/* * Copyright (c) 2019 TAOS Data, Inc. * * This program is free software: you can use, redistribute, and/or modify * it under the terms of the GNU Affero General Public License, version 3 * or later ("AGPL"), as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #define _DEFAULT_SOURCE #include "trow.h" const uint8_t tdVTypeByte[2][3] = {{ // 2 bits TD_VTYPE_NORM_BYTE_II, TD_VTYPE_NONE_BYTE_II, TD_VTYPE_NULL_BYTE_II, }, { // 1 bit TD_VTYPE_NORM_BYTE_I, // normal TD_VTYPE_NULL_BYTE_I, TD_VTYPE_NULL_BYTE_I, // padding } }; // declaration static uint8_t tdGetBitmapByte(uint8_t byte); static bool tdSTSRowIterGetTpVal(STSRowIter *pIter, col_type_t colType, int32_t offset, SCellVal *pVal); static bool tdSTSRowIterGetKvVal(STSRowIter *pIter, col_id_t colId, col_id_t *nIdx, SCellVal *pVal); static bool tdSTpRowGetVal(STSRow *pRow, col_id_t colId, col_type_t colType, int32_t flen, uint32_t offset, col_id_t colIdx, SCellVal *pVal); static bool tdSKvRowGetVal(STSRow *pRow, col_id_t colId, col_id_t colIdx, SCellVal *pVal); static void tdSCellValPrint(SCellVal *pVal, int8_t colType); // implementation /** * @brief Compress bitmap bytes comprised of 2-bits to counterpart of 1-bit. * e.g. * TD_VTYPE_NORM 0x00U(00000000) to 00000000 Normal * TD_VTYPE_NULL 0x01U(00000001) to 00000001 Null * TD_VTYPE_NONE 0x02U(00000010) to 00000001 Null * * 00000000 0x00 0x00 * 01000000 0x40 0x08 * 10000000 0x80 0x08 * ... * @param byte * @return uint8_t */ static uint8_t tdGetMergedBitmapByte(uint8_t byte) { switch (byte) { case 0x00: return 0x00; case 0x40: return 0x08; case 0x80: return 0x08; case 0x10: return 0x04; case 0x50: return 0x0c; case 0x90: return 0x0c; case 0x20: return 0x04; case 0x60: return 0x0c; case 0xa0: return 0x0c; case 0x04: return 0x02; case 0x44: return 0x0a; case 0x84: return 0x0a; case 0x14: return 0x06; case 0x54: return 0x0e; case 0x94: return 0x0e; case 0x24: return 0x06; case 0x64: return 0x0e; case 0xa4: return 0x0e; case 0x08: return 0x02; case 0x48: return 0x0a; case 0x88: return 0x0a; case 0x18: return 0x06; case 0x58: return 0x0e; case 0x98: return 0x0e; case 0x28: return 0x06; case 0x68: return 0x0e; case 0xa8: return 0x0e; case 0x01: return 0x01; case 0x41: return 0x09; case 0x81: return 0x09; case 0x11: return 0x05; case 0x51: return 0x0d; case 0x91: return 0x0d; case 0x21: return 0x05; case 0x61: return 0x0d; case 0xa1: return 0x0d; case 0x05: return 0x03; case 0x45: return 0x0b; case 0x85: return 0x0b; case 0x15: return 0x07; case 0x55: return 0x0f; case 0x95: return 0x0f; case 0x25: return 0x07; case 0x65: return 0x0f; case 0xa5: return 0x0f; case 0x09: return 0x03; case 0x49: return 0x0b; case 0x89: return 0x0b; case 0x19: return 0x07; case 0x59: return 0x0f; case 0x99: return 0x0f; case 0x29: return 0x07; case 0x69: return 0x0f; case 0xa9: return 0x0f; case 0x02: return 0x01; case 0x42: return 0x09; case 0x82: return 0x09; case 0x12: return 0x05; case 0x52: return 0x0d; case 0x92: return 0x0d; case 0x22: return 0x05; case 0x62: return 0x0d; case 0xa2: return 0x0d; case 0x06: return 0x03; case 0x46: return 0x0b; case 0x86: return 0x0b; case 0x16: return 0x07; case 0x56: return 0x0f; case 0x96: return 0x0f; case 0x26: return 0x07; case 0x66: return 0x0f; case 0xa6: return 0x0f; case 0x0a: return 0x03; case 0x4a: return 0x0b; case 0x8a: return 0x0b; case 0x1a: return 0x07; case 0x5a: return 0x0f; case 0x9a: return 0x0f; case 0x2a: return 0x07; case 0x6a: return 0x0f; case 0xaa: return 0x0f; default: // make sure the bitmap area is set to 0 firstly ASSERT(0); return 0x0f; // return NULL bitmap for exception } } /** * @brief Merge bitmap from 2 bits to 1 bit, and the memory buffer should be guaranteed by the invoker. * * @param srcBitmap * @param nBits * @param dstBitmap */ void tdMergeBitmap(uint8_t *srcBitmap, int32_t nBits, uint8_t *dstBitmap) { int32_t i = 0, j = 0; int32_t nBytes = TD_BITMAP_BYTES(nBits); int32_t nRoundBytes = nBits / 4; int32_t nRemainderBits = nBits - nRoundBytes * 4; switch (nRemainderBits) { case 0: // NOTHING TODO break; case 1: { void *lastByte = POINTER_SHIFT(srcBitmap, nRoundBytes); *(uint8_t *)lastByte &= 0xC0; } break; case 2: { void *lastByte = POINTER_SHIFT(srcBitmap, nRoundBytes); *(uint8_t *)lastByte &= 0xF0; } break; case 3: { void *lastByte = POINTER_SHIFT(srcBitmap, nRoundBytes); *(uint8_t *)lastByte &= 0xFC; } break; default: ASSERT(0); } if (nBytes > 0) { dstBitmap[j] = (tdGetMergedBitmapByte(srcBitmap[i]) << 4); } while ((++i) < nBytes) { if ((i & 1) == 0) { dstBitmap[j] = (tdGetMergedBitmapByte(srcBitmap[i]) << 4); } else { dstBitmap[j] |= tdGetMergedBitmapByte(srcBitmap[i]); ++j; } } } /** * @brief Set bitmap area by byte preferentially and then by bit. * * @param pBitmap * @param nEle * @param valType * @param bitmapMode 0 for 2 bits, 1 for 1 bit * @return int32_t */ int32_t tdSetBitmapValTypeN(void *pBitmap, int16_t nEle, TDRowValT valType, int8_t bitmapMode) { TASSERT(valType < TD_VTYPE_MAX); int32_t nBytes = (bitmapMode == 0 ? nEle / TD_VTYPE_PARTS : nEle / TD_VTYPE_PARTS_I); uint8_t vTypeByte = tdVTypeByte[bitmapMode][valType]; for (int i = 0; i < nBytes; ++i) { *(uint8_t *)pBitmap = vTypeByte; pBitmap = POINTER_SHIFT(pBitmap, 1); } int32_t nLeft = nEle - nBytes * (bitmapMode == 0 ? TD_VTYPE_BITS : TD_VTYPE_BITS_I); for (int j = 0; j < nLeft; ++j) { tdSetBitmapValType(pBitmap, j, valType, bitmapMode); } return TSDB_CODE_SUCCESS; } bool tdIsBitmapBlkNorm(const void *pBitmap, int32_t numOfBits, int8_t bitmapMode) { int32_t nBytes = (bitmapMode == 0 ? numOfBits / TD_VTYPE_PARTS : numOfBits / TD_VTYPE_PARTS_I); uint8_t vTypeByte = tdVTypeByte[bitmapMode][TD_VTYPE_NORM]; uint8_t *qBitmap = (uint8_t *)pBitmap; for (int i = 0; i < nBytes; ++i) { if (*qBitmap != vTypeByte) { return false; } qBitmap = (uint8_t *)POINTER_SHIFT(pBitmap, i); } int32_t nLeft = numOfBits - nBytes * (bitmapMode == 0 ? TD_VTYPE_BITS : TD_VTYPE_BITS_I); for (int j = 0; j < nLeft; ++j) { uint8_t vType; tdGetBitmapValType(qBitmap, j, &vType, bitmapMode); if (vType != TD_VTYPE_NORM) { return false; } } return true; } STSRow *tdRowDup(STSRow *row) { STSRow *trow = taosMemoryMalloc(TD_ROW_LEN(row)); if (trow == NULL) return NULL; tdRowCpy(trow, row); return trow; } void tdSRowPrint(STSRow *row, STSchema *pSchema, const char *tag) { STSRowIter iter = {0}; tdSTSRowIterInit(&iter, pSchema); tdSTSRowIterReset(&iter, row); printf("%s >>>type:%d,sver:%d ", tag, (int32_t)TD_ROW_TYPE(row), (int32_t)TD_ROW_SVER(row)); STColumn *cols = (STColumn *)&iter.pSchema->columns; while (true) { SCellVal sVal = {.valType = 255, NULL}; if (!tdSTSRowIterNext(&iter, &sVal)) { break; } ASSERT(sVal.valType == 0 || sVal.valType == 1 || sVal.valType == 2); tdSCellValPrint(&sVal, cols[iter.colIdx - 1].type); } printf("\n"); } void tdSCellValPrint(SCellVal *pVal, int8_t colType) { if (tdValTypeIsNull(pVal->valType)) { printf("NULL "); return; } else if (tdValTypeIsNone(pVal->valType)) { printf("NONE "); return; } switch (colType) { case TSDB_DATA_TYPE_BOOL: printf("%s ", (*(int8_t *)pVal->val) == 0 ? "false" : "true"); break; case TSDB_DATA_TYPE_TINYINT: printf("%" PRIi8 " ", *(int8_t *)pVal->val); break; case TSDB_DATA_TYPE_SMALLINT: printf("%" PRIi16 " ", *(int16_t *)pVal->val); break; case TSDB_DATA_TYPE_INT: printf("%" PRIi32 " ", *(int32_t *)pVal->val); break; case TSDB_DATA_TYPE_BIGINT: printf("%" PRIi64 " ", *(int64_t *)pVal->val); break; case TSDB_DATA_TYPE_FLOAT: printf("%f ", *(float *)pVal->val); break; case TSDB_DATA_TYPE_DOUBLE: printf("%lf ", *(double *)pVal->val); break; case TSDB_DATA_TYPE_VARCHAR: printf("VARCHAR "); break; case TSDB_DATA_TYPE_TIMESTAMP: printf("%" PRIi64 " ", *(int64_t *)pVal->val); break; case TSDB_DATA_TYPE_NCHAR: printf("NCHAR "); break; case TSDB_DATA_TYPE_UTINYINT: printf("%" PRIu8 " ", *(uint8_t *)pVal->val); break; case TSDB_DATA_TYPE_USMALLINT: printf("%" PRIu16 " ", *(uint16_t *)pVal->val); break; case TSDB_DATA_TYPE_UINT: printf("%" PRIu32 " ", *(uint32_t *)pVal->val); break; case TSDB_DATA_TYPE_UBIGINT: printf("%" PRIu64 " ", *(uint64_t *)pVal->val); break; case TSDB_DATA_TYPE_JSON: printf("JSON "); break; case TSDB_DATA_TYPE_VARBINARY: printf("VARBIN "); break; case TSDB_DATA_TYPE_DECIMAL: printf("DECIMAL "); break; case TSDB_DATA_TYPE_BLOB: printf("BLOB "); break; case TSDB_DATA_TYPE_MEDIUMBLOB: