/* * 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 "parInsertData.h" #include "catalog.h" #include "parInt.h" #include "parUtil.h" #include "querynodes.h" #include "tRealloc.h" #define IS_RAW_PAYLOAD(t) \ (((int)(t)) == PAYLOAD_TYPE_RAW) // 0: K-V payload for non-prepare insert, 1: rawPayload for prepare insert typedef struct SBlockKeyTuple { TSKEY skey; void* payloadAddr; int16_t index; } SBlockKeyTuple; typedef struct SBlockKeyInfo { int32_t maxBytesAlloc; SBlockKeyTuple* pKeyTuple; } SBlockKeyInfo; typedef struct { int32_t index; SArray* rowArray; // array of merged rows(mem allocated by tRealloc/free by tFree) STSchema* pSchema; int64_t tbUid; // suid for child table, uid for normal table } SBlockRowMerger; static FORCE_INLINE void tdResetSBlockRowMerger(SBlockRowMerger* pMerger) { if (pMerger) { pMerger->index = -1; } } static void tdFreeSBlockRowMerger(SBlockRowMerger* pMerger) { if (pMerger) { int32_t size = taosArrayGetSize(pMerger->rowArray); for (int32_t i = 0; i < size; ++i) { tFree(*(void**)taosArrayGet(pMerger->rowArray, i)); } taosArrayDestroy(pMerger->rowArray); taosMemoryFreeClear(pMerger->pSchema); taosMemoryFree(pMerger); } } static int32_t rowDataCompar(const void* lhs, const void* rhs) { TSKEY left = *(TSKEY*)lhs; TSKEY right = *(TSKEY*)rhs; if (left == right) { return 0; } else { return left > right ? 1 : -1; } } static int32_t rowDataComparStable(const void* lhs, const void* rhs) { TSKEY left = *(TSKEY*)lhs; TSKEY right = *(TSKEY*)rhs; if (left == right) { return ((SBlockKeyTuple*)lhs)->index - ((SBlockKeyTuple*)rhs)->index; } else { return left > right ? 1 : -1; } } void setBoundColumnInfo(SParsedDataColInfo* pColList, SSchema* pSchema, col_id_t numOfCols) { pColList->numOfCols = numOfCols; pColList->numOfBound = numOfCols; pColList->orderStatus = ORDER_STATUS_ORDERED; // default is ORDERED for non-bound mode pColList->boundColumns = taosMemoryCalloc(pColList->numOfCols, sizeof(col_id_t)); pColList->cols = taosMemoryCalloc(pColList->numOfCols, sizeof(SBoundColumn)); pColList->colIdxInfo = NULL; pColList->flen = 0; pColList->allNullLen = 0; int32_t nVar = 0; for (int32_t i = 0; i < pColList->numOfCols; ++i) { uint8_t type = pSchema[i].type; if (i > 0) { pColList->cols[i].offset = pColList->cols[i - 1].offset + pSchema[i - 1].bytes; pColList->cols[i].toffset = pColList->flen; } pColList->flen += TYPE_BYTES[type]; switch (type) { case TSDB_DATA_TYPE_BINARY: pColList->allNullLen += (VARSTR_HEADER_SIZE + CHAR_BYTES); ++nVar; break; case TSDB_DATA_TYPE_NCHAR: pColList->allNullLen += (VARSTR_HEADER_SIZE + TSDB_NCHAR_SIZE); ++nVar; break; default: break; } pColList->boundColumns[i] = i; } pColList->allNullLen += pColList->flen; pColList->boundNullLen = pColList->allNullLen; // default set allNullLen pColList->extendedVarLen = (uint16_t)(nVar * sizeof(VarDataOffsetT)); } int32_t schemaIdxCompar(const void* lhs, const void* rhs) { uint16_t left = *(uint16_t*)lhs; uint16_t right = *(uint16_t*)rhs; if (left == right) { return 0; } else { return left > right ? 1 : -1; } } int32_t boundIdxCompar(const void* lhs, const void* rhs) { uint16_t left = *(uint16_t*)POINTER_SHIFT(lhs, sizeof(uint16_t)); uint16_t right = *(uint16_t*)POINTER_SHIFT(rhs, sizeof(uint16_t)); if (left == right) { return 0; } else { return left > right ? 