/* * 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 "tdataformat.h" #include "ulog.h" #include "talgo.h" #include "tcoding.h" #include "wchar.h" #include "tarray.h" static void dataColSetNEleNull(SDataCol *pCol, int nEle); static void tdMergeTwoDataCols(SDataCols *target, SDataCols *src1, int *iter1, int limit1, SDataCols *src2, int *iter2, int limit2, int tRows, bool forceSetNull); int tdAllocMemForCol(SDataCol *pCol, int maxPoints) { int spaceNeeded = pCol->bytes * maxPoints; if(IS_VAR_DATA_TYPE(pCol->type)) { spaceNeeded += sizeof(VarDataOffsetT) * maxPoints; } if(pCol->spaceSize < spaceNeeded) { void* ptr = realloc(pCol->pData, spaceNeeded); if(ptr == NULL) { uDebug("malloc failure, size:%" PRId64 " failed, reason:%s", (int64_t)spaceNeeded, strerror(errno)); return -1; } else { pCol->pData = ptr; pCol->spaceSize = spaceNeeded; } } if(IS_VAR_DATA_TYPE(pCol->type)) { pCol->dataOff = POINTER_SHIFT(pCol->pData, pCol->bytes * maxPoints); } return 0; } /** * Duplicate the schema and return a new object */ STSchema *tdDupSchema(STSchema *pSchema) { int tlen = sizeof(STSchema) + sizeof(STColumn) * schemaNCols(pSchema); STSchema *tSchema = (STSchema *)malloc(tlen); if (tSchema == NULL) return NULL; memcpy((void *)tSchema, (void *)pSchema, tlen); return tSchema; } /** * Encode a schema to dst, and return the next pointer */ int tdEncodeSchema(void **buf, STSchema *pSchema) { int tlen = 0; tlen += taosEncodeFixedI32(buf, schemaVersion(pSchema)); tlen += taosEncodeFixedI32(buf, schemaNCols(pSchema)); for (int i = 0; i < schemaNCols(pSchema); i++) { STColumn *pCol = schemaColAt(pSchema, i); tlen += taosEncodeFixedI8(buf, colType(pCol)); tlen += taosEncodeFixedI16(buf, colColId(pCol)); tlen += taosEncodeFixedI16(buf, colBytes(pCol)); } return tlen; } /** * Decode a schema from a binary. */ void *tdDecodeSchema(void *buf, STSchema **pRSchema) { int version = 0; int numOfCols = 0; STSchemaBuilder schemaBuilder; buf = taosDecodeFixedI32(buf, &version); buf = taosDecodeFixedI32(buf, &numOfCols); if (tdInitTSchemaBuilder(&schemaBuilder, version) < 0) return NULL; for (int i = 0; i < numOfCols; i++) { int8_t type = 0; int16_t colId = 0; int16_t bytes = 0; buf = taosDecodeFixedI8(buf, &type); buf = taosDecodeFixedI16(buf, &colId); buf = taosDecodeFixedI16(buf, &bytes); if (tdAddColToSchema(&schemaBuilder, type, colId, bytes) < 0) { tdDestroyTSchemaBuilder(&schemaBuilder); return NULL; } } *pRSchema = tdGetSchemaFromBuilder(&schemaBuilder); tdDestroyTSchemaBuilder(&schemaBuilder); return buf; } int tdInitTSchemaBuilder(STSchemaBuilder *pBuilder, int32_t version) { if (pBuilder == NULL) return -1; pBuilder->tCols = 256; pBuilder->columns = (STColumn *)malloc(sizeof(STColumn) * pBuilder->tCols); if (pBuilder->columns == NULL) return -1; tdResetTSchemaBuilder(pBuilder, version); return 0; } void tdDestroyTSchemaBuilder(STSchemaBuilder *pBuilder) { if (pBuilder) { tfree(pBuilder->columns); } } void tdResetTSchemaBuilder(STSchemaBuilder *pBuilder, int32_t version) { pBuilder->nCols = 0; pBuilder->tlen = 0; pBuilder->flen = 0; pBuilder->vlen = 0; pBuilder->version = version; } int tdAddColToSchema(STSchemaBuilder *pBuilder, int8_t type, int16_t colId, int16_t bytes) { if (!isValidDataType(type)) return -1; if (pBuilder->nCols >= pBuilder->tCols) { pBuilder->tCols *= 2; STColumn* columns = (STColumn *)realloc(pBuilder->columns, sizeof(STColumn) * pBuilder->tCols); if (columns == NULL) return -1; pBuilder->columns = columns; } STColumn *pCol = &(pBuilder->columns[pBuilder->nCols]); colSetType(pCol, type); colSetColId(pCol, colId); if (pBuilder->nCols == 0) { colSetOffset(pCol, 0); } else { STColumn *pTCol = &(pBuilder->columns[pBuilder->nCols-1]); colSetOffset(pCol, pTCol->offset + TYPE_BYTES[pTCol->type]); } if (IS_VAR_DATA_TYPE(type)) { colSetBytes(pCol, bytes); pBuilder->tlen += (TYPE_BYTES[type] + bytes); pBuilder->vlen += bytes - sizeof(VarDataLenT); } else { colSetBytes(pCol, TYPE_BYTES[type]); pBuilder->tlen += TYPE_BYTES[type]; pBuilder->vlen += TYPE_BYTES[type]; } pBuilder->nCols++; pBuilder->flen += TYPE_BYTES[type]; ASSERT(pCol->offset < pBuilder->flen); return 0; } STSchema *tdGetSchemaFromBuilder(STSchemaBuilder *pBuilder) { if (pBuilder->nCols <= 0) return NULL; int tlen = sizeof(STSchema) + sizeof(STColumn) * pBuilder->nCols; STSchema *pSchema = (STSchema *)malloc(tlen); if (pSchema == NULL) return NULL; schemaVersion(pSchema) = pBuilder->version; schemaNCols(pSchema) = pBuilder->nCols; schemaTLen(pSchema) = pBuilder->tlen; schemaFLen(pSchema) = pBuilder->flen; schemaVLen(pSchema) = pBuilder->vlen; memcpy(schemaColAt(pSchema, 0), pBuilder->columns, sizeof(STColumn) * pBuilder->nCols); return pSchema; } /** * Initialize a data row */ void tdInitDataRow(SDataRow row, STSchema *pSchema) { dataRowSetLen(row, TD_DATA_ROW_HEAD_SIZE + schemaFLen(pSchema)); dataRowSetVersion(row, schemaVersion(pSchema)); } SDataRow tdNewDataRowFromSchema(STSchema *pSchema) { int32_t size = dataRowMaxBytesFromSchema(pSchema); SDataRow row = malloc(size); if (row == NULL) return NULL; tdInitDataRow(row, pSchema); return row; } /** * Free the SDataRow object */ void tdFreeDataRow(SDataRow row) { if (row) free(row); } SDataRow tdDataRowDup(SDataRow row) { SDataRow trow = malloc(dataRowLen(row)); if (trow == NULL) return NULL; dataRowCpy(trow, row); return trow; } SMemRow tdMemRowDup(SMemRow row) { SMemRow trow = malloc(memRowTLen(row)); if (trow == NULL) return NULL; memRowCpy(trow, row); return trow; } void dataColInit(SDataCol *pDataCol, STColumn *pCol, int maxPoints) { pDataCol->type = colType(pCol); pDataCol->colId = colColId(pCol); pDataCol->bytes = colBytes(pCol); pDataCol->offset = colOffset(pCol) + TD_DATA_ROW_HEAD_SIZE; pDataCol->len = 0; } // value from timestamp should be TKEY here instead of TSKEY int dataColAppendVal(SDataCol *pCol, const void *value, int numOfRows, int maxPoints) { ASSERT(pCol != NULL && value != NULL); if (isAllRowsNull(pCol)) { if (isNull(value, pCol->type)) { // all null value yet, just return return 0; } if(tdAllocMemForCol(pCol, maxPoints) < 0) return -1; if (numOfRows > 0) { // Find the first not null value, fill all previouse values as NULL dataColSetNEleNull(pCol, numOfRows); } } if (IS_VAR_DATA_TYPE(pCol->type)) { // set offset pCol->dataOff[numOfRows] = pCol->len; // Copy data memcpy(POINTER_SHIFT(pCol->pData, pCol->len), value, varDataTLen(value)); // Update the length pCol->len += varDataTLen(value); } else { ASSERT(pCol->len == TYPE_BYTES[pCol->type] * numOfRows); memcpy(POINTER_SHIFT(pCol->pData, pCol->len), value, pCol->bytes); pCol->len += pCol->bytes; } return 0; } static FORCE_INLINE const void *tdGetColDataOfRowUnsafe(SDataCol *pCol, int row) { if (IS_VAR_DATA_TYPE(pCol->type)) { return POINTER_SHIFT(pCol->pData, pCol->dataOff[row]); } else { return POINTER_SHIFT(pCol->pData, TYPE_BYTES[pCol->type] * row); } } bool isNEleNull(SDataCol *pCol, int nEle) { if(isAllRowsNull(pCol)) return true; for (int i = 0; i < nEle; i++) { if (!isNull(tdGetColDataOfRowUnsafe(pCol, i), pCol->type)) return false; } return true; } static FORCE_INLINE void dataColSetNullAt(SDataCol *pCol, int index) { if (IS_VAR_DATA_TYPE(pCol->type)) { pCol->dataOff[index] = pCol->len; char *ptr = POINTER_SHIFT(pCol->pData, pCol->len); setVardataNull(ptr, pCol->type); pCol->len += varDataTLen(ptr); } else { setNull(POINTER_SHIFT(pCol->pData, TYPE_BYTES[pCol->type] * index), pCol->type, pCol->bytes); pCol->len += TYPE_BYTES[pCol->type]; } } static void dataColSetNEleNull(SDataCol *pCol, int nEle) { if (IS_VAR_DATA_TYPE(pCol->type)) { pCol->len = 0; for (int i = 0; i < nEle; i++) { dataColSetNullAt(pCol, i); } } else { setNullN(pCol->pData, pCol->type, pCol->bytes, nEle); pCol->len = TYPE_BYTES[pCol->type] * nEle; } } void dataColSetOffset(SDataCol *pCol, int nEle) { ASSERT(((pCol->type == TSDB_DATA_TYPE_BINARY) || (pCol->type == TSDB_DATA_TYPE_NCHAR))); void *tptr = pCol->pData; // char *tptr = (char *)(pCol->pData); VarDataOffsetT offset = 0; for (int i = 0; i < nEle; i++) { pCol->dataOff[i] = offset; offset += varDataTLen(tptr); tptr = POINTER_SHIFT(tptr, varDataTLen(tptr)); } } SDataCols *tdNewDataCols(int maxCols, int maxRows) { SDataCols *pCols = (SDataCols *)calloc(1, sizeof(SDataCols)); if (pCols == NULL) { uDebug("malloc failure, size:%" PRId64 " failed, reason:%s", (int64_t)sizeof(SDataCols), strerror(errno)); return NULL; } pCols->maxPoints = maxRows; pCols->maxCols = maxCols; pCols->numOfRows = 0; pCols->numOfCols = 0; if (maxCols > 0) { pCols->cols = (SDataCol *)calloc(maxCols, sizeof(SDataCol)); if (pCols->cols == NULL) { uDebug("malloc failure, size:%" PRId64 " failed, reason:%s", (int64_t)sizeof(SDataCol) * maxCols, strerror(errno)); tdFreeDataCols(pCols); return