/* * 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 "tsdb.h" #include "tsdbFSet2.h" #include "tsdbReadUtil.h" #include "tsdbSttFileRW.h" static void tLDataIterClose2(SLDataIter *pIter); // SLDataIter ================================================= SSttBlockLoadInfo *tCreateLastBlockLoadInfo(STSchema *pSchema, int16_t *colList, int32_t numOfCols, int32_t numOfSttTrigger) { SSttBlockLoadInfo *pLoadInfo = taosMemoryCalloc(numOfSttTrigger, sizeof(SSttBlockLoadInfo)); if (pLoadInfo == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } for (int32_t i = 0; i < numOfSttTrigger; ++i) { pLoadInfo[i].blockIndex[0] = -1; pLoadInfo[i].blockIndex[1] = -1; pLoadInfo[i].currentLoadBlockIndex = 1; int32_t code = tBlockDataCreate(&pLoadInfo[i].blockData[0]); if (code) { terrno = code; } code = tBlockDataCreate(&pLoadInfo[i].blockData[1]); if (code) { terrno = code; } pLoadInfo[i].aSttBlk = taosArrayInit(4, sizeof(SSttBlk)); pLoadInfo[i].pSchema = pSchema; pLoadInfo[i].colIds = colList; pLoadInfo[i].numOfCols = numOfCols; } return pLoadInfo; } SSttBlockLoadInfo *tCreateOneLastBlockLoadInfo(STSchema *pSchema, int16_t *colList, int32_t numOfCols) { SSttBlockLoadInfo *pLoadInfo = taosMemoryCalloc(1, sizeof(SSttBlockLoadInfo)); if (pLoadInfo == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } pLoadInfo->blockIndex[0] = -1; pLoadInfo->blockIndex[1] = -1; pLoadInfo->currentLoadBlockIndex = 1; int32_t code = tBlockDataCreate(&pLoadInfo->blockData[0]); if (code) { terrno = code; } code = tBlockDataCreate(&pLoadInfo->blockData[1]); if (code) { terrno = code; } pLoadInfo->aSttBlk = taosArrayInit(4, sizeof(SSttBlk)); pLoadInfo->pSchema = pSchema; pLoadInfo->colIds = colList; pLoadInfo->numOfCols = numOfCols; return pLoadInfo; } void resetLastBlockLoadInfo(SSttBlockLoadInfo *pLoadInfo) { for (int32_t i = 0; i < 1; ++i) { pLoadInfo[i].currentLoadBlockIndex = 1; pLoadInfo[i].blockIndex[0] = -1; pLoadInfo[i].blockIndex[1] = -1; taosArrayClear(pLoadInfo[i].aSttBlk); pLoadInfo[i].elapsedTime = 0; pLoadInfo[i].loadBlocks = 0; pLoadInfo[i].sttBlockLoaded = false; } } void getLastBlockLoadInfo(SSttBlockLoadInfo *pLoadInfo, int64_t *blocks, double *el) { for (int32_t i = 0; i < 1; ++i) { *el += pLoadInfo[i].elapsedTime; *blocks += pLoadInfo[i].loadBlocks; } } static void freeTombBlock(void *param) { STombBlock **pTombBlock = (STombBlock **)param; tTombBlockDestroy(*pTombBlock); taosMemoryFree(*pTombBlock); } void *destroyLastBlockLoadInfo(SSttBlockLoadInfo *pLoadInfo) { if (pLoadInfo == NULL) { return NULL; } for (int32_t i = 0; i < 1; ++i) { pLoadInfo[i].currentLoadBlockIndex = 1; pLoadInfo[i].blockIndex[0] = -1; pLoadInfo[i].blockIndex[1] = -1; tBlockDataDestroy(&pLoadInfo[i].blockData[0]); tBlockDataDestroy(&pLoadInfo[i].blockData[1]); taosArrayDestroy(pLoadInfo[i].aSttBlk); } taosMemoryFree(pLoadInfo); return NULL; } static void destroyLDataIter(SLDataIter *pIter) { tLDataIterClose2(pIter); destroyLastBlockLoadInfo(pIter->pBlockLoadInfo); taosMemoryFree(pIter); } void *destroySttBlockReader(SArray *pLDataIterArray, int64_t *blocks, double *el) { if (pLDataIterArray == NULL) { return NULL; } int32_t numOfLevel = taosArrayGetSize(pLDataIterArray); for (int32_t i = 0; i < numOfLevel; ++i) { SArray *pList = taosArrayGetP(pLDataIterArray, i); for (int32_t j = 0; j < taosArrayGetSize(pList); ++j) { SLDataIter *pIter = taosArrayGetP(pList, j); *el += pIter->pBlockLoadInfo->elapsedTime; *blocks += pIter->pBlockLoadInfo->loadBlocks; destroyLDataIter(pIter); } taosArrayDestroy(pList); } taosArrayDestroy(pLDataIterArray); return NULL; } static SBlockData *loadLastBlock(SLDataIter *pIter, const char *idStr) { int32_t code = 0; SSttBlockLoadInfo *pInfo = pIter->pBlockLoadInfo; if (pInfo->blockIndex[0] == pIter->iSttBlk) { if (pInfo->currentLoadBlockIndex != 0) { tsdbDebug("current load index is set to 0, block index:%d, file index:%d, due to uid:%" PRIu64 ", load data, %s", pIter->iSttBlk, pIter->iStt, pIter->uid, idStr); pInfo->currentLoadBlockIndex = 0; } return &pInfo->blockData[0]; } if (pInfo->blockIndex[1] == pIter->iSttBlk) { if (pInfo->currentLoadBlockIndex != 1) { tsdbDebug("current load index is set to 1, block index:%d, file index:%d, due to uid:%" PRIu64 ", load data, %s", pIter->iSttBlk, pIter->iStt, pIter->uid, idStr); pInfo->currentLoadBlockIndex = 1; } return &pInfo->blockData[1]; } if (pIter->pSttBlk == NULL || pInfo->pSchema == NULL) { return NULL; } // current block not loaded yet pInfo->currentLoadBlockIndex ^= 1; int64_t st = taosGetTimestampUs(); SBlockData *pBlock = &pInfo->blockData[pInfo->currentLoadBlockIndex]; code = tsdbSttFileReadBlockDataByColumn(pIter->pReader, pIter->pSttBlk, pBlock, pInfo->pSchema, &pInfo->colIds[1], pInfo->numOfCols - 1); if (code != TSDB_CODE_SUCCESS) { goto _exit; } double el = (taosGetTimestampUs() - st) / 1000.0; pInfo->elapsedTime += el; pInfo->loadBlocks += 1; tsdbDebug("read last block, total load:%d, trigger by uid:%" PRIu64 ", last file index:%d, last block index:%d, entry:%d, rows:%d, %p, elapsed time:%.2f ms, %s", pInfo->loadBlocks, pIter->uid, pIter->iStt, pIter->iSttBlk, pInfo->currentLoadBlockIndex, pBlock->nRow, pBlock, el, idStr); pInfo->blockIndex[pInfo->currentLoadBlockIndex] = pIter->iSttBlk; pIter->iRow = (pIter->backward) ? pInfo->blockData[pInfo->currentLoadBlockIndex].nRow : -1; tsdbDebug("last block index list:%d, %d, rowIndex:%d %s", pInfo->blockIndex[0], pInfo->blockIndex[1], pIter->iRow, idStr); return &pInfo->blockData[pInfo->currentLoadBlockIndex]; _exit: if (code != TSDB_CODE_SUCCESS) { terrno = code; } return NULL; } // find the earliest block that contains the required records static FORCE_INLINE int32_t findEarliestIndex(int32_t index, uint64_t uid, const SSttBlk *pBlockList, int32_t num, int32_t backward) { int32_t i = index; int32_t step = backward ? 