/* * 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 "builtins.h" #include "builtinsimpl.h" #include "cJSON.h" #include "querynodes.h" #include "scalar.h" #include "taoserror.h" #include "ttime.h" static int32_t buildFuncErrMsg(char* pErrBuf, int32_t len, int32_t errCode, const char* pFormat, ...) { va_list vArgList; va_start(vArgList, pFormat); vsnprintf(pErrBuf, len, pFormat, vArgList); va_end(vArgList); return errCode; } static int32_t invaildFuncParaNumErrMsg(char* pErrBuf, int32_t len, const char* pFuncName) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_PARA_NUM, "Invalid number of parameters : %s", pFuncName); } static int32_t invaildFuncParaTypeErrMsg(char* pErrBuf, int32_t len, const char* pFuncName) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_PARA_TYPE, "Invalid parameter data type : %s", pFuncName); } static int32_t invaildFuncParaValueErrMsg(char* pErrBuf, int32_t len, const char* pFuncName) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_PARA_VALUE, "Invalid parameter value : %s", pFuncName); } #define TIME_UNIT_INVALID 1 #define TIME_UNIT_TOO_SMALL 2 static int32_t validateTimeUnitParam(uint8_t dbPrec, const SValueNode* pVal) { if (!pVal->isDuration) { return TIME_UNIT_INVALID; } if (TSDB_TIME_PRECISION_MILLI == dbPrec && (0 == strcasecmp(pVal->literal, "1u") || 0 == strcasecmp(pVal->literal, "1b"))) { return TIME_UNIT_TOO_SMALL; } if (TSDB_TIME_PRECISION_MICRO == dbPrec && 0 == strcasecmp(pVal->literal, "1b")) { return TIME_UNIT_TOO_SMALL; } if (pVal->literal[0] != '1' || (pVal->literal[1] != 'u' && pVal->literal[1] != 'a' && pVal->literal[1] != 's' && pVal->literal[1] != 'm' && pVal->literal[1] != 'h' && pVal->literal[1] != 'd' && pVal->literal[1] != 'w' && pVal->literal[1] != 'b')) { return TIME_UNIT_INVALID; } return TSDB_CODE_SUCCESS; } /* Following are valid ISO-8601 timezone format: * 1 z/Z * 2 ±hh:mm * 3 ±hhmm * 4 ±hh * */ static bool validateHourRange(int8_t hour) { if (hour < 0 || hour > 12) { return false; } return true; } static bool validateMinuteRange(int8_t hour, int8_t minute, char sign) { if (minute == 0 || (minute == 30 && (hour == 3 || hour == 5) && sign == '+')) { return true; } return false; } static bool validateTimestampDigits(const SValueNode* pVal) { if (!IS_INTEGER_TYPE(pVal->node.resType.type)) { return false; } int64_t tsVal = pVal->datum.i; char fraction[20] = {0}; NUM_TO_STRING(pVal->node.resType.type, &tsVal, sizeof(fraction), fraction); int32_t tsDigits = (int32_t)strlen(fraction); if (tsDigits > TSDB_TIME_PRECISION_SEC_DIGITS) { if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS || tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS || tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { return true; } else { return false; } } return true; } static bool validateTimezoneFormat(const SValueNode* pVal) { if (TSDB_DATA_TYPE_BINARY != pVal->node.resType.type) { return false; } char* tz = varDataVal(pVal->datum.p); int32_t len = varDataLen(pVal->datum.p); char buf[3] = {0}; int8_t hour = -1, minute = -1; if (len == 0) { return false; } else if (len == 1 && (tz[0] == 'z' || tz[0] == 'Z')) { return true; } else if ((tz[0] == '+' || tz[0] == '-')) { switch (len) { case 3: case 5: { for (int32_t i = 1; i < len; ++i) { if (!isdigit(tz[i])) { return false; } if (i == 2) { memcpy(buf, &tz[i - 1], 2); hour = taosStr2Int8(buf, NULL, 10); if (!validateHourRange(hour)) { return false; } } else if (i == 4) { memcpy(buf, &tz[i - 1], 2); minute = taosStr2Int8(buf, NULL, 10); if (!validateMinuteRange(hour, minute, tz[0])) { return false; } } } break; } case 6: { for (int32_t i = 1; i < len; ++i) { if (i == 3) { if (tz[i] != ':') { return false; } continue; } if (!isdigit(tz[i])) { return false; } if (i == 2) { memcpy(buf, &tz[i - 1], 2); hour = taosStr2Int8(buf, NULL, 10); if (!validateHourRange(hour)) { return false; } } else if (i == 5) { memcpy(buf, &tz[i - 1], 2); minute = taosStr2Int8(buf, NULL, 10); if (!validateMinuteRange(hour, minute, tz[0])) { return false; } } } break; } default: { return false; } } } else { return false; } return true; } static int32_t countTrailingSpaces(const SValueNode* pVal, bool isLtrim) { int32_t numOfSpaces = 0; int32_t len = varDataLen(pVal->datum.p); char* str = varDataVal(pVal->datum.p); int32_t startPos = isLtrim ? 0 : len - 1; int32_t step = isLtrim ? 1 : -1; for (int32_t i = startPos; i < len || i >= 0; i += step) { if (!isspace(str[i])) { break; } numOfSpaces++; } return numOfSpaces; } void static addTimezoneParam(SNodeList* pList) { char buf[6] = {0}; time_t t = taosTime(NULL); struct tm tmInfo; taosLocalTime(&t, &tmInfo); strftime(buf, sizeof(buf), "%z", &tmInfo); int32_t len = (int32_t)strlen(buf); SValueNode* pVal = (SValueNode*)nodesMakeNode(QUERY_NODE_VALUE); pVal->literal = strndup(buf, len); pVal->isDuration = false; pVal->translate = true; pVal->node.resType.type = TSDB_DATA_TYPE_BINARY; pVal->node.resType.bytes = len + VARSTR_HEADER_SIZE; pVal->node.resType.precision = TSDB_TIME_PRECISION_MILLI; pVal->datum.p = taosMemoryCalloc(1, len + VARSTR_HEADER_SIZE + 