printf("MedBLOB "); break; // case TSDB_DATA_TYPE_BINARY: // printf("BINARY "); // break; case TSDB_DATA_TYPE_MAX: printf("UNDEF "); break; default: printf("UNDEF "); break; } } static FORCE_INLINE int32_t compareKvRowColId(const void *key1, const void *key2) { if (*(col_id_t *)key1 > ((SKvRowIdx *)key2)->colId) { return 1; } else if (*(col_id_t *)key1 < ((SKvRowIdx *)key2)->colId) { return -1; } else { return 0; } } bool tdSKvRowGetVal(STSRow *pRow, col_id_t colId, col_id_t colIdx, SCellVal *pVal) { if (colId == PRIMARYKEY_TIMESTAMP_COL_ID) { tdRowSetVal(pVal, TD_VTYPE_NORM, TD_ROW_KEY_ADDR(pRow)); return true; } int16_t nCols = tdRowGetNCols(pRow) - 1; if (nCols <= 0) { pVal->valType = TD_VTYPE_NONE; return true; } SKvRowIdx *pColIdx = (SKvRowIdx *)taosbsearch(&colId, TD_ROW_COL_IDX(pRow), nCols, sizeof(SKvRowIdx), compareKvRowColId, TD_EQ); if (!pColIdx) { pVal->valType = TD_VTYPE_NONE; return true; } void *pBitmap = tdGetBitmapAddrKv(pRow, tdRowGetNCols(pRow)); tdGetKvRowValOfCol(pVal, pRow, pBitmap, pColIdx->offset, POINTER_DISTANCE(pColIdx, TD_ROW_COL_IDX(pRow)) / sizeof(SKvRowIdx)); return true; } bool tdSTpRowGetVal(STSRow *pRow, col_id_t colId, col_type_t colType, int32_t flen, uint32_t offset, col_id_t colIdx, SCellVal *pVal) { if (colId == PRIMARYKEY_TIMESTAMP_COL_ID) { tdRowSetVal(pVal, TD_VTYPE_NORM, TD_ROW_KEY_ADDR(pRow)); return true; } void *pBitmap = tdGetBitmapAddrTp(pRow, flen); tdGetTpRowValOfCol(pVal, pRow, pBitmap, colType, offset - sizeof(TSKEY), colIdx); return true; } bool tdSTSRowIterFetch(STSRowIter *pIter, col_id_t colId, col_type_t colType, SCellVal *pVal) { if (colId == PRIMARYKEY_TIMESTAMP_COL_ID) { pVal->val = &pIter->pRow->ts; pVal->valType = TD_VTYPE_NORM; return true; } if (TD_IS_TP_ROW(pIter->pRow)) { STColumn *pCol = NULL; STSchema *pSchema = pIter->pSchema; while (pIter->colIdx < pSchema->numOfCols) { pCol = &pSchema->columns[pIter->colIdx]; // 1st column of schema is primary TS key if (colId == pCol->colId) { break; } else if (pCol->colId < colId) { ++pIter->colIdx; continue; } else { return false; } } tdSTSRowIterGetTpVal(pIter, pCol->type, pCol->offset - sizeof(TSKEY), pVal); ++pIter->colIdx; } else if (TD_IS_KV_ROW(pIter->pRow)) { return tdSTSRowIterGetKvVal(pIter, colId, &pIter->kvIdx, pVal); } else { pVal->valType = TD_VTYPE_NONE; terrno = TSDB_CODE_INVALID_PARA; if (COL_REACH_END(colId, pIter->maxColId)) return false; } return true; } bool tdSTSRowIterNext(STSRowIter *pIter, SCellVal *pVal) { if (pIter->colIdx >= pIter->pSchema->numOfCols) { return false; } STColumn *pCol = &pIter->pSchema->columns[pIter->colIdx]; if (pCol->colId == PRIMARYKEY_TIMESTAMP_COL_ID) { pVal->val = &pIter->pRow->ts; pVal->valType = TD_VTYPE_NORM; ++pIter->colIdx; return true; } if (TD_IS_TP_ROW(pIter->pRow)) { tdSTSRowIterGetTpVal(pIter, pCol->type, pCol->offset - sizeof(TSKEY), pVal); } else if (TD_IS_KV_ROW(pIter->pRow)) { tdSTSRowIterGetKvVal(pIter, pCol->colId, &pIter->kvIdx, pVal); } else { ASSERT(0); } ++pIter->colIdx; return true; } bool tdSTSRowIterGetTpVal(STSRowIter *pIter, col_type_t colType, int32_t offset, SCellVal *pVal) { STSRow *pRow = pIter->pRow; if (pRow->statis == 0) { pVal->valType = TD_VTYPE_NORM; if (IS_VAR_DATA_TYPE(colType)) { pVal->val = POINTER_SHIFT(pRow, *(VarDataOffsetT *)POINTER_SHIFT(TD_ROW_DATA(pRow), offset)); } else { pVal->val = POINTER_SHIFT(TD_ROW_DATA(pRow), offset); } return TSDB_CODE_SUCCESS; } if (tdGetBitmapValType(pIter->pBitmap, pIter->colIdx - 1, &pVal->valType, 0) != TSDB_CODE_SUCCESS) { pVal->valType = TD_VTYPE_NONE; return terrno; } if (pVal->valType == TD_VTYPE_NORM) { if (IS_VAR_DATA_TYPE(colType)) { pVal->val = POINTER_SHIFT(pRow, *(VarDataOffsetT *)POINTER_SHIFT(TD_ROW_DATA(pRow), offset)); } else { pVal->val = POINTER_SHIFT(TD_ROW_DATA(pRow), offset); } } return true; } bool tdSTSRowIterGetKvVal(STSRowIter *pIter, col_id_t colId, col_id_t *nIdx, SCellVal *pVal) { STSRow *pRow = pIter->pRow; SKvRowIdx *pKvIdx = NULL; bool colFound = false; col_id_t kvNCols = tdRowGetNCols(pRow) - 1; void *pColIdx = TD_ROW_COL_IDX(pRow); while (*nIdx < kvNCols) { pKvIdx = (SKvRowIdx *)POINTER_SHIFT(pColIdx, *nIdx * sizeof(SKvRowIdx)); if (pKvIdx->colId == colId) { ++(*nIdx); pVal->val = POINTER_SHIFT(pRow, pKvIdx->offset); colFound = true; break; } else if (pKvIdx->colId > colId) { pVal->valType = TD_VTYPE_NONE; return true; } else { ++(*nIdx); } } if (!colFound) { if (colId <= pIter->maxColId) { pVal->valType = TD_VTYPE_NONE; return true; } else { return false; } } if (tdGetBitmapValType(pIter->pBitmap, pIter->kvIdx - 1, &pVal->valType, 0) != TSDB_CODE_SUCCESS) { pVal->valType = TD_VTYPE_NONE; } return true; } int32_t tdSTSRowNew(SArray *pArray, STSchema *pTSchema, STSRow **ppRow) { STColumn *pTColumn; SColVal *pColVal; int32_t nColVal = taosArrayGetSize(pArray); int32_t varDataLen = 0; int32_t maxVarDataLen = 0; int32_t iColVal = 0; void *varBuf = NULL; bool isAlloc = false; ASSERT(nColVal > 1); for (int32_t iColumn = 0; iColumn < pTSchema->numOfCols; ++iColumn) { pTColumn = &pTSchema->columns[iColumn]; if (iColVal < nColVal) { pColVal = (SColVal *)taosArrayGet(pArray, iColVal); } else { pColVal = NULL; } if (iColumn == 0) { ASSERT(pColVal->cid == pTColumn->colId); ASSERT(pTColumn->type == TSDB_DATA_TYPE_TIMESTAMP); ASSERT(pTColumn->colId == PRIMARYKEY_TIMESTAMP_COL_ID); } else { if (IS_VAR_DATA_TYPE(pTColumn->type)) { if (pColVal && !pColVal->isNone && !pColVal->isNull) { varDataLen += (pColVal->value.nData + sizeof(VarDataLenT)); if (maxVarDataLen < (pColVal->value.nData + sizeof(VarDataLenT))) { maxVarDataLen = pColVal->value.nData + sizeof(VarDataLenT); } } else { varDataLen += sizeof(VarDataLenT); if (pTColumn->type == TSDB_DATA_TYPE_VARCHAR) { varDataLen += CHAR_BYTES; if (maxVarDataLen < CHAR_BYTES + sizeof(VarDataLenT)) { maxVarDataLen = CHAR_BYTES + sizeof(VarDataLenT); } } else { varDataLen += INT_BYTES; if (maxVarDataLen < INT_BYTES + sizeof(VarDataLenT)) { maxVarDataLen = INT_BYTES + sizeof(VarDataLenT); } } } } } ++iColVal; } if (!(*ppRow)) { *ppRow = (STSRow *)taosMemoryCalloc( 1, sizeof(STSRow) + pTSchema->flen + varDataLen + TD_BITMAP_BYTES(pTSchema->numOfCols - 1)); isAlloc = true; } if (!(*ppRow)) { terrno = TSDB_CODE_OUT_OF_MEMORY; return -1; } if (maxVarDataLen > 0) { varBuf = taosMemoryMalloc(maxVarDataLen); if (!varBuf) { if (isAlloc) { taosMemoryFreeClear(*ppRow); } terrno = TSDB_CODE_OUT_OF_MEMORY; return -1; } } SRowBuilder rb = {0}; tdSRowInit(&rb, pTSchema->version); tdSRowSetInfo(&rb, pTSchema->numOfCols, pTSchema->numOfCols, pTSchema->flen); tdSRowResetBuf(&rb, *ppRow); iColVal = 0; for (int32_t iColumn = 0; iColumn < pTSchema->numOfCols; ++iColumn) { pTColumn = &pTSchema->columns[iColumn]; TDRowValT valType = TD_VTYPE_NORM; const void *val = NULL; if (iColVal < nColVal) { pColVal = (SColVal *)taosArrayGet(pArray, iColVal); if (pColVal->isNone) { valType = TD_VTYPE_NONE; } else if (pColVal->isNull) { valType = TD_VTYPE_NULL; } else if (IS_VAR_DATA_TYPE(pTColumn->type)) { varDataSetLen(varBuf, pColVal->value.nData); memcpy(varDataVal(varBuf), pColVal->value.pData, pColVal->value.nData); val = varBuf; } else { val = (const void *)&pColVal->value.i64; } } else { pColVal = NULL; valType = TD_VTYPE_NONE; } tdAppendColValToRow(&rb, pTColumn->colId, pTColumn->type, valType, val, true, pTColumn->offset, iColVal); ++iColVal; } tdSRowEnd(&rb); taosMemoryFreeClear(varBuf); return 0; } static FORCE_INLINE int32_t tdCompareColId(const void *arg1, const void *arg2) { int32_t colId = *(int32_t *)arg1; STColumn *pCol = (STColumn *)arg2; if (colId < pCol->colId) { return -1; } else if (colId == pCol->colId) { return 0; } else { return 1; } } bool tdSTSRowGetVal(STSRowIter *pIter, col_id_t colId, col_type_t colType, SCellVal *pVal) { if (colId == PRIMARYKEY_TIMESTAMP_COL_ID) { pVal->val = &pIter->pRow->ts; pVal->valType = TD_VTYPE_NORM; return true; } STSRow *pRow = pIter->pRow; int16_t colIdx = -1; if (TD_IS_TP_ROW(pRow)) { STSchema *pSchema = pIter->pSchema; STColumn *pCol = (STColumn *)taosbsearch(&colId, pSchema->columns, pSchema->numOfCols, sizeof(STColumn), tdCompareColId, TD_EQ); if (!pCol) { pVal->valType = TD_VTYPE_NONE; if (COL_REACH_END(colId, pIter->maxColId)) return false; return true; } #ifdef TD_SUPPORT_BITMAP colIdx = POINTER_DISTANCE(pCol, pSchema->columns) / sizeof(STColumn); #endif tdGetTpRowValOfCol(pVal, pRow, pIter->pBitmap, pCol->type, pCol->offset - sizeof(TSKEY), colIdx - 1); } else if (TD_IS_KV_ROW(pRow)) { SKvRowIdx *pIdx = (SKvRowIdx *)taosbsearch(&colId, TD_ROW_COL_IDX(pRow), tdRowGetNCols(pRow), sizeof(SKvRowIdx), compareKvRowColId, TD_EQ); #ifdef TD_SUPPORT_BITMAP if (pIdx) { colIdx = POINTER_DISTANCE(pIdx, TD_ROW_COL_IDX(pRow)) / sizeof(SKvRowIdx); } #endif tdGetKvRowValOfCol(pVal, pRow, pIter->pBitmap, pIdx ? pIdx->offset : -1, colIdx); } else { if (COL_REACH_END(colId, pIter->maxColId)) return false; pVal->valType = TD_VTYPE_NONE; } return true; } int32_t tdGetBitmapValTypeII(const void *pBitmap, int16_t colIdx, TDRowValT *pValType) { if (!pBitmap || colIdx < 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } int16_t nBytes = colIdx / TD_VTYPE_PARTS; int16_t nOffset = colIdx & TD_VTYPE_OPTR; char *pDestByte = (char *)POINTER_SHIFT(pBitmap, nBytes); // use literal value directly and not use formula to simplify the codes switch (nOffset) { case 0: *pValType = (((*pDestByte) & 0xC0) >> 6); break; case 1: *pValType = (((*pDestByte) & 0x30) >> 4); break; case 2: *pValType = (((*pDestByte) & 0x0C) >> 2); break; case 3: *pValType = ((*pDestByte) & 0x03); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } return TSDB_CODE_SUCCESS; } int32_t tdGetBitmapValTypeI(const void *pBitmap, int16_t colIdx, TDRowValT *pValType) { if (!pBitmap || colIdx < 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } int16_t nBytes = colIdx / TD_VTYPE_PARTS_I; int16_t nOffset = colIdx & TD_VTYPE_OPTR_I; char *pDestByte = (char *)POINTER_SHIFT(pBitmap, nBytes); // use literal value directly and not use formula to simplify the codes switch (nOffset) { case 0: *pValType = (((*pDestByte) & 0x80) >> 7); break; case 1: *pValType = (((*pDestByte) & 0x40) >> 6); break; case 2: *pValType = (((*pDestByte) & 0x20) >> 5); break; case 3: *pValType = (((*pDestByte) & 0x10) >> 4); break; case 4: *pValType = (((*pDestByte) & 0x08) >> 3); break; case 5: *pValType = (((*pDestByte) & 0x04) >> 2); break; case 6: *pValType = (((*pDestByte) & 0x02) >> 1); break; case 7: *pValType = ((*pDestByte) & 0x01); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } return TSDB_CODE_SUCCESS; } int32_t tdSetBitmapValTypeI(void *pBitmap, int16_t colIdx, TDRowValT valType) { if (!pBitmap || colIdx < 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } int16_t nBytes = colIdx / TD_VTYPE_PARTS_I; int16_t nOffset = colIdx & TD_VTYPE_OPTR_I; char *pDestByte = (char *)POINTER_SHIFT(pBitmap, nBytes); // use literal value directly and not use formula to simplify the codes switch (nOffset) { case 0: *pDestByte = ((*pDestByte) & 0x7F) | (valType << 7); // set the value and clear other partitions for offset 0 // *pDestByte |= (valType << 7); break; case 1: *pDestByte = ((*pDestByte) & 0xBF) | (valType << 6); // *pDestByte |= (valType << 6); break; case 2: *pDestByte = ((*pDestByte) & 0xDF) | (valType << 5); // *pDestByte |= (valType << 5); break; case 3: *pDestByte = ((*pDestByte) & 0xEF) | (valType << 4); // *pDestByte |= (valType << 4); break; case 4: *pDestByte = ((*pDestByte) & 0xF7) | (valType << 3); // *pDestByte |= (valType << 3); break; case 5: *pDestByte = ((*pDestByte) & 0xFB) | (valType << 2); // *pDestByte |= (valType << 2); break; case 6: *pDestByte = ((*pDestByte) & 0xFD) | (valType << 1); // *pDestByte |= (valType << 1); break; case 7: *pDestByte = ((*pDestByte) & 0xFE) | valType; // *pDestByte |= (valType); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } return TSDB_CODE_SUCCESS; } int32_t tdGetKvRowValOfCol(SCellVal *output, STSRow *pRow, void *pBitmap, int32_t offset, int16_t colIdx) { #ifdef TD_SUPPORT_BITMAP TASSERT(colIdx < tdRowGetNCols(pRow) - 1); if (tdGetBitmapValType(pBitmap, colIdx, &output->valType, 0) != TSDB_CODE_SUCCESS) { output->valType = TD_VTYPE_NONE; return terrno; } if (tdValTypeIsNorm(output->valType)) { if (offset < 0) { terrno = TSDB_CODE_INVALID_PARA; output->valType = TD_VTYPE_NONE; return terrno; } output->val = POINTER_SHIFT(pRow, offset); } #else TASSERT(0); if (offset < 0) { terrno = TSDB_CODE_INVALID_PARA; output->valType = TD_VTYPE_NONE; return terrno; } output->val = POINTER_SHIFT(pRow, offset); output->valType = isNull(output->val, colType) ? TD_VTYPE_NULL : TD_VTYPE_NORM; #endif return TSDB_CODE_SUCCESS; } int32_t tdGetTpRowValOfCol(SCellVal *output, STSRow *pRow, void *pBitmap, int8_t colType, int32_t offset, int16_t colIdx) { if (pRow->statis == 0) { output->valType = TD_VTYPE_NORM; if (IS_VAR_DATA_TYPE(colType)) { output->val = POINTER_SHIFT(pRow, *(VarDataOffsetT *)POINTER_SHIFT(TD_ROW_DATA(pRow), offset)); } else { output->val = POINTER_SHIFT(TD_ROW_DATA(pRow), offset); } return TSDB_CODE_SUCCESS; } if (tdGetBitmapValType(pBitmap, colIdx, &output->valType, 0) != TSDB_CODE_SUCCESS) { output->valType = TD_VTYPE_NONE; return terrno; } if (output->valType == TD_VTYPE_NORM) { if (IS_VAR_DATA_TYPE(colType)) { output->val = POINTER_SHIFT(pRow, *(VarDataOffsetT *)POINTER_SHIFT(TD_ROW_DATA(pRow), offset)); } else { output->val = POINTER_SHIFT(TD_ROW_DATA(pRow), offset); } } return TSDB_CODE_SUCCESS; } int32_t tdAppendColValToRow(SRowBuilder *pBuilder, col_id_t colId, int8_t colType, TDRowValT valType, const void *val, bool isCopyVarData, int32_t offset, col_id_t colIdx) { STSRow *pRow = pBuilder->pBuf; if (!val) { #ifdef TD_SUPPORT_BITMAP if (valType == TD_VTYPE_NORM) { terrno = TSDB_CODE_INVALID_PTR; return terrno; } #else TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; #endif } // TS KEY is stored in STSRow.ts and not included in STSRow.data field. if (colId == PRIMARYKEY_TIMESTAMP_COL_ID) { TD_ROW_KEY(pRow) = *(TSKEY *)val; // The primary TS key is Norm all the time, thus its valType is not stored in bitmap. return TSDB_CODE_SUCCESS; } // TODO: We can avoid the type judegement by FP, but would prevent the inline scheme. switch (valType) { case TD_VTYPE_NORM: break; case TD_VTYPE_NULL: if (!pBuilder->hasNull) pBuilder->hasNull = true; break; case TD_VTYPE_NONE: if (!pBuilder->hasNone) pBuilder->hasNone = true; return TSDB_CODE_SUCCESS; default: ASSERT(0); break; } if (TD_IS_TP_ROW(pRow)) { tdAppendColValToTpRow(pBuilder, valType, val, isCopyVarData, colType, colIdx, offset); } else { tdAppendColValToKvRow(pBuilder, valType, val, isCopyVarData, colType, colIdx, offset, colId); } return TSDB_CODE_SUCCESS; } int32_t tdAppendColValToKvRow(SRowBuilder *pBuilder, TDRowValT valType, const void *val, bool isCopyVarData, int8_t colType, int16_t colIdx, int32_t offset, col_id_t colId) { if ((offset < (int32_t)sizeof(SKvRowIdx)) || (colIdx < 1)) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } offset -= sizeof(SKvRowIdx); --colIdx; #ifdef TD_SUPPORT_BITMAP if (tdSetBitmapValType(pBuilder->pBitmap, colIdx, valType, 0) != TSDB_CODE_SUCCESS) { return terrno; } #endif STSRow *row = pBuilder->pBuf; // No need to store None/Null values. SKvRowIdx *pColIdx = (SKvRowIdx *)POINTER_SHIFT(TD_ROW_COL_IDX(row), offset); pColIdx->colId = colId; pColIdx->offset = TD_ROW_LEN(row); // the offset include the TD_ROW_HEAD_LEN if (valType == TD_VTYPE_NORM) { char *ptr = (char *)POINTER_SHIFT(row, TD_ROW_LEN(row)); if (IS_VAR_DATA_TYPE(colType)) { if (isCopyVarData) { memcpy(ptr, val, varDataTLen(val)); } TD_ROW_LEN(row) += varDataTLen(val); } else { memcpy(ptr, val, TYPE_BYTES[colType]); TD_ROW_LEN(row) += TYPE_BYTES[colType]; } } return 0; } int32_t tdAppendColValToTpRow(SRowBuilder *pBuilder, TDRowValT valType, const void *val, bool isCopyVarData, int8_t colType, int16_t colIdx, int32_t offset) { if ((offset < (int32_t)sizeof(TSKEY)) || (colIdx < 1)) { terrno = TSDB_CODE_INVALID_PARA; return terrno; } offset -= sizeof(TSKEY); --colIdx; #ifdef TD_SUPPORT_BITMAP if (tdSetBitmapValType(pBuilder->pBitmap, colIdx, valType, 0) != TSDB_CODE_SUCCESS) { return terrno; } #endif STSRow *row = pBuilder->pBuf; // 1. No need to set flen part for Null/None, just use bitmap. When upsert for the same primary TS key, the bitmap // should be updated simultaneously if Norm val overwrite Null/None cols. // 2. When consume STSRow in memory by taos client/tq, the output of Null/None cols should both be Null. if (valType == TD_VTYPE_NORM) { // TODO: The layout of new data types imported