1 : -1; while (i >= 0 && i < num && uid >= pBlockList[i].minUid && uid <= pBlockList[i].maxUid) { i += step; } return i - step; } static int32_t binarySearchForStartBlock(SSttBlk *pBlockList, int32_t num, uint64_t uid, int32_t backward) { int32_t midPos = -1; if (num <= 0) { return -1; } int32_t firstPos = 0; int32_t lastPos = num - 1; // find the first position which is bigger than the key if ((uid > pBlockList[lastPos].maxUid) || (uid < pBlockList[firstPos].minUid)) { return -1; } while (1) { if (uid >= pBlockList[firstPos].minUid && uid <= pBlockList[firstPos].maxUid) { return findEarliestIndex(firstPos, uid, pBlockList, num, backward); } if (uid > pBlockList[lastPos].maxUid || uid < pBlockList[firstPos].minUid) { return -1; } int32_t numOfRows = lastPos - firstPos + 1; midPos = (numOfRows >> 1u) + firstPos; if (uid < pBlockList[midPos].minUid) { lastPos = midPos - 1; } else if (uid > pBlockList[midPos].maxUid) { firstPos = midPos + 1; } else { return findEarliestIndex(midPos, uid, pBlockList, num, backward); } } } static FORCE_INLINE int32_t findEarliestRow(int32_t index, uint64_t uid, const uint64_t *uidList, int32_t num, int32_t backward) { int32_t i = index; int32_t step = backward ? 1 : -1; while (i >= 0 && i < num && uid == uidList[i]) { i += step; } return i - step; } static int32_t binarySearchForStartRowIndex(uint64_t *uidList, int32_t num, uint64_t uid, int32_t backward) { int32_t firstPos = 0; int32_t lastPos = num - 1; // find the first position which is bigger than the key if ((uid > uidList[lastPos]) || (uid < uidList[firstPos])) { return -1; } while (1) { if (uid == uidList[firstPos]) { return findEarliestRow(firstPos, uid, uidList, num, backward); } if (uid > uidList[lastPos] || uid < uidList[firstPos]) { return -1; } int32_t numOfRows = lastPos - firstPos + 1; int32_t midPos = (numOfRows >> 1u) + firstPos; if (uid < uidList[midPos]) { lastPos = midPos - 1; } else if (uid > uidList[midPos]) { firstPos = midPos + 1; } else { return findEarliestRow(midPos, uid, uidList, num, backward); } } } int32_t tLDataIterOpen(struct SLDataIter *pIter, SDataFReader *pReader, int32_t iStt, int8_t backward, uint64_t suid, uint64_t uid, STimeWindow *pTimeWindow, SVersionRange *pRange, SSttBlockLoadInfo *pBlockLoadInfo, const char *idStr, bool strictTimeRange) { return 0; } static int32_t extractSttBlockInfo(SLDataIter *pIter, const TSttBlkArray *pArray, SSttBlockLoadInfo *pBlockLoadInfo, uint64_t suid) { if (TARRAY2_SIZE(pArray) <= 0) { return TSDB_CODE_SUCCESS; } SSttBlk *pStart = &pArray->data[0]; SSttBlk *pEnd = &pArray->data[TARRAY2_SIZE(pArray) - 1]; // all identical if (pStart->suid == pEnd->suid) { if (pStart->suid != suid) { // no qualified stt block existed taosArrayClear(pBlockLoadInfo->aSttBlk); pIter->iSttBlk = -1; return TSDB_CODE_SUCCESS; } else { // all blocks are qualified taosArrayClear(pBlockLoadInfo->aSttBlk); taosArrayAddBatch(pBlockLoadInfo->aSttBlk, pArray->data, pArray->size); } } else { SArray *pTmp = taosArrayInit(TARRAY2_SIZE(pArray), sizeof(SSttBlk)); for (int32_t i = 0; i < TARRAY2_SIZE(pArray); ++i) { SSttBlk *p = &pArray->data[i]; if (p->suid < suid) { continue; } if (p->suid == suid) { taosArrayPush(pTmp, p); } else if (p->suid > suid) { break; } } taosArrayDestroy(pBlockLoadInfo->aSttBlk); pBlockLoadInfo->aSttBlk = pTmp; } return TSDB_CODE_SUCCESS; } static int32_t uidComparFn(const void *p1, const void *p2) { const uint64_t *uid1 = p1; const uint64_t *uid2 = p2; return (*uid1) - (*uid2); } static bool existsFromSttBlkStatis(const TStatisBlkArray *pStatisBlkArray, uint64_t suid, uint64_t uid, SSttFileReader *pReader) { if (TARRAY2_SIZE(pStatisBlkArray) <= 0) { return true; } int32_t i = 0; for (i = 0; i < TARRAY2_SIZE(pStatisBlkArray); ++i) { SStatisBlk *p = &pStatisBlkArray->data[i]; if (p->minTbid.suid <= suid && p->maxTbid.suid >= suid) { break; } } // for (; i < TARRAY2_SIZE(pStatisBlkArray); ++i) { // SStatisBlk *p = &pStatisBlkArray->data[i]; // if (p->minTbid.uid <= uid && p->maxTbid.uid >= uid) { // break; // } // // if (p->maxTbid.uid < uid) { // break; // } // } if (i >= TARRAY2_SIZE(pStatisBlkArray)) { return false; } SStatisBlk *p = &pStatisBlkArray->data[i]; STbStatisBlock block = {0}; tsdbSttFileReadStatisBlock(pReader, p, &block); int32_t index = tarray2SearchIdx(block.uid, &uid, sizeof(int64_t), uidComparFn, TD_EQ); tStatisBlockDestroy(&block); return (index != -1); } int32_t tLDataIterOpen2(struct SLDataIter *pIter, SSttFileReader *pSttFileReader, int32_t iStt, int8_t backward, uint64_t suid, uint64_t uid, STimeWindow *pTimeWindow, SVersionRange *pRange, SSttBlockLoadInfo *pBlockLoadInfo, const char *idStr, bool strictTimeRange, _load_tomb_fn loadTombFn, void *pReader1) { int32_t code = TSDB_CODE_SUCCESS; pIter->uid = uid; pIter->iStt = iStt; pIter->backward = backward; pIter->verRange.minVer = pRange->minVer; pIter->verRange.maxVer = pRange->maxVer; pIter->timeWindow.skey = pTimeWindow->skey; pIter->timeWindow.ekey = pTimeWindow->ekey; pIter->pReader = pSttFileReader; pIter->pBlockLoadInfo = pBlockLoadInfo; if (!pBlockLoadInfo->sttBlockLoaded) { int64_t st = taosGetTimestampUs(); const TSttBlkArray *pSttBlkArray = NULL; pBlockLoadInfo->sttBlockLoaded = true; // load the stt block info for each stt-block code = tsdbSttFileReadSttBlk(pIter->pReader, &pSttBlkArray); if (code != TSDB_CODE_SUCCESS) { tsdbError("load stt blk failed, code:%s, %s", tstrerror(code), idStr); return code; } code = extractSttBlockInfo(pIter, pSttBlkArray, pBlockLoadInfo, suid); if (code != TSDB_CODE_SUCCESS) { tsdbError("load stt block info failed, code:%s, %s", tstrerror(code), idStr); return code; } // load stt blocks statis for all stt-blocks, to decide if the data of queried table exists in current stt file code = tsdbSttFileReadStatisBlk(pIter->pReader, (const TStatisBlkArray **)&pBlockLoadInfo->pSttStatisBlkArray); if (code != TSDB_CODE_SUCCESS) { tsdbError("failed to