/* * 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 "parserUtil.h" #include #include #include "function.h" #include "parser.h" #include "parserInt.h" #include "queryInfoUtil.h" #include "taoserror.h" #include "tbuffer.h" #include "thash.h" #include "tmsg.h" #include "tmsgtype.h" #include "ttypes.h" #include "tutil.h" typedef struct STableFilterCond { uint64_t uid; int16_t idx; //table index int32_t len; // length of tag query condition data char * cond; } STableFilterCond; static STableMetaInfo* addTableMetaInfo(SQueryStmtInfo* pQueryInfo, SName* name, STableMeta* pTableMeta, SVgroupsInfo* vgroupList, SArray* pTagCols, SArray* pVgroupTables); int32_t parserValidateIdToken(SToken* pToken) { if (pToken == NULL || pToken->z == NULL || pToken->type != TK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } // it is a token quoted with escape char '`' if (pToken->z[0] == TS_ESCAPE_CHAR && pToken->z[pToken->n - 1] == TS_ESCAPE_CHAR) { return TSDB_CODE_SUCCESS; } char* sep = strnchr(pToken->z, TS_PATH_DELIMITER[0], pToken->n, true); if (sep == NULL) { // It is a single part token, not a complex type if (isNumber(pToken)) { return TSDB_CODE_TSC_INVALID_OPERATION; } strntolower(pToken->z, pToken->z, pToken->n); } else { // two part int32_t oldLen = pToken->n; char* pStr = pToken->z; if (pToken->type == TK_SPACE) { pToken->n = (uint32_t)strtrim(pToken->z); } pToken->n = tGetToken(pToken->z, &pToken->type); if (pToken->z[pToken->n] != TS_PATH_DELIMITER[0]) { return TSDB_CODE_TSC_INVALID_OPERATION; } if (pToken->type != TK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } int32_t firstPartLen = pToken->n; pToken->z = sep + 1; pToken->n = (uint32_t)(oldLen - (sep - pStr) - 1); int32_t len = tGetToken(pToken->z, &pToken->type); if (len != pToken->n || pToken->type != TK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } // re-build the whole name string if (pStr[firstPartLen] == TS_PATH_DELIMITER[0]) { // first part do not have quote do nothing } else { pStr[firstPartLen] = TS_PATH_DELIMITER[0]; memmove(&pStr[firstPartLen + 1], pToken->z, pToken->n); uint32_t offset = (uint32_t)(pToken->z - (pStr + firstPartLen + 1)); memset(pToken->z + pToken->n - offset, ' ', offset); } pToken->n += (firstPartLen + sizeof(TS_PATH_DELIMITER[0])); pToken->z = pStr; strntolower(pToken->z, pToken->z, pToken->n); } return TSDB_CODE_SUCCESS; } int32_t parserValidatePassword(SToken* pToken, SMsgBuf* pMsgBuf) { const char* msg1 = "password can not be empty"; const char* msg2 = "name or password too long"; const char* msg3 = "password needs single quote marks enclosed"; if (pToken->type != TK_STRING) { return buildInvalidOperationMsg(pMsgBuf, msg3); } strdequote(pToken->z); pToken->n = (uint32_t)strtrim(pToken->z); // trim space before and after passwords if (pToken->n <= 0) { return buildInvalidOperationMsg(pMsgBuf, msg1); } if (pToken->n >= TSDB_USET_PASSWORD_LEN) { return buildInvalidOperationMsg(pMsgBuf, msg2); } return TSDB_CODE_SUCCESS; } int32_t parserValidateNameToken(SToken* pToken) { if (pToken == NULL || pToken->z == NULL || pToken->type != TK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } // it is a token quoted with escape char '`' if (pToken->z[0] == TS_ESCAPE_CHAR && pToken->z[pToken->n - 1] == TS_ESCAPE_CHAR) { return TSDB_CODE_SUCCESS; } char* sep = strnchr(pToken->z, TS_PATH_DELIMITER[0], pToken->n, true); if (sep != NULL) { // It is a complex type, not allow return TSDB_CODE_TSC_INVALID_OPERATION; } strntolower(pToken->z, pToken->z, pToken->n); return TSDB_CODE_SUCCESS; } int32_t buildInvalidOperationMsg(SMsgBuf* pBuf, const char* msg) { strncpy(pBuf->buf, msg, pBuf->len); return TSDB_CODE_TSC_INVALID_OPERATION; } int32_t buildSyntaxErrMsg(SMsgBuf* pBuf, const char* additionalInfo, const char* sourceStr) { const char* msgFormat1 = "syntax error near \'%s\'"; const char* msgFormat2 = "syntax error near \'%s\' (%s)"; const char* msgFormat3 = "%s"; const char* prefix = "syntax error"; if (sourceStr == NULL) { assert(additionalInfo != NULL); snprintf(pBuf->buf, pBuf->len, msgFormat1, additionalInfo); return TSDB_CODE_TSC_SQL_SYNTAX_ERROR; } char buf[64] = {0}; // only extract part of sql string strncpy(buf, sourceStr, tListLen(buf) - 1); if (additionalInfo != NULL) { snprintf(pBuf->buf, pBuf->len, msgFormat2, buf, additionalInfo); } else { const char* msgFormat = (0 == strncmp(sourceStr, prefix, strlen(prefix))) ? msgFormat3 : msgFormat1; snprintf(pBuf->buf, pBuf->len, msgFormat, buf); } return TSDB_CODE_TSC_SQL_SYNTAX_ERROR; } SCond* getSTableQueryCond(STagCond* pTagCond, uint64_t uid) { if (pTagCond->pCond == NULL) { return NULL; } size_t size = taosArrayGetSize(pTagCond->pCond); for (int32_t i = 0; i < size; ++i) { SCond* pCond = taosArrayGet(pTagCond->pCond, i); if (uid == pCond->uid) { return pCond; } } return NULL; } STableFilterCond* tsGetTableFilter(SArray* filters, uint64_t uid, int16_t idx) { if (filters == NULL) { return NULL; } size_t size = taosArrayGetSize(filters); for (int32_t i = 0; i < size; ++i) { STableFilterCond* cond = taosArrayGet(filters, i); if (uid == cond->uid && (idx >= 0 && cond->idx == idx)) { return cond; } } return NULL; } void setSTableQueryCond(STagCond* pTagCond, uint64_t uid, SBufferWriter* bw) { if (tbufTell(bw) == 0) { return; } SCond cond = { .uid = uid, .len = (int32_t)(tbufTell(bw)), .cond = NULL, }; cond.cond = tbufGetData(bw, true); if (pTagCond->pCond == NULL) { pTagCond->pCond = taosArrayInit(3, sizeof(SCond)); } taosArrayPush(pTagCond->pCond, &cond); } //typedef struct SJoinStatus { // SSDataBlock* pBlock; // point to the upstream block // int32_t index; // bool completed;// current upstream is completed or not //} SJoinStatus; /* static void createInputDataFilterInfo(SQueryStmtInfo* px, int32_t numOfCol1, int32_t* numOfFilterCols, SSingleColumnFilterInfo** pFilterInfo) { SColumnInfo* tableCols = calloc(numOfCol1, sizeof(SColumnInfo)); for(int32_t i = 0; i < numOfCol1; ++i) { SColumn* pCol = taosArrayGetP(px->colList, i); if (pCol->info.flist.numOfFilters > 0) { (*numOfFilterCols) += 1; } tableCols[i] = pCol->info; } if ((*numOfFilterCols) > 0) { doCreateFilterInfo(tableCols, numOfCol1, (*numOfFilterCols), pFilterInfo, 0); } tfree(tableCols); } */ //void destroyTableNameList(SInsertStatementParam* pInsertParam) { // if (pInsertParam->numOfTables == 0) { // assert(pInsertParam->pTableNameList == NULL); // return; // } // // for(int32_t i = 0; i < pInsertParam->numOfTables; ++i) { // tfree(pInsertParam->pTableNameList[i]); // } // // pInsertParam->numOfTables = 0; // tfree(pInsertParam->pTableNameList); //} //void tscDestroyBoundColumnInfo(SParsedDataColInfo* pColInfo) { // tfree(pColInfo->boundedColumns); // tfree(pColInfo->cols); // tfree(pColInfo->colIdxInfo); //} // //void tscDestroyDataBlock(STableDataBlocks* pDataBlock, bool removeMeta) { // if (pDataBlock == NULL) { // return; // } // // tfree(pDataBlock->pData); // // if (removeMeta) { // char name[TSDB_TABLE_FNAME_LEN] = {0}; // tNameExtractFullName(&pDataBlock->tableName, name); // // taosHashRemove(tscTableMetaMap, name, strnlen(name, TSDB_TABLE_FNAME_LEN)); // } // // if (!pDataBlock->cloned) { // tfree(pDataBlock->params); // // // free the refcount for metermeta // if (pDataBlock->pTableMeta != NULL) { // tfree(pDataBlock->pTableMeta); // } // // tscDestroyBoundColumnInfo(&pDataBlock->boundColumnInfo); // } // // tfree(pDataBlock); //} //SParamInfo* tscAddParamToDataBlock(STableDataBlocks* pDataBlock, char type, uint8_t timePrec, int16_t bytes, // uint32_t offset) { // uint32_t needed = pDataBlock->numOfParams + 1; // if (needed > pDataBlock->numOfAllocedParams) { // needed *= 2; // void* tmp = realloc(pDataBlock->params, needed * sizeof(SParamInfo)); // if (tmp == NULL) { // return NULL; // } // pDataBlock->params = (SParamInfo*)tmp; // pDataBlock->numOfAllocedParams = needed; // } // // SParamInfo* param = pDataBlock->params + pDataBlock->numOfParams; // param->idx = -1; // param->type = type; // param->timePrec = timePrec; // param->bytes = bytes; // param->offset = offset; // // ++pDataBlock->numOfParams; // return param; //} //void* tscDestroyBlockArrayList(SArray* pDataBlockList) { // if (pDataBlockList == NULL) { // return NULL; // } // // size_t size = taosArrayGetSize(pDataBlockList); // for (int32_t i = 0; i < size; i++) { // void* d = taosArrayGetP(pDataBlockList, i); // tscDestroyDataBlock(d, false); // } // // taosArrayDestroy(pDataBlockList); // return NULL; //} //void freeUdfInfo(SUdfInfo* pUdfInfo) { // if (pUdfInfo == NULL) { // return; // } // // if (pUdfInfo->funcs[TSDB_UDF_FUNC_DESTROY]) { // (*(udfDestroyFunc)pUdfInfo->funcs[TSDB_UDF_FUNC_DESTROY])(&pUdfInfo->init); // } // // tfree(pUdfInfo->name); // // if (pUdfInfo->path) { // unlink(pUdfInfo->path); // } // // tfree(pUdfInfo->path); // // tfree(pUdfInfo->content); // // taosCloseDll(pUdfInfo->handle); //} //void* tscDestroyUdfArrayList(SArray* pUdfList) { // if (pUdfList == NULL) { // return NULL; // } // // size_t size = taosArrayGetSize(pUdfList); // for (int32_t i = 0; i < size; i++) { // SUdfInfo* udf = taosArrayGet(pUdfList, i); // freeUdfInfo(udf); // } // // taosArrayDestroy(pUdfList); // return NULL; //} //void* tscDestroyBlockHashTable(SHashObj* pBlockHashTable, bool removeMeta) { // if (pBlockHashTable == NULL) { // return NULL; // } // // STableDataBlocks** p = taosHashIterate(pBlockHashTable, NULL); // while(p) { // tscDestroyDataBlock(*p, removeMeta); // p = taosHashIterate(pBlockHashTable, p); // } // // taosHashCleanup(pBlockHashTable); // return NULL; //} /** * create the in-memory buffer for each table to keep the submitted data block * @param initialSize * @param rowSize * @param startOffset * @param name * @param dataBlocks * @return */ //int32_t tscCreateDataBlock(size_t defaultSize, int32_t rowSize, int32_t startOffset, SName* name, // STableMeta* pTableMeta, STableDataBlocks** dataBlocks) { // STableDataBlocks* dataBuf = (STableDataBlocks*)calloc(1, sizeof(STableDataBlocks)); // if (dataBuf == NULL) { // tscError("failed to allocated memory, reason:%s", strerror(errno)); // 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 = calloc(1, dataBuf->nAllocSize); // dataBuf->pData = malloc(dataBuf->nAllocSize); // if (dataBuf->pData == NULL) { // tscError("failed to allocated memory, reason:%s", strerror(errno)); // tfree(dataBuf); // return TSDB_CODE_TSC_OUT_OF_MEMORY; // } // memset(dataBuf->pData, 0, sizeof(SSubmitBlk)); // // //Here we keep the tableMeta to avoid it to be remove by other threads. // dataBuf->pTableMeta = tscTableMetaDup(pTableMeta); // // SParsedDataColInfo* pColInfo = &dataBuf->boundColumnInfo; // SSchema* pSchema = getTableColumnSchema(dataBuf->pTableMeta); // tscSetBoundColumnInfo(pColInfo, pSchema, dataBuf->pTableMeta->tableInfo.numOfColumns); // // dataBuf->ordered = true; // dataBuf->prevTS = INT64_MIN; // dataBuf->rowSize = rowSize; // dataBuf->size = startOffset; // dataBuf->tsSource = -1; // dataBuf->vgId = dataBuf->pTableMeta->vgId; // // tNameAssign(&dataBuf->tableName, name); // // assert(defaultSize > 0 && pTableMeta != NULL && dataBuf->pTableMeta != NULL); // // *dataBlocks = dataBuf; // return TSDB_CODE_SUCCESS; //} // //int32_t tscGetDataBlockFromList(SHashObj* pHashList, int64_t id, int32_t size, int32_t startOffset, int32_t rowSize, // SName* name, STableMeta* pTableMeta, STableDataBlocks** dataBlocks, // SArray* pBlockList) { // *dataBlocks = NULL; // STableDataBlocks** t1 = (STableDataBlocks**)taosHashGet(pHashList, (const char*)&id, sizeof(id)); // if (t1 != NULL) { // *dataBlocks = *t1; // } // // if (*dataBlocks == NULL) { // int32_t ret = tscCreateDataBlock((size_t)size, rowSize, startOffset, name, pTableMeta, dataBlocks); // if (ret != TSDB_CODE_SUCCESS) { // return ret; // } // // taosHashPut(pHashList, (const char*)&id, sizeof(int64_t), (char*)dataBlocks, POINTER_BYTES); // if (pBlockList) { // taosArrayPush(pBlockList, dataBlocks); // } // } // // return TSDB_CODE_SUCCESS; //} // //// Erase the empty space reserved for binary data //static int trimDataBlock(void* pDataBlock, STableDataBlocks* pTableDataBlock, SInsertStatementParam* insertParam, // SBlockKeyTuple* blkKeyTuple) { // // TODO: optimize this function, handle the case while binary is not presented // STableMeta* pTableMeta = pTableDataBlock->pTableMeta; // STableComInfo tinfo = tscGetTableInfo(pTableMeta); // SSchema* pSchema = getTableColumnSchema(pTableMeta); // // SSubmitBlk* pBlock = pDataBlock; // memcpy(pDataBlock, pTableDataBlock->pData, sizeof(SSubmitBlk)); // pDataBlock = (char*)pDataBlock + sizeof(SSubmitBlk); // // int32_t flen = 0; // original total length of row // // // schema needs to be included into the submit data block // if (insertParam->schemaAttached) { // int32_t numOfCols = tscGetNumOfColumns(pTableDataBlock->pTableMeta); // for(int32_t j = 0; j < numOfCols; ++j) { // STColumn* pCol = (STColumn*) pDataBlock; // pCol->colId = htons(pSchema[j].colId); // pCol->type = pSchema[j].type; // pCol->bytes = htons(pSchema[j].bytes); // pCol->offset = 0; // // pDataBlock = (char*)pDataBlock + sizeof(STColumn); // flen += TYPE_BYTES[pSchema[j].type]; // } // // int32_t schemaSize = sizeof(STColumn) * numOfCols; // pBlock->schemaLen = schemaSize; // } else { // if (IS_RAW_PAYLOAD(insertParam->payloadType)) { // for (int32_t j = 0; j < tinfo.numOfColumns; ++j) { // flen += TYPE_BYTES[pSchema[j].type]; // } // } // pBlock->schemaLen = 0; // } // // char* p = pTableDataBlock->pData + sizeof(SSubmitBlk); // pBlock->dataLen = 0; // int32_t numOfRows = htons(pBlock->numOfRows); // // if (IS_RAW_PAYLOAD(insertParam->payloadType)) { // for (int32_t i = 0; i < numOfRows; ++i) { // SMemRow memRow = (SMemRow)pDataBlock; // memRowSetType(memRow, SMEM_ROW_DATA); // SDataRow trow = memRowDataBody(memRow); // dataRowSetLen(trow, (uint16_t)(TD_DATA_ROW_HEAD_SIZE + flen)); // dataRowSetVersion(trow, pTableMeta->sversion); // // int toffset = 0; // for (int32_t j = 0; j < tinfo.numOfColumns; j++) { // tdAppendColVal(trow, p, pSchema[j].type, toffset); // toffset += TYPE_BYTES[pSchema[j].type]; // p += pSchema[j].bytes; // } // // pDataBlock = (char*)pDataBlock + memRowTLen(memRow); // pBlock->dataLen += memRowTLen(memRow); // } // } else { // for (int32_t i = 0; i < numOfRows; ++i) { // char* payload = (blkKeyTuple + i)->payloadAddr; // if (isNeedConvertRow(payload)) { // convertSMemRow(pDataBlock, payload, pTableDataBlock); // TDRowTLenT rowTLen = memRowTLen(pDataBlock); // pDataBlock = POINTER_SHIFT(pDataBlock, rowTLen); // pBlock->dataLen += rowTLen; // } else { // TDRowTLenT rowTLen = memRowTLen(payload); // memcpy(pDataBlock, payload, rowTLen); // pDataBlock = POINTER_SHIFT(pDataBlock, rowTLen); // pBlock->dataLen += rowTLen; // } // } // } // // int32_t len = pBlock->dataLen + pBlock->schemaLen; // pBlock->dataLen = htonl(pBlock->dataLen); // pBlock->schemaLen = htonl(pBlock->schemaLen); // // return len; //} TAOS_FIELD createField(const SSchema* pSchema) { TAOS_FIELD f = { .type = pSchema->type, .bytes = pSchema->bytes, }; tstrncpy(f.name, pSchema->name, sizeof(f.name)); return f; } void setColumn(SColumn* pColumn, uint64_t uid, const char* tableName, int8_t flag, const SSchema* pSchema) { pColumn->uid = uid; pColumn->flag = flag; pColumn->info.colId = pSchema->colId; pColumn->info.bytes = pSchema->bytes; pColumn->info.type = pSchema->type; if (tableName != NULL) { snprintf(pColumn->name, tListLen(pColumn->name), "%s.%s", tableName, pSchema->name); } else { tstrncpy(pColumn->name, pSchema->name, tListLen(pColumn->name)); } } SColumn createColumn(uint64_t uid, const char* tableName, int8_t flag, const SSchema* pSchema) { SColumn c; c.uid = uid; c.flag = flag; c.info.colId = pSchema->colId; c.info.bytes = pSchema->bytes; c.info.type = pSchema->type; if (tableName != NULL) { snprintf(c.name, tListLen(c.name), "%s.%s", tableName, pSchema->name); } else { tstrncpy(c.name, pSchema->name, tListLen(c.name)); } return c; } void addIntoSourceParam(SSourceParam* pSourceParam, tExprNode* pNode, SColumn* pColumn) { assert(pSourceParam != NULL); pSourceParam->num += 1; if (pSourceParam->pExprNodeList != NULL) { assert(pNode != NULL && pColumn == NULL); if (pSourceParam->pExprNodeList == NULL) { pSourceParam->pExprNodeList = taosArrayInit(4, POINTER_BYTES); } taosArrayPush(pSourceParam->pExprNodeList, &pNode); } else { assert(pColumn != NULL); if (pSourceParam->pColumnList == NULL) { pSourceParam->pColumnList = taosArrayInit(4, POINTER_BYTES); } taosArrayPush(pSourceParam->pColumnList, &pColumn); } } int32_t getNumOfFields(SFieldInfo* pFieldInfo) { return pFieldInfo->numOfOutput; } SInternalField* appendFieldInfo(SFieldInfo* pFieldInfo, TAOS_FIELD* pField) { assert(pFieldInfo != NULL); pFieldInfo->numOfOutput++; struct SInternalField info = { .pExpr = NULL, .visible = true }; info.field = *pField; return taosArrayPush(pFieldInfo->internalField, &info); } SInternalField* insertFieldInfo(SFieldInfo* pFieldInfo, int32_t index, SSchema* pSchema) { pFieldInfo->numOfOutput++; struct SInternalField info = { .pExpr = NULL, .visible = true }; info.field.type = pSchema->type; info.field.bytes = pSchema->bytes; tstrncpy(info.field.name, pSchema->name, tListLen(pSchema->name)); return taosArrayInsert(pFieldInfo->internalField, index, &info); } void fieldInfoUpdateOffset(SQueryStmtInfo* pQueryInfo) { int32_t offset = 0; size_t numOfExprs = getNumOfExprs(pQueryInfo); SArray* pList = getCurrentExprList(pQueryInfo); for (int32_t i = 0; i < numOfExprs; ++i) { SExprInfo* p = taosArrayGetP(pList, i); // p->base.offset = offset; offset += p->base.resSchema.bytes; } } SInternalField* getInternalField(SFieldInfo* pFieldInfo, int32_t index) { assert(index < pFieldInfo->numOfOutput); return TARRAY_GET_ELEM(pFieldInfo->internalField, index); } TAOS_FIELD* getFieldInfo(SFieldInfo* pFieldInfo, int32_t index) { assert(index < pFieldInfo->numOfOutput); return &((SInternalField*)TARRAY_GET_ELEM(pFieldInfo->internalField, index))->field; } int32_t fieldInfoCompare(const SFieldInfo* pFieldInfo1, const SFieldInfo* pFieldInfo2, int32_t *diffSize) { assert(pFieldInfo1 != NULL && pFieldInfo2 != NULL); if (pFieldInfo1->numOfOutput != pFieldInfo2->numOfOutput) { return pFieldInfo1->numOfOutput - pFieldInfo2->numOfOutput; } for (int32_t i = 0; i < pFieldInfo1->numOfOutput; ++i) { TAOS_FIELD* pField1 = getFieldInfo((SFieldInfo*) pFieldInfo1, i); TAOS_FIELD* pField2 = getFieldInfo((SFieldInfo*) pFieldInfo2, i); if (pField1->type != pField2->type || strcasecmp(pField1->name, pField2->name) != 0) { return 1; } if (pField1->bytes != pField2->bytes) { *diffSize = 1; if (pField2->bytes > pField1->bytes) { assert(IS_VAR_DATA_TYPE(pField1->type)); pField1->bytes = pField2->bytes; } } } return 0; } int32_t getFieldInfoSize(const SFieldInfo* pFieldInfo1, const SFieldInfo* pFieldInfo2) { assert(pFieldInfo1 != NULL && pFieldInfo2 != NULL); for (int32_t i = 0; i < pFieldInfo1->numOfOutput; ++i) { TAOS_FIELD* pField1 = getFieldInfo((SFieldInfo*) pFieldInfo1, i); TAOS_FIELD* pField2 = getFieldInfo((SFieldInfo*) pFieldInfo2, i); pField2->bytes = pField1->bytes; } return 0; } static void destroyFilterInfo(SColumnFilterList* pFilterList) { if (pFilterList->filterInfo == NULL) { pFilterList->numOfFilters = 0; return; } for(int32_t i = 0; i < pFilterList->numOfFilters; ++i) { if (pFilterList->filterInfo[i].filterstr) { tfree(pFilterList->filterInfo[i].pz); } } tfree(pFilterList->filterInfo); pFilterList->numOfFilters = 