sver) { return 1; } else if (pKey1->sver == pKey2->sver) { return 0; } else { return -1; } } static inline int metaNameIdxCmpr(const void *arg1, int len1, const void *arg2, int len2) { return strcmp((char *)arg1, (char *)arg2); } static inline int metaCtbIdxCmpr(const void *arg1, int len1, const void *arg2, int len2) { int c; SCtbIdxKey *pKey1 = (SCtbIdxKey *)arg1; SCtbIdxKey *pKey2 = (SCtbIdxKey *)arg2; c = metaUidCmpr(arg1, sizeof(tb_uid_t), arg2, sizeof(tb_uid_t)); if (c) return c; return metaUidCmpr(&pKey1->uid, sizeof(tb_uid_t), &pKey2->uid, sizeof(tb_uid_t)); } static inline int metaSmaIdxCmpr(const void *arg1, int len1, const void *arg2, int len2) { int c; SSmaIdxKey *pKey1 = (SSmaIdxKey *)arg1; SSmaIdxKey *pKey2 = (SSmaIdxKey *)arg2; c = metaUidCmpr(arg1, sizeof(tb_uid_t), arg2, sizeof(tb_uid_t)); if (c) return c; return metaUidCmpr(&pKey1->smaUid, sizeof(int64_t), &pKey2->smaUid, sizeof(int64_t)); } int metaOpenDB(SMeta *pMeta) { SMetaDB *pMetaDb; int ret; // allocate DB handle pMetaDb = taosMemoryCalloc(1, sizeof(*pMetaDb)); if (pMetaDb == NULL) { // TODO ASSERT(0); return -1; } // open the ENV ret = tdbEnvOpen(pMeta->path, 4096, 256, &(pMetaDb->pEnv)); if (ret < 0) { // TODO ASSERT(0); return -1; } // open table DB ret = tdbDbOpen("table.db", sizeof(tb_uid_t), TDB_VARIANT_LEN, metaUidCmpr, pMetaDb->pEnv, &(pMetaDb->pTbDB)); if (ret < 0) { // TODO ASSERT(0); return -1; } #ifdef META_TDB_SMA_TEST ret = tdbDbOpen("sma.db", sizeof(int64_t), TDB_VARIANT_LEN, metaUidCmpr, pMetaDb->pEnv, &(pMetaDb->pSmaDB)); if (ret < 0) { // TODO ASSERT(0); return -1; } #endif // open schema DB ret = tdbDbOpen("schema.db", sizeof(SSchemaDbKey), TDB_VARIANT_LEN, metaSchemaKeyCmpr, pMetaDb->pEnv, &(pMetaDb->pSchemaDB)); if (ret < 0) { // TODO ASSERT(0); return -1; } ret = tdbDbOpen("name.idx", TDB_VARIANT_LEN, 0, metaNameIdxCmpr, pMetaDb->pEnv, &(pMetaDb->pNameIdx)); if (ret < 0) { // TODO ASSERT(0); return -1; } ret = tdbDbOpen("stb.idx", sizeof(tb_uid_t), 0, metaUidCmpr, pMetaDb->pEnv, &(pMetaDb->pStbIdx)); if (ret < 0) { // TODO ASSERT(0); return -1; } ret = tdbDbOpen("ntb.idx", sizeof(tb_uid_t), 0, metaUidCmpr, pMetaDb->pEnv, &(pMetaDb->pNtbIdx)); if (ret < 0) { // TODO ASSERT(0); return -1; } ret = tdbDbOpen("ctb.idx", sizeof(SCtbIdxKey), 0, metaCtbIdxCmpr, pMetaDb->pEnv, &(pMetaDb->pCtbIdx)); if (ret < 0) { // TODO ASSERT(0); return -1; } #ifdef META_TDB_SMA_TEST ret = tdbDbOpen("sma.idx", sizeof(SSmaIdxKey), 0, metaSmaIdxCmpr, pMetaDb->pEnv, &(pMetaDb->pSmaIdx)); if (ret < 0) { // TODO ASSERT(0); return -1; } #endif pMetaDb->pPool = openPool(); tdbTxnOpen(&pMetaDb->txn, 0, poolMalloc, poolFree, pMetaDb->pPool, TDB_TXN_WRITE | TDB_TXN_READ_UNCOMMITTED); tdbBegin(pMetaDb->pEnv, NULL); pMeta->pDB = pMetaDb; return 0; } void metaCloseDB(SMeta *pMeta) { if (pMeta->pDB) { tdbCommit(pMeta->pDB->pEnv, &pMeta->pDB->txn); tdbTxnClose(&pMeta->pDB->txn); clearPool(pMeta->pDB->pPool); #ifdef META_TDB_SMA_TEST tdbDbClose(pMeta->pDB->pSmaIdx); #endif tdbDbClose(pMeta->pDB->pCtbIdx); tdbDbClose(pMeta->pDB->pNtbIdx); tdbDbClose(pMeta->pDB->pStbIdx); tdbDbClose(pMeta->pDB->pNameIdx); #ifdef META_TDB_SMA_TEST tdbDbClose(pMeta->pDB->pSmaDB); #endif tdbDbClose(pMeta->pDB->pSchemaDB); tdbDbClose(pMeta->pDB->pTbDB); taosMemoryFree(pMeta->pDB); } } int metaSaveTableToDB(SMeta *pMeta, STbCfg *pTbCfg) { tb_uid_t uid; SMetaDB *pMetaDb; void *pKey; void *pVal; int kLen; int vLen; int ret; char buf[512]; void *pBuf; SCtbIdxKey ctbIdxKey; SSchemaDbKey schemaDbKey; SSchemaWrapper schemaWrapper; pMetaDb = pMeta->pDB; // TODO: make this operation pre-process if (pTbCfg->type == META_SUPER_TABLE) { uid = pTbCfg->stbCfg.suid; } else { uid = metaGenerateUid(pMeta); } // check name and uid unique if (tdbDbGet(pMetaDb->pTbDB, &uid, sizeof(uid), NULL, NULL) == 0) { return -1; } if (tdbDbGet(pMetaDb->pNameIdx, pTbCfg->name, strlen(pTbCfg->name) + 1, NULL, NULL) == 0) { return -1; } // save to table.db pKey = &uid; kLen = sizeof(uid); pVal = pBuf = buf; metaEncodeTbInfo(&pBuf, pTbCfg); vLen = POINTER_DISTANCE(pBuf, buf); ret = tdbDbInsert(pMetaDb->pTbDB, pKey, kLen, pVal, vLen, &pMetaDb->txn); if (ret < 0) { return -1; } // save to schema.db for META_SUPER_TABLE and META_NORMAL_TABLE if (pTbCfg->type != META_CHILD_TABLE) { schemaDbKey.uid = uid; schemaDbKey.sver = 0; // TODO pKey = &schemaDbKey; kLen = sizeof(schemaDbKey); if (pTbCfg->type == META_SUPER_TABLE) { schemaWrapper.nCols = pTbCfg->stbCfg.nCols; schemaWrapper.pSchema = pTbCfg->stbCfg.pSchema; } else { schemaWrapper.nCols = pTbCfg->ntbCfg.nCols; schemaWrapper.pSchema = pTbCfg->ntbCfg.pSchema; } pVal = pBuf = buf; metaEncodeSchemaEx(&pBuf, &schemaWrapper); vLen = POINTER_DISTANCE(pBuf, buf); ret = tdbDbInsert(pMetaDb->pSchemaDB, pKey, kLen, pVal, vLen, &pMeta->pDB->txn); if (ret < 0) { return -1; } } // update name.idx int nameLen = strlen(pTbCfg->name); memcpy(buf, pTbCfg->name, nameLen + 1); ((tb_uid_t *)(buf + nameLen + 1))[0] = uid; pKey = buf; kLen = nameLen + 1 + sizeof(uid); pVal = NULL; vLen = 0; ret = tdbDbInsert(pMetaDb->pNameIdx, pKey, kLen, pVal, vLen, &pMetaDb->txn); if (ret < 0) { return -1; } // update other index if (pTbCfg->type == META_SUPER_TABLE) { pKey = &uid; kLen = sizeof(uid); pVal = NULL; vLen = 0; ret = tdbDbInsert(pMetaDb->pStbIdx, pKey, kLen, pVal, vLen, &pMetaDb->txn); if (ret < 0) { return -1; } } else if (pTbCfg->type == META_CHILD_TABLE) { ctbIdxKey.suid = pTbCfg->ctbCfg.suid; ctbIdxKey.uid = uid; pKey = &ctbIdxKey; kLen = sizeof(ctbIdxKey); pVal = NULL; vLen = 0; ret = tdbDbInsert(pMetaDb->pCtbIdx, pKey, kLen, pVal, vLen, &pMetaDb->txn); if (ret < 0) { return -1; } } else if (pTbCfg->type == META_NORMAL_TABLE) { pKey = &uid; kLen = sizeof(uid); pVal = NULL; vLen = 0; ret = tdbDbInsert(pMetaDb->pNtbIdx, pKey, kLen, pVal, vLen, &pMetaDb->txn); if (ret < 0) { return -1; } } if (pMeta->pDB->pPool->size > 0) { metaCommit(pMeta); } return 0; } int metaRemoveTableFromDb(SMeta *pMeta, tb_uid_t uid) { // TODO ASSERT(0); return 0; } STbCfg *metaGetTbInfoByUid(SMeta *pMeta, tb_uid_t uid) { int ret; SMetaDB *pMetaDb = pMeta->pDB; void *pKey; void *pVal; int kLen; int vLen; STbCfg *pTbCfg; // Fetch pKey = &uid; kLen = sizeof(uid); pVal = NULL; ret = tdbDbGet(pMetaDb->pTbDB, pKey, kLen, &pVal, &vLen); if (ret < 0) { return NULL; } // Decode pTbCfg = taosMemoryMalloc(sizeof(*pTbCfg)); metaDecodeTbInfo(pVal, pTbCfg); TDB_FREE(pVal); return pTbCfg; } STbCfg *metaGetTbInfoByName(SMeta *pMeta, char *tbname, tb_uid_t *uid) { void *pKey; void *pVal; void *ppKey; int pkLen; int kLen; int vLen; int ret; pKey = tbname; kLen = strlen(tbname) + 1; pVal = NULL; ppKey = NULL; ret = tdbDbPGet(pMeta->pDB->pNameIdx, pKey, kLen, &ppKey, &pkLen, &pVal, &vLen); if (ret < 0) { return NULL; } ASSERT(pkLen == kLen + sizeof(uid)); *uid = *(tb_uid_t *)POINTER_SHIFT(ppKey, kLen); TDB_FREE(ppKey); TDB_FREE(pVal); return metaGetTbInfoByUid(pMeta, *uid); } SSchemaWrapper *metaGetTableSchema(SMeta *pMeta, tb_uid_t uid, int32_t sver, bool isinline) { return metaGetTableSchemaImpl(pMeta, uid, sver, isinline, false); } static SSchemaWrapper *metaGetTableSchemaImpl(SMeta *pMeta, tb_uid_t uid, int32_t sver, bool isinline, bool isGetEx) { void *pKey; void *pVal; int kLen; int vLen; int ret; SSchemaDbKey schemaDbKey; SSchemaWrapper *pSchemaWrapper; void *pBuf; // fetch schemaDbKey.uid = uid; schemaDbKey.sver = sver; pKey = &schemaDbKey; kLen = sizeof(schemaDbKey); pVal = NULL; ret = tdbDbGet(pMeta->pDB->pSchemaDB, pKey, kLen, &pVal, &vLen); if (ret < 0) { return NULL; } // decode pBuf = pVal; pSchemaWrapper = taosMemoryMalloc(sizeof(*pSchemaWrapper)); metaDecodeSchemaEx(pBuf, pSchemaWrapper, isGetEx); TDB_FREE(pVal); return pSchemaWrapper; } STSchema *metaGetTbTSchema(SMeta *pMeta, tb_uid_t uid, int32_t sver) { tb_uid_t quid; SSchemaWrapper *pSW; STSchemaBuilder sb; SSchema *pSchema; STSchema *pTSchema; STbCfg *pTbCfg; pTbCfg = metaGetTbInfoByUid(pMeta, uid); if (pTbCfg->type == META_CHILD_TABLE) { quid = pTbCfg->ctbCfg.suid; } else { quid = uid; } pSW = metaGetTableSchemaImpl(pMeta, quid, sver, true, true); if (pSW == NULL) { return NULL; } tdInitTSchemaBuilder(&sb, 0); for (int i = 0; i < pSW->nCols; i++) { pSchema = pSW->pSchema + i; tdAddColToSchema(&sb, pSchema->type, pSchema->flags, pSchema->colId, pSchema->bytes); } pTSchema = tdGetSchemaFromBuilder(&sb); tdDestroyTSchemaBuilder(&sb); return pTSchema; } struct SMTbCursor { TDBC *pDbc; }; SMTbCursor *metaOpenTbCursor(SMeta *pMeta) { SMTbCursor *pTbCur = NULL; SMetaDB *pDB = pMeta->pDB; pTbCur = (SMTbCursor *)taosMemoryCalloc(1, sizeof(*pTbCur)); if (pTbCur == NULL) { return NULL; } tdbDbcOpen(pDB->pTbDB, &pTbCur->pDbc); return pTbCur; } void metaCloseTbCursor(SMTbCursor *pTbCur) { if (pTbCur) { if (pTbCur->pDbc) { tdbDbcClose(pTbCur->pDbc); } taosMemoryFree(pTbCur); } } char *metaTbCursorNext(SMTbCursor *pTbCur) { void *pKey = NULL; void *pVal = NULL; int kLen; int vLen; int ret; void *pBuf; STbCfg tbCfg; for (;;) { ret = tdbDbNext(pTbCur->pDbc, &pKey, &kLen, &pVal, &vLen); if (ret < 0) break; pBuf = pVal; metaDecodeTbInfo(pBuf, &tbCfg); if (tbCfg.type == META_SUPER_TABLE) { taosMemoryFree(tbCfg.name); taosMemoryFree(tbCfg.stbCfg.pTagSchema); continue; } else if (tbCfg.type == META_CHILD_TABLE) { kvRowFree(tbCfg.ctbCfg.pTag); } return tbCfg.name; } return NULL; } struct SMCtbCursor { TDBC *pCur; tb_uid_t suid; void *pKey; void *pVal; int kLen; int vLen; }; SMCtbCursor *metaOpenCtbCursor(SMeta *pMeta, tb_uid_t uid) { SMCtbCursor *pCtbCur = NULL; SMetaDB *pDB = pMeta->pDB; int ret; pCtbCur = (SMCtbCursor *)taosMemoryCalloc(1, sizeof(*pCtbCur)); if (pCtbCur == NULL) { return NULL; } pCtbCur->suid = uid; ret = tdbDbcOpen(pDB->pCtbIdx, &pCtbCur->pCur); if (ret < 0) { taosMemoryFree(pCtbCur); return NULL; } // TODO: move the cursor to the suid there return pCtbCur; } void metaCloseCtbCurosr(SMCtbCursor *pCtbCur) { if (pCtbCur) { if (pCtbCur->pCur) { tdbDbcClose(pCtbCur->pCur); TDB_FREE(pCtbCur->pKey); TDB_FREE(pCtbCur->pVal); } taosMemoryFree(pCtbCur); } } tb_uid_t metaCtbCursorNext(SMCtbCursor *pCtbCur) { int ret; SCtbIdxKey *pCtbIdxKey; ret = tdbDbNext(pCtbCur->pCur, &pCtbCur->pKey, &pCtbCur->kLen, &pCtbCur->pVal, &pCtbCur->vLen); if (ret < 0) { return 0; } pCtbIdxKey = pCtbCur->pKey; return pCtbIdxKey->uid; } int metaGetTbNum(SMeta *pMeta) { // TODO // ASSERT(0); return 0; } struct SMSmaCursor { TDBC *pCur; tb_uid_t uid; void *pKey; void *pVal; int kLen; int vLen; }; STSmaWrapper *metaGetSmaInfoByTable(SMeta *pMeta, tb_uid_t uid) { // TODO // ASSERT(0); // return NULL; #ifdef META_TDB_SMA_TEST STSmaWrapper *pSW = NULL; SMSmaCursor *pCur = metaOpenSmaCursor(pMeta, uid); if (pCur == NULL) { return NULL; } void *pBuf = NULL; SSmaIdxKey *pSmaIdxKey = NULL; while (true) { // TODO: lock during iterate? if (tdbDbNext(pCur->pCur, &pCur->pKey, &pCur->kLen, NULL, &pCur->vLen) == 0) { pSmaIdxKey = pCur->pKey; ASSERT(pSmaIdxKey != NULL); void *pSmaVal = metaGetSmaInfoByIndex(pMeta, pSmaIdxKey->smaUid, false); if (pSmaVal == NULL) { tsdbWarn("no tsma exists for indexUid: %" PRIi64, pSmaIdxKey->smaUid); continue; } if ((pSW == NULL) && ((pSW = taosMemoryCalloc(1, sizeof(*pSW))) == NULL)) { TDB_FREE(pSmaVal); metaCloseSmaCursor(pCur); return NULL; } ++pSW->number; STSma *tptr = (STSma *)taosMemoryRealloc(pSW->tSma, pSW->number * sizeof(STSma)); if (tptr == NULL) { TDB_FREE(pSmaVal); metaCloseSmaCursor(pCur); tdDestroyTSmaWrapper(pSW); taosMemoryFreeClear(pSW); return NULL; } pSW->tSma = tptr; pBuf = pSmaVal; if (tDecodeTSma(pBuf, pSW->tSma + pSW->number - 1) == NULL) { TDB_FREE(pSmaVal); metaCloseSmaCursor(pCur); tdDestroyTSmaWrapper(pSW); taosMemoryFreeClear(pSW); return NULL; } TDB_FREE(pSmaVal); continue; } break; } metaCloseSmaCursor(pCur); return pSW; #endif } int metaRemoveSmaFromDb(SMeta *pMeta, int64_t indexUid) { // TODO ASSERT(0); #ifndef META_TDB_SMA_TEST DBT key = {0}; key.data = (void *)indexName; key.size = strlen(indexName); metaDBWLock(pMeta->pDB); // TODO: No guarantee of consistence. // Use transaction or DB->sync() for some guarantee. pMeta->pDB->pSmaDB->del(pMeta->pDB->pSmaDB, NULL, &key, 0); metaDBULock(pMeta->pDB); #endif return 0; } int metaSaveSmaToDB(SMeta *pMeta, STSma *pSmaCfg) { // TODO // ASSERT(0); #ifdef META_TDB_SMA_TEST int32_t ret = 0; SMetaDB *pMetaDb = pMeta->pDB; void *pBuf = NULL, *qBuf = NULL; void *key = {0}, *val = {0}; // save sma info int32_t len = tEncodeTSma(NULL, pSmaCfg); pBuf = taosMemoryCalloc(1, len); if (pBuf == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return -1; } key = (void *)&pSmaCfg->indexUid; qBuf = pBuf; tEncodeTSma(&qBuf, pSmaCfg); val = pBuf; int32_t kLen = sizeof(pSmaCfg->indexUid); int32_t vLen = POINTER_DISTANCE(qBuf, pBuf); ret = tdbDbInsert(pMeta->pDB->pSmaDB, key, kLen, val, vLen, &pMetaDb->txn); if (ret < 0) { taosMemoryFreeClear(pBuf); return -1; } // add sma idx SSmaIdxKey smaIdxKey; smaIdxKey.uid = pSmaCfg->tableUid; smaIdxKey.smaUid = pSmaCfg->indexUid; key = &smaIdxKey; kLen = sizeof(smaIdxKey); val = NULL; vLen = 0; ret = tdbDbInsert(pMeta->pDB->pSmaIdx, key, kLen, val, vLen, &pMetaDb->txn); if (ret < 0) { taosMemoryFreeClear(pBuf); return -1; } // release taosMemoryFreeClear(pBuf); if (pMeta->pDB->pPool->size > 0) { metaCommit(pMeta); } #endif return 0; } void *metaGetSmaInfoByIndex(SMeta *pMeta, int64_t indexUid, bool isDecode) { // TODO // ASSERT(0); // return NULL; #ifdef META_TDB_SMA_TEST SMetaDB *pDB = pMeta->pDB; void *pKey = NULL; void *pVal = NULL; int kLen = 0; int vLen = 0; int ret = -1; // Set key pKey = (void *)&indexUid; kLen = sizeof(indexUid); // Query ret = tdbDbGet(pDB->pSmaDB, pKey, kLen, &pVal, &vLen); if (ret != 0 || !pVal) { return NULL; } if (!isDecode) { // return raw value return pVal; } // Decode STSma *pCfg = (STSma *)taosMemoryCalloc(1, sizeof(STSma)); if (pCfg == NULL) { taosMemoryFree(pVal); return NULL; } void *pBuf = pVal; if (tDecodeTSma(pBuf, pCfg) == NULL) { tdDestroyTSma(pCfg); taosMemoryFree(pCfg); TDB_FREE(pVal); return NULL; } TDB_FREE(pVal); return pCfg; #endif } /** * @brief * * @param pMeta * @param uid 0 means iterate all uids. * @return SMSmaCursor* */ SMSmaCursor *metaOpenSmaCursor(SMeta *pMeta, tb_uid_t uid) { // TODO // ASSERT(0); // return NULL; #ifdef META_TDB_SMA_TEST SMSmaCursor *pCur = NULL; SMetaDB *pDB = pMeta->pDB; int ret; pCur = (SMSmaCursor *)taosMemoryCalloc(1, sizeof(*pCur)); if (pCur == NULL) { return NULL; } pCur->uid = uid; ret = tdbDbcOpen(pDB->pSmaIdx, &(pCur->pCur)); if ((ret != 0) || (pCur->pCur == NULL)) { taosMemoryFree(pCur); return NULL; } if (uid != 0) { // TODO: move to the specific uid } return pCur; #endif } /** * @brief * * @param pCur * @return int64_t smaIndexUid */ int64_t metaSmaCursorNext(SMSmaCursor *pCur) { // TODO // ASSERT(0); // return NULL; #ifdef META_TDB_SMA_TEST int ret; void *pBuf; SSmaIdxKey *smaIdxKey; ret = tdbDbNext(pCur->pCur, &pCur->pKey, &pCur->kLen, &pCur->pVal, &pCur->vLen); if (ret < 0) { return 0; } smaIdxKey = pCur->pKey; return smaIdxKey->smaUid; #endif } void metaCloseSmaCursor(SMSmaCursor *pCur) { // TODO // ASSERT(0); #ifdef META_TDB_SMA_TEST if (pCur) { if (pCur->pCur) { tdbDbcClose(pCur->pCur); } taosMemoryFree(pCur); } #endif } SArray *metaGetSmaTbUids(SMeta *pMeta, bool isDup) { // TODO // ASSERT(0); // comment this line to pass CI // return NULL: #ifdef META_TDB_SMA_TEST SArray *pUids = NULL; SMetaDB *pDB = pMeta->pDB; void *pKey; // TODO: lock? SMSmaCursor *pCur = metaOpenSmaCursor(pMeta, 0); if (pCur == NULL) { return NULL; } // TODO: lock? SSmaIdxKey *pSmaIdxKey = NULL; tb_uid_t uid = 0; while (true) { // TODO: lock during iterate? if (tdbDbNext(pCur->pCur, &pCur->pKey, &pCur->kLen, NULL, &pCur->vLen) == 0) { ASSERT(pSmaIdxKey != NULL); pSmaIdxKey = pCur->pKey; if (pSmaIdxKey->uid == 0 || pSmaIdxKey->uid == uid) { continue; } uid = pSmaIdxKey->uid; if (!pUids) { pUids = taosArrayInit(16, sizeof(tb_uid_t)); if (!pUids) { metaCloseSmaCursor(pCur); return