load stt block statistics, code:%s, %s", tstrerror(code), idStr); return code; } code = loadTombFn(pReader1, pIter->pReader, pIter->pBlockLoadInfo); double el = (taosGetTimestampUs() - st) / 1000.0; tsdbDebug("load the stt file info completed, elapsed time:%.2fms, %s", el, idStr); } // bool exists = existsFromSttBlkStatis(pBlockLoadInfo->pSttStatisBlkArray, suid, uid, pIter->pReader); // if (!exists) { // pIter->iSttBlk = -1; // pIter->pSttBlk = NULL; // return TSDB_CODE_SUCCESS; // } // find the start block, actually we could load the position to avoid repeatly searching for the start position when // the skey is updated. size_t size = taosArrayGetSize(pBlockLoadInfo->aSttBlk); pIter->iSttBlk = binarySearchForStartBlock(pBlockLoadInfo->aSttBlk->pData, size, uid, backward); if (pIter->iSttBlk != -1) { pIter->pSttBlk = taosArrayGet(pBlockLoadInfo->aSttBlk, pIter->iSttBlk); pIter->iRow = (pIter->backward) ? pIter->pSttBlk->nRow : -1; if ((!backward) && ((strictTimeRange && pIter->pSttBlk->minKey >= pIter->timeWindow.ekey) || (!strictTimeRange && pIter->pSttBlk->minKey > pIter->timeWindow.ekey))) { pIter->pSttBlk = NULL; } if (backward && ((strictTimeRange && pIter->pSttBlk->maxKey <= pIter->timeWindow.skey) || (!strictTimeRange && pIter->pSttBlk->maxKey < pIter->timeWindow.skey))) { pIter->pSttBlk = NULL; pIter->ignoreEarlierTs = true; } } return code; } void tLDataIterClose2(SLDataIter *pIter) { tsdbSttFileReaderClose(&pIter->pReader); pIter->pReader = NULL; } void tLDataIterNextBlock(SLDataIter *pIter, const char *idStr) { int32_t step = pIter->backward ? -1 : 1; int32_t oldIndex = pIter->iSttBlk; pIter->iSttBlk += step; int32_t index = -1; size_t size = pIter->pBlockLoadInfo->aSttBlk->size; for (int32_t i = pIter->iSttBlk; i < size && i >= 0; i += step) { SSttBlk *p = taosArrayGet(pIter->pBlockLoadInfo->aSttBlk, i); if ((!pIter->backward) && p->minUid > pIter->uid) { break; } if (pIter->backward && p->maxUid < pIter->uid) { break; } // check uid firstly if (p->minUid <= pIter->uid && p->maxUid >= pIter->uid) { if ((!pIter->backward) && p->minKey > pIter->timeWindow.ekey) { break; } if (pIter->backward && p->maxKey < pIter->timeWindow.skey) { break; } // check time range secondly if (p->minKey <= pIter->timeWindow.ekey && p->maxKey >= pIter->timeWindow.skey) { if ((!pIter->backward) && p->minVer > pIter->verRange.maxVer) { break; } if (pIter->backward && p->maxVer < pIter->verRange.minVer) { break; } if (p->minVer <= pIter->verRange.maxVer && p->maxVer >= pIter->verRange.minVer) { index = i; break; } } } } pIter->pSttBlk = NULL; if (index != -1) { pIter->iSttBlk = index; pIter->pSttBlk = (SSttBlk *)taosArrayGet(pIter->pBlockLoadInfo->aSttBlk, pIter->iSttBlk); tsdbDebug("try next last file block:%d from stt fileIdx:%d, trigger by uid:%" PRIu64 ", file index:%d, %s", pIter->iSttBlk, oldIndex, pIter->uid, pIter->iStt, idStr); } else { tsdbDebug("no more last block qualified, uid:%" PRIu64 ", file index:%d, %s", pIter->uid, oldIndex, idStr); } } static void findNextValidRow(SLDataIter *pIter, const char *idStr) { bool hasVal = false; int32_t step = pIter->backward ? -1 : 1; int32_t i = pIter->iRow; SBlockData *pData = loadLastBlock(pIter, idStr); // mostly we only need to find the start position for a given table if ((((i == 0) && (!pIter->backward)) || (i == pData->nRow - 1 && pIter->backward)) && pData->aUid != NULL) { i = binarySearchForStartRowIndex((uint64_t *)pData->aUid, pData->nRow, pIter->uid, pIter->backward); if (i == -1) { tsdbDebug("failed to find the data in pBlockData, uid:%" PRIu64 " , %s", pIter->uid, idStr); pIter->iRow = -1; return; } } for (; i < pData->nRow && i >= 0; i += step) { if (pData->aUid != NULL) { if (!pIter->backward) { if (pData->aUid[i] > pIter->uid) { break; } } else { if (pData->aUid[i] < pIter->uid) { break; } } } int64_t ts = pData->aTSKEY[i]; if (!pIter->backward) { // asc if (ts > pIter->timeWindow.ekey) { // no more data break; } else if (ts < pIter->timeWindow.skey) { continue; } } else { if (ts < pIter->timeWindow.skey) { break; } else if (ts > pIter->timeWindow.ekey) { continue; } } int64_t ver = pData->aVersion[i]; if (ver < pIter->verRange.minVer) { continue; } // todo opt handle desc case if (ver > pIter->verRange.maxVer) { continue; } hasVal = true; break; } pIter->iRow = (hasVal) ? i : -1; } bool tLDataIterNextRow(SLDataIter *pIter, const char *idStr) { int32_t step = pIter->backward ? -1 : 1; terrno = TSDB_CODE_SUCCESS; // no qualified last file block in current file, no need to fetch row if (pIter->pSttBlk == NULL) { return false; } int32_t iBlockL = pIter->iSttBlk; SBlockData *pBlockData = loadLastBlock(pIter, idStr); if (pBlockData == NULL || terrno != TSDB_CODE_SUCCESS) { goto _exit; } pIter->iRow += step; while (1) { bool skipBlock = false; findNextValidRow(pIter, idStr); if (pIter->pBlockLoadInfo->checkRemainingRow) { skipBlock = true; int16_t *aCols = pIter->pBlockLoadInfo->colIds; int nCols = pIter->pBlockLoadInfo->numOfCols; bool isLast = pIter->pBlockLoadInfo->isLast; for (int inputColIndex = 0; inputColIndex < nCols; ++inputColIndex) { for (int colIndex = 0; colIndex < pBlockData->nColData; ++colIndex) { SColData *pColData = &pBlockData->aColData[colIndex]; int16_t cid = pColData->cid; if (cid == aCols[inputColIndex]) { if (isLast && (pColData->flag & HAS_VALUE)) { skipBlock = false; break; } else if (pColData->flag & (HAS_VALUE | HAS_NULL)) { skipBlock = false; break; } } } } } if (skipBlock || pIter->iRow >= pBlockData->nRow || pIter->iRow < 0) { tLDataIterNextBlock(pIter, idStr); if (pIter->pSttBlk == NULL) { // no more data goto _exit; } } else { break; } if (iBlockL != pIter->iSttBlk) { pBlockData = loadLastBlock(pIter, idStr); if (pBlockData == NULL) { goto _exit; } // set start row index pIter->iRow = pIter->backward ? pBlockData->nRow - 1 : 0; } } pIter->rInfo.suid = pBlockData->suid; pIter->rInfo.uid = pBlockData->uid; pIter->rInfo.row = tsdbRowFromBlockData(pBlockData, pIter->iRow); _exit: return (terrno == TSDB_CODE_SUCCESS) && (pIter->pSttBlk != NULL) && (pBlockData != NULL); } SRowInfo *tLDataIterGet(SLDataIter *pIter) { return &pIter->rInfo; } // SMergeTree ================================================= static FORCE_INLINE int32_t tLDataIterCmprFn(const SRBTreeNode *p1, const SRBTreeNode *p2) { SLDataIter *pIter1 = (SLDataIter *)(((uint8_t *)p1) - offsetof(SLDataIter, node)); SLDataIter *pIter2 = (SLDataIter *)(((uint8_t *)p2) - offsetof(SLDataIter, node)); TSDBKEY key1 = TSDBROW_KEY(&pIter1->rInfo.row); TSDBKEY key2 = TSDBROW_KEY(&pIter2->rInfo.row); if (key1.ts < key2.ts) { return -1; } else if (key1.ts > key2.ts) { return 1; } else { if (key1.version < key2.version) { return -1; } else if (key1.version > key2.version) { return 1; } else { return 0; } } } static FORCE_INLINE int32_t tLDataIterDescCmprFn(const SRBTreeNode *p1, const SRBTreeNode *p2) { return -1 * tLDataIterCmprFn(p1, p2); } int32_t tMergeTreeOpen(SMergeTree *pMTree, int8_t backward, SDataFReader *pFReader, uint64_t suid, uint64_t uid, STimeWindow *pTimeWindow, SVersionRange *pVerRange, SSttBlockLoadInfo *pBlockLoadInfo, bool destroyLoadInfo, const char *idStr, bool strictTimeRange, SLDataIter *pLDataIter) { int32_t code = TSDB_CODE_SUCCESS; pMTree->backward = backward; pMTree->pIter = NULL; pMTree->idStr = idStr; if (!pMTree->backward) { // asc tRBTreeCreate(&pMTree->rbt, tLDataIterCmprFn); } else { // desc tRBTreeCreate(&pMTree->rbt, tLDataIterDescCmprFn); } pMTree->pLoadInfo = pBlockLoadInfo; pMTree->destroyLoadInfo = destroyLoadInfo; pMTree->ignoreEarlierTs = false; for (int32_t i = 0; i < pFReader->pSet->nSttF; ++i) { // open all last file memset(&pLDataIter[i], 0, sizeof(SLDataIter)); code = tLDataIterOpen(&pLDataIter[i], pFReader, i, pMTree->backward, suid, uid, pTimeWindow, pVerRange, &pMTree->pLoadInfo[i], pMTree->idStr, strictTimeRange); if (code != TSDB_CODE_SUCCESS) { goto _end; } bool hasVal = tLDataIterNextRow(&pLDataIter[i], pMTree->idStr); if (hasVal) { tMergeTreeAddIter(pMTree, &pLDataIter[i]); } else { if (!pMTree->ignoreEarlierTs) { pMTree->ignoreEarlierTs = pLDataIter[i].ignoreEarlierTs; } } } return code; _end: tMergeTreeClose(pMTree); return code; } int32_t tMergeTreeOpen2(SMergeTree *pMTree, SMergeTreeConf *pConf) { int32_t code = TSDB_CODE_SUCCESS; pMTree->pIter = NULL; pMTree->backward = pConf->backward; pMTree->idStr = pConf->idstr; if (!pMTree->backward) { // asc tRBTreeCreate(&pMTree->rbt, tLDataIterCmprFn); } else { // desc tRBTreeCreate(&pMTree->rbt, tLDataIterDescCmprFn); } pMTree->ignoreEarlierTs = false; int32_t size = ((STFileSet *)pConf->pCurrentFileset)->lvlArr->size; if (size == 0) { goto _end; } // add the list/iter placeholder while (taosArrayGetSize(pConf->pSttFileBlockIterArray) < size) { SArray *pList = taosArrayInit(4, POINTER_BYTES); taosArrayPush(pConf->pSttFileBlockIterArray, &pList); } for (int32_t j = 0; j < size; ++j) { SSttLvl *pSttLevel = ((STFileSet *)pConf->pCurrentFileset)->lvlArr->data[j]; ASSERT(pSttLevel->level == j); SArray *pList = taosArrayGetP(pConf->pSttFileBlockIterArray, j); int32_t numOfIter = taosArrayGetSize(pList); if (numOfIter < TARRAY2_SIZE(pSttLevel->fobjArr)) { int32_t inc = TARRAY2_SIZE(pSttLevel->fobjArr) - numOfIter; for (int32_t k = 0; k < inc; ++k) { SLDataIter *pIter = taosMemoryCalloc(1, sizeof(SLDataIter)); taosArrayPush(pList, &pIter); } } for (int32_t i = 0; i < TARRAY2_SIZE(pSttLevel->fobjArr); ++i) { // open all last file SLDataIter *pIter = taosArrayGetP(pList, i); SSttFileReader *pSttFileReader = pIter->pReader; SSttBlockLoadInfo *pLoadInfo = pIter->pBlockLoadInfo; // open stt file reader if not if (pSttFileReader == NULL) { SSttFileReaderConfig conf = {.tsdb = pConf->pTsdb, .szPage = pConf->pTsdb->pVnode->config.tsdbPageSize}; conf.file[0] = *pSttLevel->fobjArr->data[i]->f; code = tsdbSttFileReaderOpen(pSttLevel->fobjArr->data[i]->fname, &conf, &pSttFileReader); if (code != TSDB_CODE_SUCCESS) { return code; } } if (pLoadInfo == NULL) { pLoadInfo = tCreateOneLastBlockLoadInfo(pConf->pSchema, pConf->pCols, pConf->numOfCols); } memset(pIter, 0, sizeof(SLDataIter)); code = tLDataIterOpen2(pIter, pSttFileReader, i, pMTree->backward, pConf->suid, pConf->uid, &pConf->timewindow, &pConf->verRange, pLoadInfo, pMTree->idStr, pConf->strictTimeRange, pConf->loadTombFn, pConf->pReader); if (code != TSDB_CODE_SUCCESS) { goto _end; } bool hasVal = tLDataIterNextRow(pIter, pMTree->idStr); if (hasVal) { tMergeTreeAddIter(pMTree, pIter); } else { if (!pMTree->ignoreEarlierTs) { pMTree->ignoreEarlierTs = pIter->ignoreEarlierTs; } } } } return code; _end: tMergeTreeClose(pMTree); return code; } void tMergeTreeAddIter(SMergeTree *pMTree, SLDataIter *pIter) { tRBTreePut(&pMTree->rbt, (SRBTreeNode *)pIter); } bool tMergeTreeIgnoreEarlierTs(SMergeTree *pMTree) { return pMTree->ignoreEarlierTs; } bool tMergeTreeNext(SMergeTree *pMTree) { int32_t code = TSDB_CODE_SUCCESS; if (pMTree->pIter) { SLDataIter *pIter = pMTree->pIter; bool hasVal = tLDataIterNextRow(pIter, pMTree->idStr); if (!hasVal) { pMTree->pIter = NULL; } // compare with min in RB Tree pIter = (SLDataIter *)tRBTreeMin(&pMTree->rbt); if (pMTree->pIter && pIter) { int32_t c = pMTree->rbt.cmprFn(&pMTree->pIter->node, &pIter->node); if (c > 0) { tRBTreePut(&pMTree->rbt, (SRBTreeNode *)pMTree->pIter); pMTree->pIter = NULL; } else { ASSERT(c); } } } if (pMTree->pIter == NULL) { pMTree->pIter = (SLDataIter *)tRBTreeMin(&pMTree->rbt); if (pMTree->pIter) { tRBTreeDrop(&pMTree->rbt, (SRBTreeNode *)pMTree->pIter); } } return pMTree->pIter != NULL; } void tMergeTreeClose(SMergeTree *pMTree) { pMTree->pIter = NULL; if (pMTree->destroyLoadInfo) { pMTree->pLoadInfo = destroyLastBlockLoadInfo(pMTree->pLoadInfo); pMTree->destroyLoadInfo = false; } }