0; } void cleanupFieldInfo(SFieldInfo* pFieldInfo) { if (pFieldInfo == NULL) { return; } if (pFieldInfo->internalField != NULL) { size_t num = taosArrayGetSize(pFieldInfo->internalField); for (int32_t i = 0; i < num; ++i) { // SInternalField* pfield = taosArrayGet(pFieldInfo->internalField, i); // if (pfield->pExpr != NULL && pfield->pExpr->pExpr != NULL) { // sqlExprDestroy(pfield->pExpr); // } } } taosArrayDestroy(pFieldInfo->internalField); // tfree(pFieldInfo->final); memset(pFieldInfo, 0, sizeof(SFieldInfo)); } void copyFieldInfo(SFieldInfo* pFieldInfo, const SFieldInfo* pSrc, const SArray* pExprList) { assert(pFieldInfo != NULL && pSrc != NULL && pExprList != NULL); pFieldInfo->numOfOutput = pSrc->numOfOutput; if (pSrc->final != NULL) { pFieldInfo->final = calloc(pSrc->numOfOutput, sizeof(TAOS_FIELD)); memcpy(pFieldInfo->final, pSrc->final, sizeof(TAOS_FIELD) * pSrc->numOfOutput); } if (pSrc->internalField != NULL) { size_t num = taosArrayGetSize(pSrc->internalField); size_t numOfExpr = taosArrayGetSize(pExprList); for (int32_t i = 0; i < num; ++i) { SInternalField* pfield = taosArrayGet(pSrc->internalField, i); SInternalField p = {.visible = pfield->visible, .field = pfield->field}; bool found = false; int32_t resColId = pfield->pExpr->base.resSchema.colId; for(int32_t j = 0; j < numOfExpr; ++j) { SExprInfo* pExpr = taosArrayGetP(pExprList, j); if (pExpr->base.resSchema.colId == resColId) { p.pExpr = pExpr; found = true; break; } } if (!found) { assert(pfield->pExpr->pExpr != NULL); p.pExpr = calloc(1, sizeof(SExprInfo)); assignExprInfo(p.pExpr, pfield->pExpr); } taosArrayPush(pFieldInfo->internalField, &p); } } } // ignore the tbname columnIndex to be inserted into source list int32_t columnExists(SArray* pColumnList, int32_t columnId, uint64_t uid) { size_t numOfCols = taosArrayGetSize(pColumnList); int32_t i = 0; while (i < numOfCols) { SColumn* pCol = taosArrayGetP(pColumnList, i); if ((pCol->info.colId != columnId) || (pCol->uid != uid)) { ++i; continue; } else { break; } } if (i >= numOfCols || numOfCols == 0) { return -1; } return i; } static int32_t doFindPosition(const SArray* pColumnList, uint64_t uid, const SSchema* pSchema) { int32_t i = 0; size_t numOfCols = taosArrayGetSize(pColumnList); while (i < numOfCols) { SColumn* pCol = taosArrayGetP(pColumnList, i); if (pCol->uid < uid) { i++; continue; } if (pCol->info.colId < pSchema->colId) { i++; continue; } break; } return i; } SColumn* columnListInsert(SArray* pColumnList, uint64_t uid, SSchema* pSchema, int32_t flag) { // ignore the tbname columnIndex to be inserted into source list assert(pSchema != NULL && pColumnList != NULL); int32_t i = doFindPosition(pColumnList, uid, pSchema); size_t size = taosArrayGetSize(pColumnList); if (size > 0 && i < size) { SColumn* pCol = taosArrayGetP(pColumnList, i); if (pCol->uid == uid && pCol->info.colId == pSchema->colId) { return pCol; } } SColumn* b = calloc(1, sizeof(SColumn)); if (b == NULL) { return NULL; } b->uid = uid; b->flag = flag; b->info.colId = pSchema->colId; b->info.bytes = pSchema->bytes; b->info.type = pSchema->type; tstrncpy(b->name, pSchema->name, tListLen(b->name)); taosArrayInsert(pColumnList, i, &b); return b; } SColumn* insertPrimaryTsColumn(SArray* pColumnList, const char* colName, uint64_t tableUid) { SSchema s = {.type = TSDB_DATA_TYPE_TIMESTAMP, .bytes = TSDB_KEYSIZE, .colId = PRIMARYKEY_TIMESTAMP_COL_ID}; strncpy(s.name, colName, tListLen(s.name)); return columnListInsert(pColumnList, tableUid, &s, TSDB_COL_NORMAL); } void columnCopy(SColumn* pDest, const SColumn* pSrc); SColumn* columnClone(const SColumn* src) { assert(src != NULL); SColumn* dst = calloc(1, sizeof(SColumn)); if (dst == NULL) { return NULL; } columnCopy(dst, src); return dst; } SColumnFilterInfo* tFilterInfoDup(const SColumnFilterInfo* src, int32_t numOfFilters) { if (numOfFilters == 0 || src == NULL) { assert(src == NULL); return NULL; } SColumnFilterInfo* pFilter = calloc(1, numOfFilters * sizeof(SColumnFilterInfo)); memcpy(pFilter, src, sizeof(SColumnFilterInfo) * numOfFilters); for (int32_t j = 0; j < numOfFilters; ++j) { if (pFilter[j].filterstr) { size_t len = (size_t) pFilter[j].len + 1 * TSDB_NCHAR_SIZE; pFilter[j].pz = (int64_t) calloc(1, len); memcpy((char*)pFilter[j].pz, (char*)src[j].pz, (size_t) pFilter[j].len); } } assert(src->filterstr == 0 || src->filterstr == 1); assert(!(src->lowerRelOptr == TSDB_RELATION_INVALID && src->upperRelOptr == TSDB_RELATION_INVALID)); return pFilter; } void columnCopy(SColumn* pDest, const SColumn* pSrc) { destroyFilterInfo(&pDest->info.flist); pDest->uid = pSrc->uid; pDest->info.flist.numOfFilters = pSrc->info.flist.numOfFilters; pDest->info.flist.filterInfo = tFilterInfoDup(pSrc->info.flist.filterInfo, pSrc->info.flist.numOfFilters); pDest->info.type = pSrc->info.type; pDest->info.colId = pSrc->info.colId; pDest->info.bytes = pSrc->info.bytes; } void columnListCopyAll(SArray* dst, const SArray* src) { assert(src != NULL && dst != NULL); size_t num = taosArrayGetSize(src); for (int32_t i = 0; i < num; ++i) { SColumn* pCol = taosArrayGetP(src, i); SColumn* p = columnClone(pCol); taosArrayPush(dst, &p); } } void columnListCopy(SArray* dst, const SArray* src, uint64_t uid) { assert(src != NULL && dst != NULL); size_t num = taosArrayGetSize(src); for (int32_t i = 0; i < num; ++i) { SColumn* pCol = taosArrayGetP(src, i); if (pCol->uid == uid) { SColumn* p = columnClone(pCol); taosArrayPush(dst, &p); } } } static void columnDestroy(SColumn* pCol) { destroyFilterInfo(&pCol->info.flist); free(pCol); } void columnListDestroy(SArray* pColumnList) { if (pColumnList == NULL) { return; } size_t num = taosArrayGetSize(pColumnList); for (int32_t i = 0; i < num; ++i) { SColumn* pCol = taosArrayGetP(pColumnList, i); columnDestroy(pCol); } taosArrayDestroy(pColumnList); } bool validateColumnId(STableMetaInfo* pTableMetaInfo, int32_t colId, int32_t numOfParams) { if (pTableMetaInfo->pTableMeta == NULL) { return false; } if (colId == TSDB_TBNAME_COLUMN_INDEX || (colId <= TSDB_UD_COLUMN_INDEX && numOfParams == 2)) { return true; } SSchema* pSchema = getTableColumnSchema(pTableMetaInfo->pTableMeta); STableComInfo tinfo = getTableInfo(pTableMetaInfo->pTableMeta); int32_t numOfTotal = tinfo.numOfTags + tinfo.numOfColumns; for (int32_t i = 0; i < numOfTotal; ++i) { if (pSchema[i].colId == colId) { return true; } } return false; } int32_t tscTagCondCopy(STagCond* dest, const STagCond* src) { memset(dest, 0, sizeof(STagCond)); if (src->tbnameCond.cond != NULL) { dest->tbnameCond.cond = strdup(src->tbnameCond.cond); if (dest->tbnameCond.cond == NULL) { return -1; } } dest->tbnameCond.uid = src->tbnameCond.uid; dest->tbnameCond.len = src->tbnameCond.len; dest->joinInfo.hasJoin = src->joinInfo.hasJoin; for (int32_t i = 0; i < TSDB_MAX_JOIN_TABLE_NUM; ++i) { if (src->joinInfo.joinTables[i]) { dest->joinInfo.joinTables[i] = calloc(1, sizeof(SJoinNode)); memcpy(dest->joinInfo.joinTables[i], src->joinInfo.joinTables[i], sizeof(SJoinNode)); if (src->joinInfo.joinTables[i]->tsJoin) { dest->joinInfo.joinTables[i]->tsJoin = taosArrayDup(src->joinInfo.joinTables[i]->tsJoin); } if (src->joinInfo.joinTables[i]->tagJoin) { dest->joinInfo.joinTables[i]->tagJoin = taosArrayDup(src->joinInfo.joinTables[i]->tagJoin); } } } dest->relType = src->relType; if (src->pCond == NULL) { return 0; } size_t s = taosArrayGetSize(src->pCond); dest->pCond = taosArrayInit(s, sizeof(SCond)); for (int32_t i = 0; i < s; ++i) { SCond* pCond = taosArrayGet(src->pCond, i); SCond c = {0}; c.len = pCond->len; c.uid = pCond->uid; if (pCond->len > 0) { assert(pCond->cond != NULL); c.cond = malloc(c.len); if (c.cond == NULL) { return -1; } memcpy(c.cond, pCond->cond, c.len); } taosArrayPush(dest->pCond, &c); } return 0; } int32_t tscColCondCopy(SArray** dest, const SArray* src, uint64_t uid, int16_t tidx) { if (src == NULL) { return 0; } size_t s = taosArrayGetSize(src); *dest = taosArrayInit(s, sizeof(SCond)); for (int32_t i = 0; i < s; ++i) { STableFilterCond* pCond = taosArrayGet(src, i); STableFilterCond c = {0}; if (tidx > 0) { if (!(pCond->uid == uid && pCond->idx == tidx)) { continue; } c.idx = 0; } else { c.idx = pCond->idx; } c.len = pCond->len; c.uid = pCond->uid; if (pCond->len > 0) { assert(pCond->cond != NULL); c.cond = malloc(c.len); if (c.cond == NULL) { return -1; } memcpy(c.cond, pCond->cond, c.len); } taosArrayPush(*dest, &c); } return 0; } void cleanupColumnCond(SArray** pCond) { if (*pCond == NULL) { return; } size_t s = taosArrayGetSize(*pCond); for (int32_t i = 0; i < s; ++i) { STableFilterCond* p = taosArrayGet(*pCond, i); tfree(p->cond); } taosArrayDestroy(*pCond); *pCond = NULL; } void cleanupTagCond(STagCond* pTagCond) { free(pTagCond->tbnameCond.cond); if (pTagCond->pCond != NULL) { size_t s = taosArrayGetSize(pTagCond->pCond); for (int32_t i = 0; i < s; ++i) { SCond* p = taosArrayGet(pTagCond->pCond, i); tfree(p->cond); } taosArrayDestroy(pTagCond->pCond); } for (int32_t i = 0; i < TSDB_MAX_JOIN_TABLE_NUM; ++i) { SJoinNode *node = pTagCond->joinInfo.joinTables[i]; if (node == NULL) { continue; } if (node->tsJoin != NULL) { taosArrayDestroy(node->tsJoin); } if (node->tagJoin != NULL) { taosArrayDestroy(node->tagJoin); } tfree(node); } memset(pTagCond, 0, sizeof(STagCond)); } //void tscGetSrcColumnInfo(SSrcColumnInfo* pColInfo, SQueryStmtInfo* pQueryInfo) { // STableMetaInfo* pTableMetaInfo = tscGetMetaInfo(pQueryInfo, 0); // SSchema* pSchema = getTableColumnSchema(pTableMetaInfo->pTableMeta); // // size_t numOfExprs = getNumOfExprs(pQueryInfo); // for (int32_t i = 0; i < numOfExprs; ++i) { // SExprInfo* pExpr = getExprInfo(pQueryInfo, i); // pColInfo[i].functionId = pExpr->base.functionId; // // if (TSDB_COL_IS_TAG(pExpr->base.colInfo.flag)) { // SSchema* pTagSchema = tscGetTableTagSchema(pTableMetaInfo->pTableMeta); // // int16_t index = pExpr->base.colInfo.colIndex; // pColInfo[i].type = (index != -1) ? pTagSchema[index].type : TSDB_DATA_TYPE_BINARY; // } else { // pColInfo[i].type = pSchema[pExpr->base.colInfo.colIndex].type; // } // } //} /** * * @param clauseIndex denote the index of the union sub clause, usually are 0, if no union query exists. * @param tableIndex denote the table index for join query, where more than one table exists * @return */ STableMetaInfo* getMetaInfo(const SQueryStmtInfo* pQueryInfo, int32_t tableIndex) { assert(pQueryInfo != NULL); if (pQueryInfo->pTableMetaInfo == NULL) { assert(pQueryInfo->numOfTables == 0); return NULL; } assert(tableIndex >= 0 && tableIndex <= pQueryInfo->numOfTables && pQueryInfo->pTableMetaInfo != NULL); return pQueryInfo->pTableMetaInfo[tableIndex]; } STableMetaInfo* getTableMetaInfoByUid(SQueryStmtInfo* pQueryInfo, uint64_t uid, int32_t* index) { int32_t k = -1; for (int32_t i = 0; i < pQueryInfo->numOfTables; ++i) { if (pQueryInfo->pTableMetaInfo[i]->pTableMeta->uid == uid) { k = i; break; } } if (index != NULL) { *index = k; } assert(k != -1); return getMetaInfo(pQueryInfo, k); } int32_t queryInfoCopy(SQueryStmtInfo* pQueryInfo, const SQueryStmtInfo* pSrc) { assert(pQueryInfo != NULL && pSrc != NULL); int32_t code = TSDB_CODE_SUCCESS; memcpy(&pQueryInfo->interval, &pSrc->interval, sizeof(pQueryInfo->interval)); pQueryInfo->command = pSrc->command; pQueryInfo->type = pSrc->type; pQueryInfo->window = pSrc->window; pQueryInfo->limit = pSrc->limit; pQueryInfo->slimit = pSrc->slimit; pQueryInfo->order = pSrc->order; pQueryInfo->vgroupLimit = pSrc->vgroupLimit; pQueryInfo->tsBuf = NULL; pQueryInfo->fillType = pSrc->fillType; pQueryInfo->fillVal = NULL; pQueryInfo->numOfFillVal = 0;; pQueryInfo->clauseLimit = pSrc->clauseLimit; pQueryInfo->prjOffset = pSrc->prjOffset; pQueryInfo->numOfTables = 0; pQueryInfo->window = pSrc->window; pQueryInfo->sessionWindow = pSrc->sessionWindow; pQueryInfo->pTableMetaInfo = NULL; pQueryInfo->bufLen = pSrc->bufLen; // pQueryInfo->orderProjectQuery = pSrc->orderProjectQuery; // pQueryInfo->arithmeticOnAgg = pSrc->arithmeticOnAgg; pQueryInfo->buf = malloc(pSrc->bufLen); if (pQueryInfo->buf == NULL) { code = TSDB_CODE_TSC_OUT_OF_MEMORY; goto _error; } if (pSrc->bufLen > 0) { memcpy(pQueryInfo->buf, pSrc->buf, pSrc->bufLen); } pQueryInfo->groupbyExpr = pSrc->groupbyExpr; if (pSrc->groupbyExpr.columnInfo != NULL) { pQueryInfo->groupbyExpr.columnInfo = taosArrayDup(pSrc->groupbyExpr.columnInfo); if (pQueryInfo->groupbyExpr.columnInfo == NULL) { code = TSDB_CODE_TSC_OUT_OF_MEMORY; goto _error; } } if (tscTagCondCopy(&pQueryInfo->tagCond, &pSrc->tagCond) != 0) { code = TSDB_CODE_TSC_OUT_OF_MEMORY; goto _error; } if (tscColCondCopy(&pQueryInfo->colCond, pSrc->colCond, 0, -1) != 0) { code = TSDB_CODE_TSC_OUT_OF_MEMORY; goto _error; } if (pSrc->fillType != TSDB_FILL_NONE) { pQueryInfo->fillVal = calloc(1, pSrc->fieldsInfo.numOfOutput * sizeof(int64_t)); if (pQueryInfo->fillVal == NULL) { code = TSDB_CODE_TSC_OUT_OF_MEMORY; goto _error; } pQueryInfo->numOfFillVal = pSrc->fieldsInfo.numOfOutput; memcpy(pQueryInfo->fillVal, pSrc->fillVal, pSrc->fieldsInfo.numOfOutput * sizeof(int64_t)); } if (copyAllExprInfo(pQueryInfo->exprList[0], pSrc->exprList[0], true) != 0) { code = TSDB_CODE_TSC_OUT_OF_MEMORY; goto _error; } columnListCopyAll(pQueryInfo->colList, pSrc->colList); copyFieldInfo(&pQueryInfo->fieldsInfo, &pSrc->fieldsInfo, pQueryInfo->exprList[0]); for(int32_t i = 0; i < pSrc->numOfTables; ++i) { STableMetaInfo* p1 = getMetaInfo((SQueryStmtInfo*) pSrc, i); STableMeta* pMeta = tableMetaDup(p1->pTableMeta); if (pMeta == NULL) { // todo handle the error } addTableMetaInfo(pQueryInfo, &p1->name, pMeta, p1->vgroupList, p1->tagColList, NULL); } SArray *pUdfInfo = NULL; if (pSrc->pUdfInfo) { pUdfInfo = taosArrayDup(pSrc->pUdfInfo); } pQueryInfo->pUdfInfo = pUdfInfo; _error: return code; } void clearAllTableMetaInfo(SQueryStmtInfo* pQueryInfo, bool removeMeta, uint64_t id) { for(int32_t i = 0; i < pQueryInfo->numOfTables; ++i) { STableMetaInfo* pTableMetaInfo = getMetaInfo(pQueryInfo, i); clearTableMetaInfo(pTableMetaInfo); } tfree(pQueryInfo->pTableMetaInfo); } STableMetaInfo* addTableMetaInfo(SQueryStmtInfo* pQueryInfo, SName* name, STableMeta* pTableMeta, SVgroupsInfo* vgroupList, SArray* pTagCols, SArray* pVgroupTables) { void* tmp = realloc(pQueryInfo->pTableMetaInfo, (pQueryInfo->numOfTables + 1) * POINTER_BYTES); if (tmp == NULL) { terrno = TSDB_CODE_TSC_OUT_OF_MEMORY; return NULL; } pQueryInfo->pTableMetaInfo = tmp; STableMetaInfo* pTableMetaInfo = calloc(1, sizeof(STableMetaInfo)); if (pTableMetaInfo == NULL) { terrno = TSDB_CODE_TSC_OUT_OF_MEMORY; return NULL; } pQueryInfo->pTableMetaInfo[pQueryInfo->numOfTables] = pTableMetaInfo; if (name != NULL) { tNameAssign(&pTableMetaInfo->name, name); } pTableMetaInfo->pTableMeta = pTableMeta; if (vgroupList != NULL) { // pTableMetaInfo->vgroupList = vgroupInfoClone(vgroupList); } // TODO handle malloc failure pTableMetaInfo->tagColList = taosArrayInit(4, POINTER_BYTES); if (pTableMetaInfo->tagColList == NULL) { return NULL; } if (pTagCols != NULL && pTableMetaInfo->pTableMeta != NULL) { columnListCopy(pTableMetaInfo->tagColList, pTagCols, pTableMetaInfo->pTableMeta->uid); } pQueryInfo->numOfTables += 1; return pTableMetaInfo; } STableMetaInfo* addEmptyMetaInfo(SQueryStmtInfo* pQueryInfo) { return addTableMetaInfo(pQueryInfo, NULL, NULL, NULL, NULL, NULL); } SInternalField* getInternalFieldInfo(SFieldInfo* pFieldInfo, int32_t index) { assert(index < pFieldInfo->numOfOutput); return TARRAY_GET_ELEM(pFieldInfo->internalField, index); } int32_t getNumOfInternalField(SFieldInfo* pFieldInfo) { return (int32_t) taosArrayGetSize(pFieldInfo->internalField); } static void doSetSqlExprAndResultFieldInfo(SQueryStmtInfo* pNewQueryInfo, int64_t uid) { int32_t numOfOutput = (int32_t)getNumOfExprs(pNewQueryInfo); if (numOfOutput == 0) { return; } // set the field info in pNewQueryInfo object according to sqlExpr information for (int32_t i = 0; i < numOfOutput; ++i) { SExprInfo* pExpr = getExprInfo(pNewQueryInfo, i); TAOS_FIELD f = createField(&pExpr->base.resSchema); SInternalField* pInfo1 = appendFieldInfo(&pNewQueryInfo->fieldsInfo, &f); pInfo1->pExpr = pExpr; } // update the pSqlExpr pointer in SInternalField according the field name // make sure the pSqlExpr point to the correct SqlExpr in pNewQueryInfo, not SqlExpr in pQueryInfo for (int32_t f = 0; f < pNewQueryInfo->fieldsInfo.numOfOutput; ++f) { TAOS_FIELD* field = getFieldInfo(&pNewQueryInfo->fieldsInfo, f); bool matched = false; for (int32_t k1 = 0; k1 < numOfOutput; ++k1) { SExprInfo* pExpr1 = getExprInfo(pNewQueryInfo, k1); if (strcmp(field->name, pExpr1->base.resSchema.name) == 0) { // establish link according to the result field name SInternalField* pInfo = getInternalFieldInfo(&pNewQueryInfo->fieldsInfo, f); pInfo->pExpr = pExpr1; matched = true; break; } } assert(matched); (void)matched; } // updateFieldInfoOffset(pNewQueryInfo); } int16_t getJoinTagColIdByUid(STagCond* pTagCond, uint64_t uid) { int32_t i = 0; while (i < TSDB_MAX_JOIN_TABLE_NUM) { SJoinNode* node = pTagCond->joinInfo.joinTables[i]; if (node && node->uid == uid) { return node->tagColId; } i++; } assert(0); return -1; } int16_t getTagColIndexById(STableMeta* pTableMeta, int16_t colId) { int32_t numOfTags = getNumOfTags(pTableMeta); SSchema* pSchema = getTableTagSchema(pTableMeta); for(int32_t i = 0; i < numOfTags; ++i) { if (pSchema[i].colId == colId) { return i; } } // can not reach here assert(0); return INT16_MIN; } bool isQueryWithLimit(SQueryStmtInfo* pQueryInfo) { while(pQueryInfo != NULL) { if (pQueryInfo->limit.limit > 0) { return true; } pQueryInfo = pQueryInfo->sibling; } return false; } SVgroupsInfo* vgroupInfoClone(SVgroupsInfo *vgroupList) { if (vgroupList == NULL) { return NULL; } size_t size = sizeof(SVgroupsInfo) + sizeof(SVgroupMsg) * vgroupList->numOfVgroups; SVgroupsInfo* pNew = malloc(size); if (pNew == NULL) { return NULL; } pNew->numOfVgroups = vgroupList->numOfVgroups; for(int32_t i = 0; i < vgroupList->numOfVgroups; ++i) { SVgroupMsg* pNewVInfo = &pNew->vgroups[i]; SVgroupMsg* pvInfo = &vgroupList->vgroups[i]; pNewVInfo->vgId = pvInfo->vgId; pNewVInfo->numOfEps = pvInfo->numOfEps; for(int32_t j = 0; j < pvInfo->numOfEps; ++j) { pNewVInfo->epAddr[j].port = pvInfo->epAddr[j].port; tstrncpy(pNewVInfo->epAddr[j].fqdn, pvInfo->epAddr[j].fqdn, TSDB_FQDN_LEN); } } return pNew; } void* vgroupInfoClear(SVgroupsInfo *vgroupList) { if (vgroupList == NULL) { return NULL; } tfree(vgroupList); return NULL; } int32_t copyTagData(STagData* dst, const STagData* src) { dst->dataLen = src->dataLen; tstrncpy(dst->name, src->name, tListLen(dst->name)); if (dst->dataLen > 0) { dst->data = malloc(dst->dataLen); if (dst->data == NULL) { return -1; } memcpy(dst->data, src->data, dst->dataLen); } return 0; } uint32_t getTableMetaSize(const STableMeta* pTableMeta) { assert(pTableMeta != NULL); int32_t totalCols = 0; if (pTableMeta->tableInfo.numOfColumns >= 0) { totalCols = pTableMeta->tableInfo.numOfColumns + pTableMeta->tableInfo.numOfTags; } return sizeof(STableMeta) + totalCols * sizeof(SSchema); } uint32_t getTableMetaMaxSize() { return sizeof(STableMeta) + TSDB_MAX_COLUMNS * sizeof(SSchema); } STableMeta* tableMetaDup(const STableMeta* pTableMeta) { assert(pTableMeta != NULL); size_t size = getTableMetaSize(pTableMeta); STableMeta* p = malloc(size); memcpy(p, pTableMeta, size); return p; } SVgroupsInfo* vgroupsInfoDup(SVgroupsInfo* pVgroupsInfo) { assert(pVgroupsInfo != NULL); size_t size = sizeof(SVgroupMsg) * pVgroupsInfo->numOfVgroups + sizeof(SVgroupsInfo); SVgroupsInfo* pInfo = calloc(1, size); pInfo->numOfVgroups = pVgroupsInfo->numOfVgroups; for (int32_t m = 0; m < pVgroupsInfo->numOfVgroups; ++m) { memcpy(&pInfo->vgroups[m], &pVgroupsInfo->vgroups[m], sizeof(SVgroupMsg)); } return pInfo; } int32_t getNumOfOutput(SFieldInfo* pFieldInfo) { return pFieldInfo->numOfOutput; } int32_t getColFilterSerializeLen(SQueryStmtInfo* pQueryInfo) { int16_t numOfCols = (int16_t)taosArrayGetSize(pQueryInfo->colList); int32_t len = 0; for(int32_t i = 0; i < numOfCols; ++i) { SColumn* pCol = taosArrayGetP(pQueryInfo->colList, i); for (int32_t j = 0; j < pCol->info.flist.numOfFilters; ++j) { len += sizeof(SColumnFilterInfo); if (pCol->info.flist.filterInfo[j].filterstr) { len += (int32_t)pCol->info.flist.filterInfo[j].len + 1 * TSDB_NCHAR_SIZE; } } } return len; } int32_t getTagFilterSerializeLen(SQueryStmtInfo* pQueryInfo) { // serialize tag column query condition if (pQueryInfo->tagCond.pCond != NULL && taosArrayGetSize(pQueryInfo->tagCond.pCond) > 0) { STagCond* pTagCond = &pQueryInfo->tagCond; STableMetaInfo *pTableMetaInfo = getMetaInfo(pQueryInfo, 0); STableMeta * pTableMeta = pTableMetaInfo->pTableMeta; SCond *pCond = getSTableQueryCond(pTagCond, pTableMeta->uid); if (pCond != NULL && pCond->cond != NULL) { return pCond->len; } } return 0; } uint32_t convertRelationalOperator(SToken *pToken) { switch (pToken->type) { case TK_LT: return TSDB_RELATION_LESS; case TK_LE: return TSDB_RELATION_LESS_EQUAL; case TK_GT: return TSDB_RELATION_GREATER; case TK_GE: return TSDB_RELATION_GREATER_EQUAL; case TK_NE: return TSDB_RELATION_NOT_EQUAL; case TK_AND: return TSDB_RELATION_AND; case TK_OR: return TSDB_RELATION_OR; case TK_EQ: return TSDB_RELATION_EQUAL; case TK_PLUS: return TSDB_BINARY_OP_ADD; case TK_MINUS: return TSDB_BINARY_OP_SUBTRACT; case TK_STAR: return TSDB_BINARY_OP_MULTIPLY; case TK_SLASH: case TK_DIVIDE: return TSDB_BINARY_OP_DIVIDE; case TK_REM: return TSDB_BINARY_OP_REMAINDER; case TK_LIKE: return TSDB_RELATION_LIKE; case TK_MATCH: return TSDB_RELATION_MATCH; case TK_NMATCH: return TSDB_RELATION_NMATCH; case TK_ISNULL: return TSDB_RELATION_ISNULL; case TK_NOTNULL: return TSDB_RELATION_NOTNULL; case TK_IN: return TSDB_RELATION_IN; default: { return 0; } } } bool isDclSqlStatement(SSqlInfo* pSqlInfo) { int32_t type = pSqlInfo->type; return (type == TSDB_SQL_CREATE_USER || type == TSDB_SQL_CREATE_ACCT || type == TSDB_SQL_DROP_USER || type == TSDB_SQL_DROP_ACCT || type == TSDB_SQL_SHOW); } bool isDdlSqlStatement(SSqlInfo* pSqlInfo) { int32_t type = pSqlInfo->type; return (type == TSDB_SQL_CREATE_TABLE || type == TSDB_SQL_CREATE_DB || type == TSDB_SQL_DROP_DB); } bool isDqlSqlStatement(SSqlInfo* pSqlInfo) { return pSqlInfo->type == TSDB_SQL_SELECT; } static uint8_t TRUE_VALUE = (uint8_t)TSDB_TRUE; static uint8_t FALSE_VALUE = (uint8_t)TSDB_FALSE; static FORCE_INLINE int32_t toDouble(SToken *pToken, double *value, char **endPtr) { errno = 0; *value = strtold(pToken->z, endPtr); // not a valid integer number, return error if ((*endPtr - pToken->z) != pToken->n) { return TK_ILLEGAL; } return pToken->type; } static bool isNullStr(SToken *pToken) { return (pToken->type == TK_NULL) || ((pToken->type == TK_STRING) && (pToken->n != 0) && (strncasecmp(TSDB_DATA_NULL_STR_L, pToken->z, pToken->n) == 0)); } static FORCE_INLINE int32_t checkAndTrimValue(SToken* pToken, uint32_t type, char* tmpTokenBuf, SMsgBuf* pMsgBuf) { if ((pToken->type != TK_NOW && pToken->type != TK_INTEGER && pToken->type != TK_STRING && pToken->type != TK_FLOAT && pToken->type != TK_BOOL && pToken->type != TK_NULL && pToken->type != TK_HEX && pToken->type != TK_OCT && pToken->type != TK_BIN) || (pToken->n == 0) || (pToken->type == TK_RP)) { return buildSyntaxErrMsg(pMsgBuf, "invalid data or symbol", pToken->z); } if (IS_NUMERIC_TYPE(type) && pToken->n == 0) { return buildSyntaxErrMsg(pMsgBuf, "invalid numeric data", pToken->z); } // Remove quotation marks if (TK_STRING == type) { if (pToken->n >= TSDB_MAX_BYTES_PER_ROW) { return buildSyntaxErrMsg(pMsgBuf, "too long string", pToken->z); } // delete escape character: \\, \', \" char delim = pToken->z[0]; int32_t cnt = 0; int32_t j = 0; for (uint32_t k = 1; k < pToken->n - 1; ++k) { if (pToken->z[k] == '\\' || (pToken->z[k] == delim && pToken->z[k + 1] == delim)) { tmpTokenBuf[j] = pToken->z[k + 1]; cnt++; j++; k++; continue; } tmpTokenBuf[j] = pToken->z[k]; j++; } tmpTokenBuf[j] = 0; pToken->z = tmpTokenBuf; pToken->n -= 2 + cnt; } return TSDB_CODE_SUCCESS; } static int parseTime(char **end, SToken *pToken, int16_t timePrec, int64_t *time, SMsgBuf* pMsgBuf) { int32_t index = 0; SToken sToken; int64_t interval; int64_t ts = 0; char* pTokenEnd = *end; if (pToken->type == TK_NOW) { ts = taosGetTimestamp(timePrec); } else if (pToken->type == TK_INTEGER) { bool isSigned = false; toInteger(pToken->z, pToken->n, 10, &ts, &isSigned); } else { // parse the RFC-3339/ISO-8601 timestamp format string if (taosParseTime(pToken->z, time, pToken->n, timePrec, tsDaylight) != TSDB_CODE_SUCCESS) { return buildSyntaxErrMsg(pMsgBuf, "invalid timestamp format", pToken->z); } return TSDB_CODE_SUCCESS; } for (int k = pToken->n; pToken->z[k] != '\0'; k++) { if (pToken->z[k] == ' ' || pToken->z[k] == '\t') continue; if (pToken->z[k] == ',') { *end = pTokenEnd; *time = ts; return 0; } break; } /* * time expression: * e.g., now+12a, now-5h */ SToken valueToken; index = 0; sToken = tStrGetToken(pTokenEnd, &index, false); pTokenEnd += index; if (sToken.type == TK_MINUS || sToken.type == TK_PLUS) { index = 0; valueToken = tStrGetToken(pTokenEnd, &index, false); pTokenEnd += index; if (valueToken.n < 2) { return buildSyntaxErrMsg(pMsgBuf, "value expected in timestamp", sToken.z); } char unit = 0; if (parseAbsoluteDuration(valueToken.z, valueToken.n, &interval, &unit, timePrec) != TSDB_CODE_SUCCESS) { return TSDB_CODE_TSC_INVALID_OPERATION; } if (sToken.type == TK_PLUS) { ts += interval; } else { ts = ts - interval; } *end = pTokenEnd; } *time = ts; return TSDB_CODE_SUCCESS; } int32_t parseValueToken(char** end, SToken* pToken, SSchema* pSchema, int16_t timePrec, char* tmpTokenBuf, _row_append_fn_t func, void* param, SMsgBuf* pMsgBuf) { int64_t iv; char *endptr = NULL; bool isSigned = false; int32_t code = checkAndTrimValue(pToken, pSchema->type, tmpTokenBuf, pMsgBuf); if (code != TSDB_CODE_SUCCESS) { return code; } if (isNullStr(pToken)) { if (TSDB_DATA_TYPE_TIMESTAMP == pSchema->type && PRIMARYKEY_TIMESTAMP_COL_ID == pSchema->colId) { int64_t tmpVal = 0; return func(&tmpVal, pSchema->bytes, param); } return func(getNullValue(pSchema->type), 0, param); } switch (pSchema->type) { case TSDB_DATA_TYPE_BOOL: { if ((pToken->type == TK_BOOL || pToken->type == TK_STRING) && (pToken->n != 0)) { if (strncmp(pToken->z, "true", pToken->n) == 0) { return func(&TRUE_VALUE, pSchema->bytes, param); } else if (strncmp(pToken->z, "false", pToken->n) == 0) { return func(&FALSE_VALUE, pSchema->bytes, param); } else { return buildSyntaxErrMsg(pMsgBuf, "invalid bool data", pToken->z); } } else if (pToken->type == TK_INTEGER) { return func(((strtoll(pToken->z, NULL, 10) == 0) ? &FALSE_VALUE : &TRUE_VALUE), pSchema->bytes, param); } else if (pToken->type == TK_FLOAT) { return func(((strtod(pToken->z, NULL) == 0) ? &FALSE_VALUE : &TRUE_VALUE), pSchema->bytes, param); } else { return buildSyntaxErrMsg(pMsgBuf, "invalid bool data", pToken->z); } } case TSDB_DATA_TYPE_TINYINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid tinyint data", pToken->z); } else if (!IS_VALID_TINYINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "tinyint data overflow", pToken->z); } uint8_t tmpVal = (uint8_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_UTINYINT:{ if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned tinyint data", pToken->z); } else if (!IS_VALID_UTINYINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned tinyint data overflow", pToken->z); } uint8_t tmpVal = (uint8_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_SMALLINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid smallint data", pToken->z); } else if (!IS_VALID_SMALLINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "smallint data overflow", pToken->z); } int16_t tmpVal = (int16_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_USMALLINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned smallint data", pToken->z); } else if (!IS_VALID_USMALLINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned smallint data overflow", pToken->z); } uint16_t tmpVal = (uint16_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_INT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid int data", pToken->z); } else if (!IS_VALID_INT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "int data overflow", pToken->z); } int32_t tmpVal = (int32_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_UINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned int data", pToken->z); } else if (!IS_VALID_UINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned int data overflow", pToken->z); } uint32_t tmpVal = (uint32_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_BIGINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid bigint data", pToken->z); } else if (!IS_VALID_BIGINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "bigint data overflow", pToken->z); } return func(&iv, pSchema->bytes, param); } case TSDB_DATA_TYPE_UBIGINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned bigint data", pToken->z); } else if (!IS_VALID_UBIGINT((uint64_t)iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned bigint data overflow", pToken->z); } uint64_t tmpVal = (uint64_t)iv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_FLOAT: { double dv; if (TK_ILLEGAL == toDouble(pToken, &dv, &endptr)) { return buildSyntaxErrMsg(pMsgBuf, "illegal float data", pToken->z); } if (((dv == HUGE_VAL || dv == -HUGE_VAL) && errno == ERANGE) || dv > FLT_MAX || dv < -FLT_MAX || isinf(dv) || isnan(dv)) { return buildSyntaxErrMsg(pMsgBuf, "illegal float data", pToken->z); } float tmpVal = (float)dv; return func(&tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_DOUBLE: { double dv; if (TK_ILLEGAL == toDouble(pToken, &dv, &endptr)) { return buildSyntaxErrMsg(pMsgBuf, "illegal double data", pToken->z); } if (((dv == HUGE_VAL || dv == -HUGE_VAL) && errno == ERANGE) || isinf(dv) || isnan(dv)) { return buildSyntaxErrMsg(pMsgBuf, "illegal double data", pToken->z); } return func(&dv, pSchema->bytes, param); } case TSDB_DATA_TYPE_BINARY: { // Too long values will raise the invalid sql error message if (pToken->n + VARSTR_HEADER_SIZE > pSchema->bytes) { return buildSyntaxErrMsg(pMsgBuf, "string data overflow", pToken->z); } return func(pToken->z, pToken->n, param); } case TSDB_DATA_TYPE_NCHAR: { return func(pToken->z, pToken->n, param); } case TSDB_DATA_TYPE_TIMESTAMP: { int64_t tmpVal; if (parseTime(end, pToken, timePrec, &tmpVal, pMsgBuf) != TSDB_CODE_SUCCESS) { return buildSyntaxErrMsg(pMsgBuf, "invalid timestamp", pToken->z); } return func(&tmpVal, pSchema->bytes, param); } } return TSDB_CODE_FAILED; } int32_t KvRowAppend(const void *value, int32_t len, void *param) { SKvParam* pa = (SKvParam*) param; int32_t type = pa->schema->type; int32_t colId = pa->schema->colId; if (TSDB_DATA_TYPE_BINARY == type) { STR_WITH_SIZE_TO_VARSTR(pa->buf, value, len); tdAddColToKVRow(pa->builder, colId, type, pa->buf); } else if (TSDB_DATA_TYPE_NCHAR == type) { // if the converted output len is over than pColumnModel->bytes, return error: 'Argument list too long' int32_t output = 0; if (!taosMbsToUcs4(value, len, varDataVal(pa->buf), pa->schema->bytes - VARSTR_HEADER_SIZE, &output)) { return TSDB_CODE_TSC_SQL_SYNTAX_ERROR; } varDataSetLen(pa->buf, output); tdAddColToKVRow(pa->builder, colId, type, pa->buf); } else { tdAddColToKVRow(pa->builder, colId, type, value); } return TSDB_CODE_SUCCESS; } int32_t createSName(SName* pName, SToken* pTableName, SParseBasicCtx* pParseCtx, SMsgBuf* pMsgBuf) { const char* msg1 = "name too long"; int32_t code = TSDB_CODE_SUCCESS; char* p = strnchr(pTableName->z, TS_PATH_DELIMITER[0], pTableName->n, false); if (p != NULL) { // db has been specified in sql string so we ignore current db path tNameSetAcctId(pName, pParseCtx->acctId); char name[TSDB_TABLE_FNAME_LEN] = {0}; strncpy(name, pTableName->z, pTableName->n); code = tNameFromString(pName, name, T_NAME_DB|T_NAME_TABLE); if (code != 0) { return buildInvalidOperationMsg(pMsgBuf, msg1); } } else { // get current DB name first, and then set it into path if (pTableName->n >= TSDB_TABLE_NAME_LEN) { return buildInvalidOperationMsg(pMsgBuf, msg1); } tNameSetDbName(pName, pParseCtx->acctId, pParseCtx->db, strlen(pParseCtx->db)); char name[TSDB_TABLE_FNAME_LEN] = {0}; strncpy(name, pTableName->z, pTableName->n); code = tNameFromString(pName, name, T_NAME_TABLE); if (code != 0) { code = buildInvalidOperationMsg(pMsgBuf, msg1); } } return code; }