since 3.0 like blob/medium blob is the same with binary/nchar. if (IS_VAR_DATA_TYPE(colType)) { // ts key stored in STSRow.ts *(VarDataOffsetT *)POINTER_SHIFT(TD_ROW_DATA(row), offset) = TD_ROW_LEN(row); if (isCopyVarData) { memcpy(POINTER_SHIFT(row, TD_ROW_LEN(row)), val, varDataTLen(val)); } TD_ROW_LEN(row) += varDataTLen(val); } else { memcpy(POINTER_SHIFT(TD_ROW_DATA(row), offset), val, TYPE_BYTES[colType]); } } return 0; } int32_t tdSRowSetExtendedInfo(SRowBuilder *pBuilder, int32_t nCols, int32_t nBoundCols, int32_t flen, int32_t allNullLen, int32_t boundNullLen) { if ((boundNullLen > 0) && (allNullLen > 0) && (nBoundCols > 0)) { uint32_t tpLen = allNullLen; uint32_t kvLen = sizeof(col_id_t) + sizeof(SKvRowIdx) * nBoundCols + boundNullLen; if (isSelectKVRow(kvLen, tpLen)) { pBuilder->rowType = TD_ROW_KV; } else { pBuilder->rowType = TD_ROW_TP; } } else { pBuilder->rowType = TD_ROW_TP; } pBuilder->flen = flen; pBuilder->nCols = nCols; pBuilder->nBoundCols = nBoundCols; if (pBuilder->flen <= 0 || pBuilder->nCols <= 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } #ifdef TD_SUPPORT_BITMAP // the primary TS key is stored separatedly pBuilder->nBitmaps = (col_id_t)TD_BITMAP_BYTES(pBuilder->nCols - 1); if (nBoundCols > 0) { pBuilder->nBoundBitmaps = (col_id_t)TD_BITMAP_BYTES(pBuilder->nBoundCols - 1); } else { pBuilder->nBoundBitmaps = 0; } #else pBuilder->nBitmaps = 0; pBuilder->nBoundBitmaps = 0; #endif return TSDB_CODE_SUCCESS; } int32_t tdSRowResetBuf(SRowBuilder *pBuilder, void *pBuf) { pBuilder->pBuf = (STSRow *)pBuf; if (!pBuilder->pBuf) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } if (pBuilder->hasNone) pBuilder->hasNone = false; if (pBuilder->hasNull) pBuilder->hasNull = false; TD_ROW_SET_INFO(pBuilder->pBuf, 0); TD_ROW_SET_TYPE(pBuilder->pBuf, pBuilder->rowType); TASSERT(pBuilder->nBitmaps > 0 && pBuilder->flen > 0); uint32_t len = 0; switch (pBuilder->rowType) { case TD_ROW_TP: #ifdef TD_SUPPORT_BITMAP pBuilder->pBitmap = tdGetBitmapAddrTp(pBuilder->pBuf, pBuilder->flen); memset(pBuilder->pBitmap, TD_VTYPE_NONE_BYTE_II, pBuilder->nBitmaps); #endif // the primary TS key is stored separatedly len = TD_ROW_HEAD_LEN + pBuilder->flen - sizeof(TSKEY) + pBuilder->nBitmaps; TD_ROW_SET_LEN(pBuilder->pBuf, len); TD_ROW_SET_SVER(pBuilder->pBuf, pBuilder->sver); break; case TD_ROW_KV: #ifdef TD_SUPPORT_BITMAP pBuilder->pBitmap = tdGetBitmapAddrKv(pBuilder->pBuf, pBuilder->nBoundCols); memset(pBuilder->pBitmap, TD_VTYPE_NONE_BYTE_II, pBuilder->nBoundBitmaps); #endif len = TD_ROW_HEAD_LEN + TD_ROW_NCOLS_LEN + (pBuilder->nBoundCols - 1) * sizeof(SKvRowIdx) + pBuilder->nBoundBitmaps; // add TD_ROW_SET_LEN(pBuilder->pBuf, len); TD_ROW_SET_SVER(pBuilder->pBuf, pBuilder->sver); TD_ROW_SET_NCOLS(pBuilder->pBuf, pBuilder->nBoundCols); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } return TSDB_CODE_SUCCESS; } int32_t tdSRowGetBuf(SRowBuilder *pBuilder, void *pBuf) { pBuilder->pBuf = (STSRow *)pBuf; if (!pBuilder->pBuf) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } TASSERT(pBuilder->nBitmaps > 0 && pBuilder->flen > 0); uint32_t len = 0; switch (pBuilder->rowType) { case TD_ROW_TP: #ifdef TD_SUPPORT_BITMAP pBuilder->pBitmap = tdGetBitmapAddrTp(pBuilder->pBuf, pBuilder->flen); #endif break; case TD_ROW_KV: #ifdef TD_SUPPORT_BITMAP pBuilder->pBitmap = tdGetBitmapAddrKv(pBuilder->pBuf, pBuilder->nBoundCols); #endif break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } return TSDB_CODE_SUCCESS; } void tdSRowReset(SRowBuilder *pBuilder) { pBuilder->rowType = TD_ROW_TP; pBuilder->pBuf = NULL; pBuilder->nBoundCols = -1; pBuilder->nCols = -1; pBuilder->flen = -1; pBuilder->pBitmap = NULL; } int32_t tdSRowSetTpInfo(SRowBuilder *pBuilder, int32_t nCols, int32_t flen) { pBuilder->flen = flen; pBuilder->nCols = nCols; if (pBuilder->flen <= 0 || pBuilder->nCols <= 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } #ifdef TD_SUPPORT_BITMAP // the primary TS key is stored separatedly pBuilder->nBitmaps = (int16_t)TD_BITMAP_BYTES(pBuilder->nCols - 1); #else pBuilder->nBitmaps = 0; pBuilder->nBoundBitmaps = 0; #endif return TSDB_CODE_SUCCESS; } int32_t