1 : -1; } } void destroyBoundColumnInfo(void* pBoundInfo) { if (NULL == pBoundInfo) { return; } SParsedDataColInfo* pColList = (SParsedDataColInfo*)pBoundInfo; taosMemoryFreeClear(pColList->boundColumns); taosMemoryFreeClear(pColList->cols); taosMemoryFreeClear(pColList->colIdxInfo); } static int32_t createDataBlock(size_t defaultSize, int32_t rowSize, int32_t startOffset, STableMeta* pTableMeta, STableDataBlocks** dataBlocks) { STableDataBlocks* dataBuf = (STableDataBlocks*)taosMemoryCalloc(1, sizeof(STableDataBlocks)); if (dataBuf == NULL) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } dataBuf->nAllocSize = (uint32_t)defaultSize; dataBuf->headerSize = startOffset; // the header size will always be the startOffset value, reserved for the subumit block header if (dataBuf->nAllocSize <= dataBuf->headerSize) { dataBuf->nAllocSize = dataBuf->headerSize * 2; } dataBuf->pData = taosMemoryMalloc(dataBuf->nAllocSize); if (dataBuf->pData == NULL) { taosMemoryFreeClear(dataBuf); return TSDB_CODE_TSC_OUT_OF_MEMORY; } memset(dataBuf->pData, 0, sizeof(SSubmitBlk)); dataBuf->pTableMeta = tableMetaDup(pTableMeta); SParsedDataColInfo* pColInfo = &dataBuf->boundColumnInfo; SSchema* pSchema = getTableColumnSchema(dataBuf->pTableMeta); setBoundColumnInfo(pColInfo, pSchema, dataBuf->pTableMeta->tableInfo.numOfColumns); dataBuf->ordered = true; dataBuf->prevTS = INT64_MIN; dataBuf->rowSize = rowSize; dataBuf->size = startOffset; dataBuf->vgId = dataBuf->pTableMeta->vgId; assert(defaultSize > 0 && pTableMeta != NULL && dataBuf->pTableMeta != NULL); *dataBlocks = dataBuf; return TSDB_CODE_SUCCESS; } int32_t buildCreateTbMsg(STableDataBlocks* pBlocks, SVCreateTbReq* pCreateTbReq) { SEncoder coder = {0}; char* pBuf; int32_t len; int32_t ret = 0; tEncodeSize(tEncodeSVCreateTbReq, pCreateTbReq, len, ret); if (pBlocks->nAllocSize - pBlocks->size < len) { pBlocks->nAllocSize += len + pBlocks->rowSize; char* pTmp = taosMemoryRealloc(pBlocks->pData, pBlocks->nAllocSize); if (pTmp != NULL) { pBlocks->pData = pTmp; memset(pBlocks->pData + pBlocks->size, 0, pBlocks->nAllocSize - pBlocks->size); } else { pBlocks->nAllocSize -= len + pBlocks->rowSize; return TSDB_CODE_TSC_OUT_OF_MEMORY; } } pBuf = pBlocks->pData + pBlocks->size; tEncoderInit(&coder, pBuf, len); int32_t code = tEncodeSVCreateTbReq(&coder, pCreateTbReq); tEncoderClear(&coder); pBlocks->size += len; pBlocks->createTbReqLen = len; return code; } int32_t getDataBlockFromList(SHashObj* pHashList, void* id, int32_t idLen, int32_t size, int32_t startOffset, int32_t rowSize, STableMeta* pTableMeta, STableDataBlocks** dataBlocks, SArray* pBlockList, SVCreateTbReq* pCreateTbReq) { *dataBlocks = NULL; STableDataBlocks** t1 = (STableDataBlocks**)taosHashGet(pHashList, (const char*)id, idLen); if (t1 != NULL) { *dataBlocks = *t1; } if (*dataBlocks == NULL) { int32_t ret = createDataBlock((size_t)size, rowSize, startOffset, pTableMeta, dataBlocks); if (ret != TSDB_CODE_SUCCESS) { return ret; } if (NULL != pCreateTbReq && NULL != pCreateTbReq->ctb.pTag) { ret = buildCreateTbMsg(*dataBlocks, pCreateTbReq); if (ret != TSDB_CODE_SUCCESS) { return ret; } } taosHashPut(pHashList, id, idLen, dataBlocks, POINTER_BYTES); if (pBlockList) { taosArrayPush(pBlockList, dataBlocks); } } return TSDB_CODE_SUCCESS; } static int32_t getRowExpandSize(STableMeta* pTableMeta) { int32_t result = TD_ROW_HEAD_LEN - sizeof(TSKEY); int32_t columns = getNumOfColumns(pTableMeta); SSchema* pSchema = getTableColumnSchema(pTableMeta); for (int32_t i = 0; i < columns; ++i) { if (IS_VAR_DATA_TYPE((pSchema + i)->type)) { result += TYPE_BYTES[TSDB_DATA_TYPE_BINARY]; } } result += (int32_t)TD_BITMAP_BYTES(columns - 1); return result; } static void destroyDataBlock(STableDataBlocks* pDataBlock) { if (pDataBlock == NULL) { return; } taosMemoryFreeClear(pDataBlock->pData); // if (!pDataBlock->cloned) { // free the refcount for metermeta taosMemoryFreeClear(pDataBlock->pTableMeta); destroyBoundColumnInfo(&pDataBlock->boundColumnInfo); // } taosMemoryFreeClear(pDataBlock); } void destroyBlockArrayList(SArray* pDataBlockList) { if (pDataBlockList == NULL) { return; } size_t size = taosArrayGetSize(pDataBlockList); for (int32_t i = 0; i < size; i++) { void* p = taosArrayGetP(pDataBlockList, i); destroyDataBlock(p); } taosArrayDestroy(pDataBlockList); } void destroyBlockHashmap(SHashObj* pDataBlockHash) { if (pDataBlockHash == NULL) { return; } void** p1 = taosHashIterate(pDataBlockHash, NULL); while (p1) { STableDataBlocks* pBlocks = *p1; destroyDataBlock(pBlocks); p1 = taosHashIterate(pDataBlockHash, p1); } taosHashCleanup(pDataBlockHash); } // data block is disordered, sort it in ascending order void sortRemoveDataBlockDupRowsRaw(STableDataBlocks* dataBuf) { SSubmitBlk* pBlocks = (SSubmitBlk*)dataBuf->pData; // size is less than the total size, since duplicated rows may be removed yet. assert(pBlocks->numOfRows * dataBuf->rowSize + sizeof(SSubmitBlk) == dataBuf->size); if (!dataBuf->ordered) { char* pBlockData = pBlocks->data; // todo. qsort is unstable, if timestamp is same, should get the last one taosSort(pBlockData, pBlocks->numOfRows, dataBuf->rowSize, rowDataCompar); int32_t i = 0; int32_t j = 1; // delete rows with timestamp conflicts while (j < pBlocks->numOfRows) { TSKEY ti = *(TSKEY*)(pBlockData + dataBuf->rowSize * i); TSKEY tj = *(TSKEY*)(pBlockData + dataBuf->rowSize * j); if (ti == tj) { ++j; continue; } int32_t nextPos = (++i); if (nextPos != j) { memmove(pBlockData + dataBuf->rowSize * nextPos, pBlockData + dataBuf->rowSize * j, dataBuf->rowSize); } ++j; } dataBuf->ordered = true; pBlocks->numOfRows = i + 1; dataBuf->size = sizeof(SSubmitBlk) + dataBuf->rowSize * pBlocks->numOfRows; } dataBuf->prevTS = INT64_MIN; } // data block is disordered, sort it in ascending order static int sortRemoveDataBlockDupRows(STableDataBlocks* dataBuf, SBlockKeyInfo* pBlkKeyInfo) { SSubmitBlk* pBlocks = (SSubmitBlk*)dataBuf->pData; int16_t nRows = pBlocks->numOfRows; // size is less than the total size, since duplicated rows may be removed yet. // allocate memory size_t nAlloc = nRows * sizeof(SBlockKeyTuple); if (pBlkKeyInfo->pKeyTuple == NULL || pBlkKeyInfo->maxBytesAlloc < nAlloc) { char* tmp = taosMemoryRealloc(pBlkKeyInfo->pKeyTuple, nAlloc); if (tmp == NULL) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } pBlkKeyInfo->pKeyTuple = (SBlockKeyTuple*)tmp; pBlkKeyInfo->maxBytesAlloc = (int32_t)nAlloc; } memset(pBlkKeyInfo->pKeyTuple, 0, nAlloc); int32_t extendedRowSize = getExtendedRowSize(dataBuf); SBlockKeyTuple* pBlkKeyTuple = pBlkKeyInfo->pKeyTuple; char* pBlockData = pBlocks->data + pBlocks->schemaLen; int n = 0; while (n < nRows) { pBlkKeyTuple->skey = TD_ROW_KEY((STSRow*)pBlockData); pBlkKeyTuple->payloadAddr = pBlockData; pBlkKeyTuple->index = n; // next loop pBlockData += extendedRowSize; ++pBlkKeyTuple; ++n; } if (!dataBuf->ordered) { pBlkKeyTuple = pBlkKeyInfo->pKeyTuple; // todo. qsort is unstable, if timestamp is same, should get the last one taosSort(pBlkKeyTuple, nRows, sizeof(SBlockKeyTuple), rowDataComparStable); pBlkKeyTuple = pBlkKeyInfo->pKeyTuple; int32_t i = 0; int32_t j = 1; while (j < nRows) { TSKEY ti = (pBlkKeyTuple + i)->skey; TSKEY tj = (pBlkKeyTuple + j)->skey; if (ti == tj) { ++j; continue; } int32_t nextPos = (++i); if (nextPos != j) { memmove(pBlkKeyTuple + nextPos, pBlkKeyTuple + j, sizeof(SBlockKeyTuple)); } ++j; } dataBuf->ordered = true; pBlocks->numOfRows = i + 1; } dataBuf->size = sizeof(SSubmitBlk) + pBlocks->numOfRows * extendedRowSize; dataBuf->prevTS = INT64_MIN; return 0; } static void* tdGetCurRowFromBlockMerger(SBlockRowMerger* pBlkRowMerger) { if (pBlkRowMerger && (pBlkRowMerger->index >= 0)) { ASSERT(pBlkRowMerger->index < taosArrayGetSize(pBlkRowMerger->rowArray)); return *(void**)taosArrayGet(pBlkRowMerger->rowArray, pBlkRowMerger->index); } return NULL; } static int32_t tdBlockRowMerge(STableMeta* pTableMeta, SBlockKeyTuple* pEndKeyTp, int32_t nDupRows, SBlockRowMerger** pBlkRowMerger, int32_t rowSize) { ASSERT(nDupRows > 1); SBlockKeyTuple* pStartKeyTp = pEndKeyTp - (nDupRows - 1); ASSERT(pStartKeyTp->skey == pEndKeyTp->skey); // TODO: optimization if end row is all normal #if 0 STSRow* pEndRow = (STSRow*)pEndKeyTp->payloadAddr; if(isNormal(pEndRow)) { // set the end row if it is normal and return directly pStartKeyTp->payloadAddr = pEndKeyTp->payloadAddr; return TSDB_CODE_SUCCESS; } #endif if (!(*pBlkRowMerger)) { (*pBlkRowMerger) = taosMemoryCalloc(1, sizeof(**pBlkRowMerger)); if (!(*pBlkRowMerger)) { terrno = TSDB_CODE_OUT_OF_MEMORY; return TSDB_CODE_FAILED; } (*pBlkRowMerger)->index = -1; if (!(*pBlkRowMerger)->rowArray) { (*pBlkRowMerger)->rowArray = taosArrayInit(1, sizeof(void*)); if (!(*pBlkRowMerger)->rowArray) { terrno = TSDB_CODE_OUT_OF_MEMORY; return TSDB_CODE_FAILED; } } } if ((*pBlkRowMerger)->pSchema) { if ((*pBlkRowMerger)->pSchema->version != pTableMeta->sversion) { taosMemoryFreeClear((*pBlkRowMerger)->pSchema); } else { if ((*pBlkRowMerger)->tbUid != (pTableMeta->suid > 0 ? pTableMeta->suid : pTableMeta->uid)) { taosMemoryFreeClear((*pBlkRowMerger)->pSchema); } } } if (!(*pBlkRowMerger)->pSchema) { (*pBlkRowMerger)->pSchema = tdGetSTSChemaFromSSChema(pTableMeta->schema, pTableMeta->tableInfo.numOfColumns, pTableMeta->sversion); if (!