NULL; } int i; for(i = 0; i < maxCols; i++) { pCols->cols[i].spaceSize = 0; pCols->cols[i].len = 0; pCols->cols[i].pData = NULL; pCols->cols[i].dataOff = NULL; } } return pCols; } int tdInitDataCols(SDataCols *pCols, STSchema *pSchema) { int i; int oldMaxCols = pCols->maxCols; if (schemaNCols(pSchema) > oldMaxCols) { pCols->maxCols = schemaNCols(pSchema); void* ptr = (SDataCol *)realloc(pCols->cols, sizeof(SDataCol) * pCols->maxCols); if (ptr == NULL) return -1; pCols->cols = ptr; for(i = oldMaxCols; i < pCols->maxCols; i++) { pCols->cols[i].pData = NULL; pCols->cols[i].dataOff = NULL; pCols->cols[i].spaceSize = 0; } } tdResetDataCols(pCols); pCols->numOfCols = schemaNCols(pSchema); for (i = 0; i < schemaNCols(pSchema); i++) { dataColInit(pCols->cols + i, schemaColAt(pSchema, i), pCols->maxPoints); } return 0; } SDataCols *tdFreeDataCols(SDataCols *pCols) { int i; if (pCols) { if(pCols->cols) { int maxCols = pCols->maxCols; for(i = 0; i < maxCols; i++) { SDataCol *pCol = &pCols->cols[i]; tfree(pCol->pData); } free(pCols->cols); pCols->cols = NULL; } free(pCols); } return NULL; } SDataCols *tdDupDataCols(SDataCols *pDataCols, bool keepData) { SDataCols *pRet = tdNewDataCols(pDataCols->maxCols, pDataCols->maxPoints); if (pRet == NULL) return NULL; pRet->numOfCols = pDataCols->numOfCols; pRet->sversion = pDataCols->sversion; if (keepData) pRet->numOfRows = pDataCols->numOfRows; for (int i = 0; i < pDataCols->numOfCols; i++) { pRet->cols[i].type = pDataCols->cols[i].type; pRet->cols[i].colId = pDataCols->cols[i].colId; pRet->cols[i].bytes = pDataCols->cols[i].bytes; pRet->cols[i].offset = pDataCols->cols[i].offset; if (keepData) { if (pDataCols->cols[i].len > 0) { if(tdAllocMemForCol(&pRet->cols[i], pRet->maxPoints) < 0) { tdFreeDataCols(pRet); return NULL; } pRet->cols[i].len = pDataCols->cols[i].len; memcpy(pRet->cols[i].pData, pDataCols->cols[i].pData, pDataCols->cols[i].len); if (IS_VAR_DATA_TYPE(pRet->cols[i].type)) { int dataOffSize = sizeof(VarDataOffsetT) * pDataCols->maxPoints; memcpy(pRet->cols[i].dataOff, pDataCols->cols[i].dataOff, dataOffSize); } } } } return pRet; } void tdResetDataCols(SDataCols *pCols) { if (pCols != NULL) { pCols->numOfRows = 0; for (int i = 0; i < pCols->maxCols; i++) { dataColReset(pCols->cols + i); } } } static void tdAppendDataRowToDataCol(SDataRow row, STSchema *pSchema, SDataCols *pCols, bool forceSetNull) { ASSERT(pCols->numOfRows == 0 || dataColsKeyLast(pCols) < dataRowKey(row)); int rcol = 0; int dcol = 0; while (dcol < pCols->numOfCols) { bool setCol = 0; SDataCol *pDataCol = &(pCols->cols[dcol]); if (rcol >= schemaNCols(pSchema)) { dataColAppendVal(pDataCol, getNullValue(pDataCol->type), pCols->numOfRows, pCols->maxPoints); dcol++; continue; } STColumn *pRowCol = schemaColAt(pSchema, rcol); if (pRowCol->colId == pDataCol->colId) { void *value = tdGetRowDataOfCol(row, pRowCol->type, pRowCol->offset + TD_DATA_ROW_HEAD_SIZE); if(!isNull(value, pDataCol->type)) setCol = 1; dataColAppendVal(pDataCol, value, pCols->numOfRows, pCols->maxPoints); dcol++; rcol++; } else if (pRowCol->colId < pDataCol->colId) { rcol++; } else { if(forceSetNull || setCol) { dataColAppendVal(pDataCol, getNullValue(pDataCol->type), pCols->numOfRows, pCols->maxPoints); } dcol++; } } pCols->numOfRows++; } static void tdAppendKvRowToDataCol(SKVRow row, STSchema *pSchema, SDataCols *pCols, bool forceSetNull) { ASSERT(pCols->numOfRows == 0 || dataColsKeyLast(pCols) < kvRowKey(row)); int rcol = 0; int dcol = 0; int nRowCols = kvRowNCols(row); while (dcol < pCols->numOfCols) { bool setCol = 0; SDataCol *pDataCol = &(pCols->cols[dcol]); if (rcol >= nRowCols || rcol >= schemaNCols(pSchema)) { dataColAppendVal(pDataCol, getNullValue(pDataCol->type), pCols->numOfRows, pCols->maxPoints); ++dcol; continue; } SColIdx *colIdx = kvRowColIdxAt(row, rcol); if (colIdx->colId == pDataCol->colId) { void *value = tdGetKvRowDataOfCol(row, colIdx->offset); if(!isNull(value, pDataCol->type)) setCol = 1; dataColAppendVal(pDataCol, value, pCols->numOfRows, pCols->maxPoints); ++dcol; ++rcol; } else if (colIdx->colId < pDataCol->colId) { ++rcol; } else { if(forceSetNull || setCol) { dataColAppendVal(pDataCol, getNullValue(pDataCol->type), pCols->numOfRows, pCols->maxPoints); } ++dcol; } } pCols->numOfRows++; } void tdAppendMemRowToDataCol(SMemRow row, STSchema *pSchema, SDataCols *pCols, bool forceSetNull) { if (isDataRow(row)) { tdAppendDataRowToDataCol(memRowDataBody(row), pSchema, pCols, forceSetNull); } else if (isKvRow(row)) { tdAppendKvRowToDataCol(memRowKvBody(row), pSchema, pCols, forceSetNull); } else { ASSERT(0); } } int tdMergeDataCols(SDataCols *target, SDataCols *source, int rowsToMerge, int *pOffset, bool forceSetNull) { ASSERT(rowsToMerge > 0 && rowsToMerge <= source->numOfRows); ASSERT(target->numOfCols == source->numOfCols); int offset = 0; if (pOffset == NULL) { pOffset = &offset; } SDataCols *pTarget = NULL; if ((target->numOfRows == 0) || (dataColsKeyLast(target) < dataColsKeyAtRow(source, *pOffset))) { // No overlap ASSERT(target->numOfRows + rowsToMerge <= target->maxPoints); for (int i = 0; i < rowsToMerge; i++) { for (int j = 0; j < source->numOfCols; j++) { if (source->cols[j].len > 0 || target->cols[j].len > 0) { dataColAppendVal(target->cols + j, tdGetColDataOfRow(source->cols + j, i + (*pOffset)), target->numOfRows, target->maxPoints); } } target->numOfRows++; } (*pOffset) += rowsToMerge; } else { pTarget = tdDupDataCols(target, true); if (pTarget == NULL) goto _err; int iter1 = 0; tdMergeTwoDataCols(target, pTarget, &iter1, pTarget->numOfRows, source, pOffset, source->numOfRows, pTarget->numOfRows + rowsToMerge, forceSetNull); } tdFreeDataCols(pTarget); return 0; _err: tdFreeDataCols(pTarget); return -1; } // src2 data has more priority than src1 static void tdMergeTwoDataCols(SDataCols *target, SDataCols *src1, int *iter1, int limit1, SDataCols *src2, int *iter2, int limit2, int tRows, bool forceSetNull) { tdResetDataCols(target); ASSERT(limit1 <= src1->numOfRows && limit2 <= src2->numOfRows); while (target->numOfRows < tRows) { if (*iter1 >= limit1 && *iter2 >= limit2) break; TSKEY key1 = (*iter1 >= limit1) ? INT64_MAX : dataColsKeyAt(src1, *iter1); TKEY tkey1 = (*iter1 >= limit1) ? TKEY_NULL : dataColsTKeyAt(src1, *iter1); TSKEY key2 = (*iter2 >= limit2) ? INT64_MAX : dataColsKeyAt(src2, *iter2); TKEY tkey2 = (*iter2 >= limit2) ? TKEY_NULL : dataColsTKeyAt(src2, *iter2); ASSERT(tkey1 == TKEY_NULL || (!TKEY_IS_DELETED(tkey1))); if (key1 < key2) { for (int i = 0; i < src1->numOfCols; i++) { ASSERT(target->cols[i].type == src1->cols[i].type); if (src1->cols[i].len > 0 || target->cols[i].len > 0) { dataColAppendVal(&(target->cols[i]), tdGetColDataOfRow(src1->cols + i, *iter1), target->numOfRows, target->maxPoints); } } target->numOfRows++; (*iter1)++; } else if (key1 >= key2) { if ((key1 > key2) || (key1 == key2 && !TKEY_IS_DELETED(tkey2))) { for (int i = 0; i < src2->numOfCols; i++) { ASSERT(target->cols[i].type == src2->cols[i].type); if (src2->cols[i].len > 0 && !isNull(src2->cols[i].pData, src2->cols[i].type)) { dataColAppendVal(&(target->cols[i]), tdGetColDataOfRow(src2->cols + i, *iter2), target->numOfRows, target->maxPoints); } else if(!forceSetNull && key1 == key2 && src1->cols[i].len > 0) { dataColAppendVal(&(target->cols[i]), tdGetColDataOfRow(src1->cols + i, *iter1), target->numOfRows, target->maxPoints); } else if(target->cols[i].len > 0) { dataColSetNullAt(&target->cols[i], target->numOfRows); } } target->numOfRows++; } (*iter2)++; if (key1 == key2) (*iter1)++; } ASSERT(target->numOfRows <= target->maxPoints); } } SKVRow tdKVRowDup(SKVRow row) { SKVRow trow = malloc(kvRowLen(row)); if (trow == NULL) return NULL; kvRowCpy(trow, row); return trow; } static int compareColIdx(const void* a, const void* b) { const SColIdx* x = (const SColIdx*)a; const SColIdx* y = (const SColIdx*)b; if (x->colId > y->colId) { return 1; } if (x->colId < y->colId) { return -1; } return 0; } void tdSortKVRowByColIdx(SKVRow row) { qsort(kvRowColIdx(row), kvRowNCols(row), sizeof(SColIdx), compareColIdx); } int tdSetKVRowDataOfCol(SKVRow *orow, int16_t colId, int8_t type, void *value) { SColIdx *pColIdx = NULL; SKVRow row = *orow; SKVRow nrow = NULL; void * ptr = taosbsearch(&colId, kvRowColIdx(row), kvRowNCols(row), sizeof(SColIdx), comparTagId, TD_GE); if (ptr == NULL || ((SColIdx *)ptr)->colId > colId) { // need to add a column value to the row int diff = IS_VAR_DATA_TYPE(type) ? varDataTLen(value) : TYPE_BYTES[type]; int nRowLen = kvRowLen(row) + sizeof(SColIdx) + diff; int oRowCols = kvRowNCols(row); ASSERT(diff > 0); nrow = malloc(nRowLen); if (nrow == NULL) return -1; kvRowSetLen(nrow, nRowLen); kvRowSetNCols(nrow, oRowCols + 