NULL; } } taosArrayPush(pUids, &uid); continue; } break; } metaCloseSmaCursor(pCur); return pUids; #endif } static int metaEncodeSchema(void **buf, SSchemaWrapper *pSW) { int tlen = 0; SSchema *pSchema; tlen += taosEncodeFixedU32(buf, pSW->nCols); for (int i = 0; i < pSW->nCols; i++) { pSchema = pSW->pSchema + i; tlen += taosEncodeFixedI8(buf, pSchema->type); tlen += taosEncodeFixedI8(buf, pSchema->flags); tlen += taosEncodeFixedI16(buf, pSchema->colId); tlen += taosEncodeFixedI32(buf, pSchema->bytes); tlen += taosEncodeString(buf, pSchema->name); } return tlen; } static void *metaDecodeSchema(void *buf, SSchemaWrapper *pSW) { SSchema *pSchema; buf = taosDecodeFixedU32(buf, &pSW->nCols); pSW->pSchema = (SSchema *)taosMemoryMalloc(sizeof(SSchema) * pSW->nCols); for (int i = 0; i < pSW->nCols; i++) { pSchema = pSW->pSchema + i; buf = taosDecodeFixedI8(buf, &pSchema->type); buf = taosSkipFixedLen(buf, sizeof(int8_t)); buf = taosDecodeFixedI16(buf, &pSchema->colId); buf = taosDecodeFixedI32(buf, &pSchema->bytes); buf = taosDecodeStringTo(buf, pSchema->name); } return buf; } static int metaEncodeSchemaEx(void **buf, SSchemaWrapper *pSW) { int tlen = 0; SSchema *pSchema; tlen += taosEncodeFixedU32(buf, pSW->nCols); for (int i = 0; i < pSW->nCols; ++i) { pSchema = pSW->pSchema + i; tlen += taosEncodeFixedI8(buf, pSchema->type); tlen += taosEncodeFixedI8(buf, pSchema->flags); tlen += taosEncodeFixedI16(buf, pSchema->colId); tlen += taosEncodeFixedI32(buf, pSchema->bytes); tlen += taosEncodeString(buf, pSchema->name); } return tlen; } static void *metaDecodeSchemaEx(void *buf, SSchemaWrapper *pSW, bool isGetEx) { buf = taosDecodeFixedU32(buf, &pSW->nCols); if (isGetEx) { pSW->pSchema = (SSchema *)taosMemoryMalloc(sizeof(SSchema) * pSW->nCols); for (int i = 0; i < pSW->nCols; i++) { SSchema *pSchema = pSW->pSchema + i; buf = taosDecodeFixedI8(buf, &pSchema->type); buf = taosDecodeFixedI8(buf, &pSchema->flags); buf = taosDecodeFixedI16(buf, &pSchema->colId); buf = taosDecodeFixedI32(buf, &pSchema->bytes); buf = taosDecodeStringTo(buf, pSchema->name); } } else { pSW->pSchema = (SSchema *)taosMemoryMalloc(sizeof(SSchema) * pSW->nCols); for (int i = 0; i < pSW->nCols; i++) { SSchema *pSchema = pSW->pSchema + i; buf = taosDecodeFixedI8(buf, &pSchema->type); buf = taosSkipFixedLen(buf, sizeof(int8_t)); buf = taosDecodeFixedI16(buf, &pSchema->colId); buf = taosDecodeFixedI32(buf, &pSchema->bytes); buf = taosDecodeStringTo(buf, pSchema->name); } } return buf; } static int metaEncodeTbInfo(void **buf, STbCfg *pTbCfg) { int tsize = 0; tsize += taosEncodeString(buf, pTbCfg->name); tsize += taosEncodeFixedU32(buf, pTbCfg->ttl); tsize += taosEncodeFixedU32(buf, pTbCfg->keep); tsize += taosEncodeFixedU8(buf, pTbCfg->info); if (pTbCfg->type == META_SUPER_TABLE) { SSchemaWrapper sw = {.nCols = pTbCfg->stbCfg.nTagCols, .pSchema = pTbCfg->stbCfg.pTagSchema}; tsize += metaEncodeSchema(buf, &sw); } else if (pTbCfg->type == META_CHILD_TABLE) { tsize += taosEncodeFixedU64(buf, pTbCfg->ctbCfg.suid); tsize += tdEncodeKVRow(buf, pTbCfg->ctbCfg.pTag); } else if (pTbCfg->type == META_NORMAL_TABLE) { // TODO } else { ASSERT(0); } return tsize; } static void *metaDecodeTbInfo(void *buf, STbCfg *pTbCfg) { buf = taosDecodeString(buf, &(pTbCfg->name)); buf = taosDecodeFixedU32(buf, &(pTbCfg->ttl)); buf = taosDecodeFixedU32(buf, &(pTbCfg->keep)); buf = taosDecodeFixedU8(buf, &(pTbCfg->info)); if (pTbCfg->type == META_SUPER_TABLE) { SSchemaWrapper sw; buf = metaDecodeSchema(buf, &sw); pTbCfg->stbCfg.nTagCols = sw.nCols; pTbCfg->stbCfg.pTagSchema = sw.pSchema; } else if (pTbCfg->type == META_CHILD_TABLE) { buf = taosDecodeFixedU64(buf, &(pTbCfg->ctbCfg.suid)); buf = tdDecodeKVRow(buf, &(pTbCfg->ctbCfg.pTag)); } else if (pTbCfg->type == META_NORMAL_TABLE) { // TODO } else { ASSERT(0); } return buf; } int metaCommit(SMeta *pMeta) { TXN *pTxn = &pMeta->pDB->txn; // Commit current txn tdbCommit(pMeta->pDB->pEnv, pTxn); tdbTxnClose(pTxn); clearPool(pMeta->pDB->pPool); // start a new txn tdbTxnOpen(&pMeta->pDB->txn, 0, poolMalloc, poolFree, pMeta->pDB->pPool, TDB_TXN_WRITE | TDB_TXN_READ_UNCOMMITTED); tdbBegin(pMeta->pDB->pEnv, pTxn); return 0; } static SPoolMem *openPool() { SPoolMem *pPool = (SPoolMem *)tdbOsMalloc(sizeof(*pPool)); pPool->prev = pPool->next = pPool; pPool->size = 0; return pPool; } static void clearPool(SPoolMem *pPool) { SPoolMem *pMem; do { pMem = pPool->next; if (pMem == pPool) break; pMem->next->prev = pMem->prev; pMem->prev->next = pMem->next; pPool->size -= pMem->size; tdbOsFree(pMem); } while (1); assert(pPool->size == 0); } static void closePool(SPoolMem *pPool) { clearPool(pPool); tdbOsFree(pPool); } static void *poolMalloc(void *arg, size_t size) { void *ptr = NULL; SPoolMem *pPool = (SPoolMem *)arg; SPoolMem *pMem; pMem = (SPoolMem *)tdbOsMalloc(sizeof(*pMem) + size); if (pMem == NULL) { assert(0); } pMem->size = sizeof(*pMem) + size; pMem->next = pPool->next; pMem->prev = pPool; pPool->next->prev = pMem; pPool->next = pMem; pPool->size += pMem->size; ptr = (void *)(&pMem[1]); return ptr; } static void poolFree(void *arg, void *ptr) { SPoolMem *pPool = (SPoolMem *)arg; SPoolMem *pMem; pMem = &(((SPoolMem *)ptr)[-1]); pMem->next->prev = pMem->prev; pMem->prev->next = pMem->next; pPool->size -= pMem->size; tdbOsFree(pMem); }