(*pBlkRowMerger)->pSchema) { terrno = TSDB_CODE_OUT_OF_MEMORY; return TSDB_CODE_FAILED; } (*pBlkRowMerger)->tbUid = pTableMeta->suid > 0 ? pTableMeta->suid : pTableMeta->uid; } void* pDestRow = NULL; ++((*pBlkRowMerger)->index); if ((*pBlkRowMerger)->index < taosArrayGetSize((*pBlkRowMerger)->rowArray)) { void** pAlloc = (void**)taosArrayGet((*pBlkRowMerger)->rowArray, (*pBlkRowMerger)->index); if (tRealloc((uint8_t**)pAlloc, rowSize) != 0) { return TSDB_CODE_FAILED; } pDestRow = *pAlloc; } else { if (tRealloc((uint8_t**)&pDestRow, rowSize) != 0) { return TSDB_CODE_FAILED; } taosArrayPush((*pBlkRowMerger)->rowArray, &pDestRow); } // merge rows to pDestRow STSchema* pSchema = (*pBlkRowMerger)->pSchema; SArray* pArray = taosArrayInit(pSchema->numOfCols, sizeof(SColVal)); for (int32_t i = 0; i < pSchema->numOfCols; ++i) { SColVal colVal = {0}; for (int32_t j = 0; j < nDupRows; ++j) { tTSRowGetVal((pEndKeyTp - j)->payloadAddr, pSchema, i, &colVal); if (!COL_VAL_IS_NONE(&colVal)) { break; } } taosArrayPush(pArray, &colVal); } if (tdSTSRowNew(pArray, pSchema, (STSRow**)&pDestRow) < 0) { taosArrayDestroy(pArray); return TSDB_CODE_FAILED; } taosArrayDestroy(pArray); return TSDB_CODE_SUCCESS; } // data block is disordered, sort it in ascending order, and merge dup rows if exists static int sortMergeDataBlockDupRows(STableDataBlocks* dataBuf, SBlockKeyInfo* pBlkKeyInfo, SBlockRowMerger** ppBlkRowMerger) { SSubmitBlk* pBlocks = (SSubmitBlk*)dataBuf->pData; STableMeta* pTableMeta = dataBuf->pTableMeta; int32_t nRows = pBlocks->numOfRows; // size is less than the total size, since duplicated rows may be removed. // allocate memory size_t nAlloc = nRows * sizeof(SBlockKeyTuple); if (pBlkKeyInfo->pKeyTuple == NULL || pBlkKeyInfo->maxBytesAlloc < nAlloc) { char* tmp = taosMemoryRealloc(pBlkKeyInfo->pKeyTuple, nAlloc); if (tmp == NULL) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } pBlkKeyInfo->pKeyTuple = (SBlockKeyTuple*)tmp; pBlkKeyInfo->maxBytesAlloc = (int32_t)nAlloc; } memset(pBlkKeyInfo->pKeyTuple, 0, nAlloc); tdResetSBlockRowMerger(*ppBlkRowMerger); int32_t extendedRowSize = getExtendedRowSize(dataBuf); SBlockKeyTuple* pBlkKeyTuple = pBlkKeyInfo->pKeyTuple; char* pBlockData = pBlocks->data + pBlocks->schemaLen; int32_t n = 0; while (n < nRows) { pBlkKeyTuple->skey = TD_ROW_KEY((STSRow*)pBlockData); pBlkKeyTuple->payloadAddr = pBlockData; pBlkKeyTuple->index = n; // next loop pBlockData += extendedRowSize; ++pBlkKeyTuple; ++n; } if (!dataBuf->ordered) { pBlkKeyTuple = pBlkKeyInfo->pKeyTuple; taosSort(pBlkKeyTuple, nRows, sizeof(SBlockKeyTuple), rowDataComparStable); pBlkKeyTuple = pBlkKeyInfo->pKeyTuple; bool hasDup = false; int32_t nextPos = 0; int32_t i = 0; int32_t j = 1; while (j < nRows) { TSKEY ti = (pBlkKeyTuple + i)->skey; TSKEY tj = (pBlkKeyTuple + j)->skey; if (ti == tj) { ++j; continue; } if ((j - i) > 1) { if (tdBlockRowMerge(pTableMeta, (pBlkKeyTuple + j - 1), j - i, ppBlkRowMerger, extendedRowSize) < 0) { return TSDB_CODE_FAILED; } (pBlkKeyTuple + nextPos)->payloadAddr = tdGetCurRowFromBlockMerger(*ppBlkRowMerger); if (!hasDup) { hasDup = true; } i = j; } else { if (hasDup) { memmove(pBlkKeyTuple + nextPos, pBlkKeyTuple + i, sizeof(SBlockKeyTuple)); } ++i; } ++nextPos; ++j; } if ((j - i) > 1) { ASSERT((pBlkKeyTuple + i)->skey == (pBlkKeyTuple + j - 1)->skey); if (tdBlockRowMerge(pTableMeta, (pBlkKeyTuple + j - 1), j - i, ppBlkRowMerger, extendedRowSize) < 0) { return TSDB_CODE_FAILED; } (pBlkKeyTuple + nextPos)->payloadAddr = tdGetCurRowFromBlockMerger(*ppBlkRowMerger); } else if (hasDup) { memmove(pBlkKeyTuple + nextPos, pBlkKeyTuple + i, sizeof(SBlockKeyTuple)); } dataBuf->ordered = true; pBlocks->numOfRows = nextPos + 1; } dataBuf->size = sizeof(SSubmitBlk) + pBlocks->numOfRows * extendedRowSize; dataBuf->prevTS = INT64_MIN; return TSDB_CODE_SUCCESS; } // Erase the empty space reserved for binary data static int trimDataBlock(void* pDataBlock, STableDataBlocks* pTableDataBlock, SBlockKeyTuple* blkKeyTuple, bool isRawPayload) { // TODO: optimize this function, handle the case while binary is not presented STableMeta* pTableMeta = pTableDataBlock->pTableMeta; STableComInfo tinfo = getTableInfo(pTableMeta); SSchema* pSchema = getTableColumnSchema(pTableMeta); int32_t nonDataLen = sizeof(SSubmitBlk) + pTableDataBlock->createTbReqLen; SSubmitBlk* pBlock = pDataBlock; memcpy(pDataBlock, pTableDataBlock->pData, nonDataLen); pDataBlock = (char*)pDataBlock + nonDataLen; int32_t flen = 0; // original total length of row if (isRawPayload) { for (int32_t j = 0; j < tinfo.numOfColumns; ++j) { flen += TYPE_BYTES[pSchema[j].type]; } } pBlock->schemaLen = pTableDataBlock->createTbReqLen; char* p = pTableDataBlock->pData + nonDataLen; pBlock->dataLen = 0; int32_t numOfRows = pBlock->numOfRows; if (isRawPayload) { SRowBuilder builder = {0}; tdSRowInit(&builder, pTableMeta->sversion); tdSRowSetInfo(&builder, getNumOfColumns(pTableMeta), -1, flen); for (int32_t i = 0; i < numOfRows; ++i) { tdSRowResetBuf(&builder, pDataBlock); int toffset = 0; for (int32_t j = 0; j < tinfo.numOfColumns; ++j) { int8_t colType = pSchema[j].type; uint8_t valType = isNull(p, colType) ? TD_VTYPE_NULL : TD_VTYPE_NORM; tdAppendColValToRow(&builder, pSchema[j].colId, colType, valType, p, true, toffset, j); toffset += TYPE_BYTES[colType]; p += pSchema[j].bytes; } tdSRowEnd(&builder); int32_t rowLen = TD_ROW_LEN((STSRow*)pDataBlock); pDataBlock = (char*)pDataBlock + rowLen; pBlock->dataLen += rowLen; } } else { for (int32_t i = 0; i < numOfRows; ++i) { void* payload = (blkKeyTuple + i)->payloadAddr; TDRowLenT rowTLen = TD_ROW_LEN((STSRow*)payload); memcpy(pDataBlock, payload, rowTLen); pDataBlock = POINTER_SHIFT(pDataBlock, rowTLen); pBlock->dataLen += rowTLen; } } return pBlock->dataLen + pBlock->schemaLen; } int32_t mergeTableDataBlocks(SHashObj* pHashObj, uint8_t payloadType, SArray** pVgDataBlocks) { const int INSERT_HEAD_SIZE = sizeof(SSubmitReq); int code = 0; bool isRawPayload = IS_RAW_PAYLOAD(payloadType); SHashObj* pVnodeDataBlockHashList = taosHashInit(128, taosGetDefaultHashFunction(TSDB_DATA_TYPE_INT), true, false); SArray* pVnodeDataBlockList = taosArrayInit(8, POINTER_BYTES); STableDataBlocks** p = taosHashIterate(pHashObj, NULL); STableDataBlocks* pOneTableBlock = *p; SBlockKeyInfo blkKeyInfo = {0}; // share by pOneTableBlock SBlockRowMerger* pBlkRowMerger = NULL; while (pOneTableBlock) { SSubmitBlk* pBlocks = (SSubmitBlk*)pOneTableBlock->pData; if (pBlocks->numOfRows > 0) { STableDataBlocks* dataBuf = NULL; pOneTableBlock->pTableMeta->vgId = pOneTableBlock->vgId; // for schemaless, restore origin vgId int32_t ret = getDataBlockFromList(pVnodeDataBlockHashList, &pOneTableBlock->vgId, sizeof(pOneTableBlock->vgId), TSDB_PAYLOAD_SIZE, INSERT_HEAD_SIZE, 0, pOneTableBlock->pTableMeta, &dataBuf, pVnodeDataBlockList, NULL); if (ret != TSDB_CODE_SUCCESS) { tdFreeSBlockRowMerger(pBlkRowMerger); taosHashCleanup(pVnodeDataBlockHashList); destroyBlockArrayList(pVnodeDataBlockList); taosMemoryFreeClear(blkKeyInfo.pKeyTuple); return