tdSRowSetInfo(SRowBuilder *pBuilder, int32_t nCols, int32_t nBoundCols, int32_t flen) { pBuilder->flen = flen; pBuilder->nCols = nCols; pBuilder->nBoundCols = nBoundCols; if (pBuilder->flen <= 0 || pBuilder->nCols <= 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } #ifdef TD_SUPPORT_BITMAP // the primary TS key is stored separatedly pBuilder->nBitmaps = (int16_t)TD_BITMAP_BYTES(pBuilder->nCols - 1); if (nBoundCols > 0) { pBuilder->nBoundBitmaps = (int16_t)TD_BITMAP_BYTES(pBuilder->nBoundCols - 1); } else { pBuilder->nBoundBitmaps = 0; } #else pBuilder->nBitmaps = 0; pBuilder->nBoundBitmaps = 0; #endif return TSDB_CODE_SUCCESS; } int32_t tdGetBitmapValType(const void *pBitmap, int16_t colIdx, TDRowValT *pValType, int8_t bitmapMode) { switch (bitmapMode) { case 0: tdGetBitmapValTypeII(pBitmap, colIdx, pValType); break; case -1: case 1: tdGetBitmapValTypeI(pBitmap, colIdx, pValType); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return TSDB_CODE_FAILED; } return TSDB_CODE_SUCCESS; } bool tdIsBitmapValTypeNorm(const void *pBitmap, int16_t idx, int8_t bitmapMode) { TDRowValT valType = 0; tdGetBitmapValType(pBitmap, idx, &valType, bitmapMode); if (tdValTypeIsNorm(valType)) { return true; } return false; } int32_t tdSetBitmapValTypeII(void *pBitmap, int16_t colIdx, TDRowValT valType) { if (!pBitmap || colIdx < 0) { TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } int16_t nBytes = colIdx / TD_VTYPE_PARTS; int16_t nOffset = colIdx & TD_VTYPE_OPTR; char *pDestByte = (char *)POINTER_SHIFT(pBitmap, nBytes); // use literal value directly and not use formula to simplify the codes switch (nOffset) { case 0: *pDestByte = ((*pDestByte) & 0x3F) | (valType << 6); // set the value and clear other partitions for offset 0 // *pDestByte |= (valType << 6); break; case 1: *pDestByte = ((*pDestByte) & 0xCF) | (valType << 4); // *pDestByte |= (valType << 4); break; case 2: *pDestByte = ((*pDestByte) & 0xF3) | (valType << 2); // *pDestByte |= (valType << 2); break; case 3: *pDestByte = ((*pDestByte) & 0xFC) | valType; // *pDestByte |= (valType); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return terrno; } return TSDB_CODE_SUCCESS; } int32_t tdSetBitmapValType(void *pBitmap, int16_t colIdx, TDRowValT valType, int8_t bitmapMode) { switch (bitmapMode) { case 0: tdSetBitmapValTypeII(pBitmap, colIdx, valType); break; case -1: case 1: tdSetBitmapValTypeI(pBitmap, colIdx, valType); break; default: TASSERT(0); terrno = TSDB_CODE_INVALID_PARA; return TSDB_CODE_FAILED; } return TSDB_CODE_SUCCESS; } void *tdGetBitmapAddr(STSRow *pRow, uint8_t rowType, uint32_t flen, col_id_t nKvCols) { #ifdef TD_SUPPORT_BITMAP switch (rowType) { case TD_ROW_TP: return tdGetBitmapAddrTp(pRow, flen); case TD_ROW_KV: return tdGetBitmapAddrKv(pRow, nKvCols); default: break; } #endif return NULL; } void tdSTSRowIterReset(STSRowIter *pIter, STSRow *pRow) { pIter->pRow = pRow; pIter->pBitmap = tdGetBitmapAddr(pRow, pRow->type, pIter->pSchema->flen, tdRowGetNCols(pRow)); pIter->offset = 0; pIter->colIdx = 0; // PRIMARYKEY_TIMESTAMP_COL_ID; pIter->kvIdx = 0; } void tdSTSRowIterInit(STSRowIter *pIter, STSchema *pSchema) { pIter->pSchema = pSchema; pIter->maxColId = pSchema->columns[pSchema->numOfCols - 1].colId; } void tTSRowGetVal(STSRow *pRow, STSchema *pTSchema, int16_t iCol, SColVal *pColVal) { STColumn *pTColumn = &pTSchema->columns[iCol]; SCellVal cv; SValue value; ASSERT((pTColumn->colId == PRIMARYKEY_TIMESTAMP_COL_ID) || (iCol > 0)); if (TD_IS_TP_ROW(pRow)) { tdSTpRowGetVal(pRow, pTColumn->colId, pTColumn->type, pTSchema->flen, pTColumn->offset, iCol - 1, &cv); } else if (TD_IS_KV_ROW(pRow)) { tdSKvRowGetVal(pRow, pTColumn->colId, iCol - 1, &cv); } else { ASSERT(0); } if (tdValTypeIsNone(cv.valType)) { *pColVal = COL_VAL_NONE(pTColumn->colId, pTColumn->type); } else if (tdValTypeIsNull(cv.valType)) { *pColVal = COL_VAL_NULL(pTColumn->colId, pTColumn->type); } else { if (IS_VAR_DATA_TYPE(pTColumn->type)) { value.nData = varDataLen(cv.val); value.pData = varDataVal(cv.val); } else { tGetValue(cv.val, &value, pTColumn->type); } *pColVal = COL_VAL_VALUE(pTColumn->colId, pTColumn->type, value); } }