1); memcpy(kvRowColIdx(nrow), kvRowColIdx(row), sizeof(SColIdx) * oRowCols); memcpy(kvRowValues(nrow), kvRowValues(row), kvRowValLen(row)); pColIdx = kvRowColIdxAt(nrow, oRowCols); pColIdx->colId = colId; pColIdx->offset = kvRowValLen(row); memcpy(kvRowColVal(nrow, pColIdx), value, diff); // copy new value tdSortKVRowByColIdx(nrow); *orow = nrow; free(row); } else { ASSERT(((SColIdx *)ptr)->colId == colId); if (IS_VAR_DATA_TYPE(type)) { void *pOldVal = kvRowColVal(row, (SColIdx *)ptr); if (varDataTLen(value) == varDataTLen(pOldVal)) { // just update the column value in place memcpy(pOldVal, value, varDataTLen(value)); } else { // need to reallocate the memory int16_t nlen = kvRowLen(row) + (varDataTLen(value) - varDataTLen(pOldVal)); ASSERT(nlen > 0); nrow = malloc(nlen); if (nrow == NULL) return -1; kvRowSetLen(nrow, nlen); kvRowSetNCols(nrow, kvRowNCols(row)); int zsize = sizeof(SColIdx) * kvRowNCols(row) + ((SColIdx *)ptr)->offset; memcpy(kvRowColIdx(nrow), kvRowColIdx(row), zsize); memcpy(kvRowColVal(nrow, ((SColIdx *)ptr)), value, varDataTLen(value)); // Copy left value part int lsize = kvRowLen(row) - TD_KV_ROW_HEAD_SIZE - zsize - varDataTLen(pOldVal); if (lsize > 0) { memcpy(POINTER_SHIFT(nrow, TD_KV_ROW_HEAD_SIZE + zsize + varDataTLen(value)), POINTER_SHIFT(row, TD_KV_ROW_HEAD_SIZE + zsize + varDataTLen(pOldVal)), lsize); } for (int i = 0; i < kvRowNCols(nrow); i++) { pColIdx = kvRowColIdxAt(nrow, i); if (pColIdx->offset > ((SColIdx *)ptr)->offset) { pColIdx->offset = pColIdx->offset - varDataTLen(pOldVal) + varDataTLen(value); } } *orow = nrow; free(row); } } else { memcpy(kvRowColVal(row, (SColIdx *)ptr), value, TYPE_BYTES[type]); } } return 0; } int tdEncodeKVRow(void **buf, SKVRow row) { // May change the encode purpose if (buf != NULL) { kvRowCpy(*buf, row); *buf = POINTER_SHIFT(*buf, kvRowLen(row)); } return kvRowLen(row); } void *tdDecodeKVRow(void *buf, SKVRow *row) { *row = tdKVRowDup(buf); if (*row == NULL) return NULL; return POINTER_SHIFT(buf, kvRowLen(*row)); } int tdInitKVRowBuilder(SKVRowBuilder *pBuilder) { pBuilder->tCols = 128; pBuilder->nCols = 0; pBuilder->pColIdx = (SColIdx *)malloc(sizeof(SColIdx) * pBuilder->tCols); if (pBuilder->pColIdx == NULL) return -1; pBuilder->alloc = 1024; pBuilder->size = 0; pBuilder->buf = malloc(pBuilder->alloc); if (pBuilder->buf == NULL) { free(pBuilder->pColIdx); return -1; } return 0; } void tdDestroyKVRowBuilder(SKVRowBuilder *pBuilder) { tfree(pBuilder->pColIdx); tfree(pBuilder->buf); } void tdResetKVRowBuilder(SKVRowBuilder *pBuilder) { pBuilder->nCols = 0; pBuilder->size = 0; } SKVRow tdGetKVRowFromBuilder(SKVRowBuilder *pBuilder) { int tlen = sizeof(SColIdx) * pBuilder->nCols + pBuilder->size; if (tlen == 0) return NULL; tlen += TD_KV_ROW_HEAD_SIZE; SKVRow row = malloc(tlen); if (row == NULL) return NULL; kvRowSetNCols(row, pBuilder->nCols); kvRowSetLen(row, tlen); memcpy(kvRowColIdx(row), pBuilder->pColIdx, sizeof(SColIdx) * pBuilder->nCols); memcpy(kvRowValues(row), pBuilder->buf, pBuilder->size); return