ret; } ASSERT(pOneTableBlock->pTableMeta->tableInfo.rowSize > 0); // the maximum expanded size in byte when a row-wise data is converted to SDataRow format int32_t expandSize = isRawPayload ? getRowExpandSize(pOneTableBlock->pTableMeta) : 0; int64_t destSize = dataBuf->size + pOneTableBlock->size + pBlocks->numOfRows * expandSize + sizeof(STColumn) * getNumOfColumns(pOneTableBlock->pTableMeta) + pOneTableBlock->createTbReqLen; if (dataBuf->nAllocSize < destSize) { dataBuf->nAllocSize = (uint32_t)(destSize * 1.5); char* tmp = taosMemoryRealloc(dataBuf->pData, dataBuf->nAllocSize); if (tmp != NULL) { dataBuf->pData = tmp; } else { // failed to allocate memory, free already allocated memory and return error code tdFreeSBlockRowMerger(pBlkRowMerger); taosHashCleanup(pVnodeDataBlockHashList); destroyBlockArrayList(pVnodeDataBlockList); taosMemoryFreeClear(dataBuf->pData); taosMemoryFreeClear(blkKeyInfo.pKeyTuple); return TSDB_CODE_TSC_OUT_OF_MEMORY; } } if (isRawPayload) { sortRemoveDataBlockDupRowsRaw(pOneTableBlock); } else { if ((code = sortMergeDataBlockDupRows(pOneTableBlock, &blkKeyInfo, &pBlkRowMerger)) != 0) { tdFreeSBlockRowMerger(pBlkRowMerger); taosHashCleanup(pVnodeDataBlockHashList); destroyBlockArrayList(pVnodeDataBlockList); taosMemoryFreeClear(dataBuf->pData); taosMemoryFreeClear(blkKeyInfo.pKeyTuple); return code; } ASSERT(blkKeyInfo.pKeyTuple != NULL && pBlocks->numOfRows > 0); } // erase the empty space reserved for binary data int32_t finalLen = trimDataBlock(dataBuf->pData + dataBuf->size, pOneTableBlock, blkKeyInfo.pKeyTuple, isRawPayload); dataBuf->size += (finalLen + sizeof(SSubmitBlk)); assert(dataBuf->size <= dataBuf->nAllocSize); dataBuf->numOfTables += 1; } p = taosHashIterate(pHashObj, p); if (p == NULL) { break; } pOneTableBlock = *p; } // free the table data blocks; tdFreeSBlockRowMerger(pBlkRowMerger); taosHashCleanup(pVnodeDataBlockHashList); taosMemoryFreeClear(blkKeyInfo.pKeyTuple); *pVgDataBlocks = pVnodeDataBlockList; return TSDB_CODE_SUCCESS; } int32_t allocateMemForSize(STableDataBlocks* pDataBlock, int32_t allSize) { size_t remain = pDataBlock->nAllocSize - pDataBlock->size; uint32_t nAllocSizeOld = pDataBlock->nAllocSize; // expand the allocated size if (remain < allSize) { pDataBlock->nAllocSize = (pDataBlock->size + allSize) * 1.5; char* tmp = taosMemoryRealloc(pDataBlock->pData, (size_t)pDataBlock->nAllocSize); if (tmp != NULL) { pDataBlock->pData = tmp; memset(pDataBlock->pData + pDataBlock->size, 0, pDataBlock->nAllocSize - pDataBlock->size); } else { // do nothing, if allocate more memory failed pDataBlock->nAllocSize = nAllocSizeOld; return TSDB_CODE_TSC_OUT_OF_MEMORY; } } return TSDB_CODE_SUCCESS; } int32_t allocateMemIfNeed(STableDataBlocks* pDataBlock, int32_t rowSize, int32_t* numOfRows) { size_t remain = pDataBlock->nAllocSize - pDataBlock->size; const int factor = 5; uint32_t nAllocSizeOld = pDataBlock->nAllocSize; // expand the allocated size if (remain < rowSize * factor) { while (remain < rowSize * factor) { pDataBlock->nAllocSize = (uint32_t)(pDataBlock->nAllocSize * 1.5); remain = pDataBlock->nAllocSize - pDataBlock->size; } char* tmp = taosMemoryRealloc(pDataBlock->pData, (size_t)pDataBlock->nAllocSize); if (tmp != NULL) { pDataBlock->pData = tmp; memset(pDataBlock->pData + pDataBlock->size, 0, pDataBlock->nAllocSize - pDataBlock->size); } else { // do nothing, if allocate more memory failed pDataBlock->nAllocSize = nAllocSizeOld; *numOfRows = (int32_t)(pDataBlock->nAllocSize - pDataBlock->headerSize) / rowSize; return TSDB_CODE_TSC_OUT_OF_MEMORY; } } *numOfRows = (int32_t)(pDataBlock->nAllocSize - pDataBlock->headerSize) / rowSize; return TSDB_CODE_SUCCESS; } int initRowBuilder(SRowBuilder* pBuilder, int16_t schemaVer, SParsedDataColInfo* pColInfo) { ASSERT(pColInfo->numOfCols > 0 && (pColInfo->numOfBound <= pColInfo->numOfCols)); tdSRowInit(pBuilder, schemaVer); tdSRowSetExtendedInfo(pBuilder, pColInfo->numOfCols, pColInfo->numOfBound, pColInfo->flen, pColInfo->allNullLen, pColInfo->boundNullLen); return TSDB_CODE_SUCCESS; } int32_t qResetStmtDataBlock(void* block, bool keepBuf) { STableDataBlocks* pBlock = (STableDataBlocks*)block; if (keepBuf) { taosMemoryFreeClear(pBlock->pData); pBlock->pData = taosMemoryMalloc(TSDB_PAYLOAD_SIZE); if (NULL == pBlock->pData) { return TSDB_CODE_OUT_OF_MEMORY; } memset(pBlock->pData, 0, sizeof(SSubmitBlk)); } else { pBlock->pData = NULL; } pBlock->ordered = true; pBlock->prevTS = INT64_MIN; pBlock->size = sizeof(SSubmitBlk); pBlock->tsSource = -1; pBlock->numOfTables = 1; pBlock->nAllocSize = TSDB_PAYLOAD_SIZE; pBlock->headerSize = pBlock->size; pBlock->createTbReqLen = 0; memset(&pBlock->rowBuilder, 0, sizeof(pBlock->rowBuilder)); return TSDB_CODE_SUCCESS; } int32_t qCloneStmtDataBlock(void** pDst, void* pSrc) { *pDst = taosMemoryMalloc(sizeof(STableDataBlocks)); if (NULL == *pDst) { return TSDB_CODE_OUT_OF_MEMORY; } memcpy(*pDst, pSrc, sizeof(STableDataBlocks)); ((STableDataBlocks*)(*pDst))->cloned = true; STableDataBlocks* pBlock = (STableDataBlocks*)(*pDst); if (pBlock->pTableMeta) { void* pNewMeta = taosMemoryMalloc(TABLE_META_SIZE(pBlock->pTableMeta)); if (NULL == pNewMeta) { taosMemoryFreeClear(*pDst); return TSDB_CODE_OUT_OF_MEMORY; } memcpy(pNewMeta, pBlock->pTableMeta, TABLE_META_SIZE(pBlock->pTableMeta)); pBlock->pTableMeta = pNewMeta; } return qResetStmtDataBlock(*pDst, false); } int32_t qRebuildStmtDataBlock(void** pDst, void* pSrc, uint64_t uid, int32_t vgId) { int32_t code = qCloneStmtDataBlock(pDst, pSrc); if (code) { return code; } STableDataBlocks* pBlock = (STableDataBlocks*)*pDst; pBlock->pData = taosMemoryMalloc(pBlock->nAllocSize); if (NULL == pBlock->pData) { qFreeStmtDataBlock(pBlock); return TSDB_CODE_OUT_OF_MEMORY; } pBlock->vgId = vgId; if (pBlock->pTableMeta) { pBlock->pTableMeta->uid = uid; pBlock->pTableMeta->vgId = vgId; } memset(pBlock->pData, 0, sizeof(SSubmitBlk)); return TSDB_CODE_SUCCESS; } STableMeta* qGetTableMetaInDataBlock(void* pDataBlock) { return ((STableDataBlocks*)pDataBlock)->pTableMeta; } void qFreeStmtDataBlock(void* pDataBlock) { if (pDataBlock == NULL) { return; } taosMemoryFreeClear(((STableDataBlocks*)pDataBlock)->pTableMeta); taosMemoryFreeClear(((STableDataBlocks*)pDataBlock)->pData); taosMemoryFreeClear(pDataBlock); } void qDestroyStmtDataBlock(void* pBlock) { if (pBlock == NULL) { return; } STableDataBlocks* pDataBlock = (STableDataBlocks*)pBlock; pDataBlock->cloned = false; destroyDataBlock(pDataBlock); }