row; } SMemRow mergeTwoMemRows(void *buffer, SMemRow row1, SMemRow row2, STSchema *pSchema1, STSchema *pSchema2) { #if 0 ASSERT(memRowKey(row1) == memRowKey(row2)); ASSERT(schemaVersion(pSchema1) == memRowVersion(row1)); ASSERT(schemaVersion(pSchema2) == memRowVersion(row2)); ASSERT(schemaVersion(pSchema1) >= schemaVersion(pSchema2)); #endif SArray *stashRow = taosArrayInit(pSchema1->numOfCols, sizeof(SColInfo)); if (stashRow == NULL) { return NULL; } SMemRow pRow = buffer; SDataRow dataRow = memRowDataBody(pRow); memRowSetType(pRow, SMEM_ROW_DATA); dataRowSetVersion(dataRow, schemaVersion(pSchema1)); // use latest schema version dataRowSetLen(dataRow, (TDRowLenT)(TD_DATA_ROW_HEAD_SIZE + pSchema1->flen)); TDRowTLenT dataLen = 0, kvLen = TD_MEM_ROW_KV_HEAD_SIZE; int32_t i = 0; // row1 int32_t j = 0; // row2 int32_t nCols1 = schemaNCols(pSchema1); int32_t nCols2 = schemaNCols(pSchema2); SColInfo colInfo = {0}; int32_t kvIdx1 = 0, kvIdx2 = 0; while (i < nCols1) { STColumn *pCol = schemaColAt(pSchema1, i); void * val1 = tdGetMemRowDataOfColEx(row1, pCol->colId, pCol->type, TD_DATA_ROW_HEAD_SIZE + pCol->offset, &kvIdx1); // if val1 != NULL, use val1; if (val1 != NULL && !isNull(val1, pCol->type)) { tdAppendColVal(dataRow, val1, pCol->type, pCol->offset); kvLen += tdGetColAppendLen(SMEM_ROW_KV, val1, pCol->type); setSColInfo(&colInfo, pCol->colId, pCol->type, val1); taosArrayPush(stashRow, &colInfo); ++i; // next col continue; } void *val2 = NULL; while (j < nCols2) { STColumn *tCol = schemaColAt(pSchema2, j); if (tCol->colId < pCol->colId) { ++j; continue; } if (tCol->colId == pCol->colId) { val2 = tdGetMemRowDataOfColEx(row2, tCol->colId, tCol->type, TD_DATA_ROW_HEAD_SIZE + tCol->offset, &kvIdx2); } else if (tCol->colId > pCol->colId) { // set NULL } break; } // end of while(jtype); } tdAppendColVal(dataRow, val2, pCol->type, pCol->offset); if (!isNull(val2, pCol->type)) { kvLen += tdGetColAppendLen(SMEM_ROW_KV, val2, pCol->type); setSColInfo(&colInfo, pCol->colId, pCol->type, val2); taosArrayPush(stashRow, &colInfo); } ++i; // next col } dataLen = memRowTLen(pRow); if (kvLen < dataLen) { // scan stashRow and generate SKVRow memset(buffer, 0, sizeof(dataLen)); SMemRow tRow = buffer; memRowSetType(tRow, SMEM_ROW_KV); SKVRow kvRow = (SKVRow)memRowKvBody(tRow); int16_t nKvNCols = (int16_t) taosArrayGetSize(stashRow); kvRowSetLen(kvRow, (TDRowLenT)(TD_KV_ROW_HEAD_SIZE + sizeof(SColIdx) * nKvNCols)); kvRowSetNCols(kvRow, nKvNCols); memRowSetKvVersion(tRow, pSchema1->version); int32_t toffset = 0; int16_t k; for (k = 0; k < nKvNCols; ++k) { SColInfo *pColInfo = taosArrayGet(stashRow, k); tdAppendKvColVal(kvRow, pColInfo->colVal, true, pColInfo->colId, pColInfo->colType, toffset); toffset += sizeof(SColIdx); } ASSERT(kvLen == memRowTLen(tRow)); } taosArrayDestroy(stashRow); return buffer; }