1); varDataSetLen(pVal->datum.p, len); strncpy(varDataVal(pVal->datum.p), pVal->literal, len); nodesListAppend(pList, (SNode*)pVal); } void static addDbPrecisonParam(SNodeList** pList, uint8_t precision) { SValueNode* pVal = (SValueNode*)nodesMakeNode(QUERY_NODE_VALUE); pVal->literal = NULL; pVal->isDuration = false; pVal->translate = true; pVal->notReserved = true; pVal->node.resType.type = TSDB_DATA_TYPE_TINYINT; pVal->node.resType.bytes = tDataTypes[TSDB_DATA_TYPE_TINYINT].bytes; pVal->node.resType.precision = precision; pVal->datum.i = (int64_t)precision; pVal->typeData = (int64_t)precision; nodesListMakeAppend(pList, (SNode*)pVal); } // There is only one parameter of numeric type, and the return type is parameter type static int32_t translateInOutNum(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } else if (IS_NULL_TYPE(paraType)) { paraType = TSDB_DATA_TYPE_BIGINT; } pFunc->node.resType = (SDataType){.bytes = tDataTypes[paraType].bytes, .type = paraType}; return TSDB_CODE_SUCCESS; } // There is only one parameter of numeric type, and the return type is double type static int32_t translateInNumOutDou(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } // There are two parameters of numeric type, and the return type is double type static int32_t translateIn2NumOutDou(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (2 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if ((!IS_NUMERIC_TYPE(para1Type) && !IS_NULL_TYPE(para1Type)) || (!IS_NUMERIC_TYPE(para2Type) && !IS_NULL_TYPE(para2Type))) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } // There is only one parameter of string type, and the return type is parameter type static int32_t translateInOutStr(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SExprNode* pPara1 = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 0); if (!IS_STR_DATA_TYPE(pPara1->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = pPara1->resType.bytes, .type = pPara1->resType.type}; return TSDB_CODE_SUCCESS; } static int32_t translateMinMax(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_TIMESTAMP_TYPE(paraType) && !IS_NUMERIC_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } else if (IS_NULL_TYPE(paraType)) { paraType = TSDB_DATA_TYPE_BIGINT; } pFunc->node.resType = (SDataType){.bytes = tDataTypes[paraType].bytes, .type = paraType}; return TSDB_CODE_SUCCESS; } static int32_t translateTrimStr(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isLtrim) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SExprNode* pPara1 = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 0); if (!IS_STR_DATA_TYPE(pPara1->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } int32_t numOfSpaces = 0; SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 0); // for select trim functions with constant value from table, // need to set the proper result result schema bytes to avoid // trailing garbage characters if (nodeType(pParamNode1) == QUERY_NODE_VALUE) { SValueNode* pValue = (SValueNode*)pParamNode1; numOfSpaces = countTrailingSpaces(pValue, isLtrim); } int32_t resBytes = pPara1->resType.bytes - numOfSpaces; pFunc->node.resType = (SDataType){.bytes = resBytes, .type = pPara1->resType.type}; return TSDB_CODE_SUCCESS; } static int32_t translateLtrim(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateTrimStr(pFunc, pErrBuf, len, true); } static int32_t translateRtrim(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateTrimStr(pFunc, pErrBuf, len, false); } static int32_t translateLogarithm(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (1 != numOfParams && 2 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(para1Type) && !IS_NULL_TYPE(para1Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (2 == numOfParams) { uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_NUMERIC_TYPE(para2Type) && !IS_NULL_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateCount(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateSum(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t resType = 0; if (IS_SIGNED_NUMERIC_TYPE(paraType) || TSDB_DATA_TYPE_BOOL == paraType || IS_NULL_TYPE(paraType)) { resType = TSDB_DATA_TYPE_BIGINT; } else if (IS_UNSIGNED_NUMERIC_TYPE(paraType)) { resType = TSDB_DATA_TYPE_UBIGINT; } else if (IS_FLOAT_TYPE(paraType)) { resType = TSDB_DATA_TYPE_DOUBLE; } pFunc->node.resType = (SDataType){.bytes = tDataTypes[resType].bytes, .type = resType}; return TSDB_CODE_SUCCESS; } static int32_t translateAvgPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = getAvgInfoSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } static int32_t translateAvgMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (TSDB_DATA_TYPE_BINARY != paraType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateStddevPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = getStddevInfoSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } static int32_t translateStddevMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (TSDB_DATA_TYPE_BINARY != paraType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateWduration(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { // pseudo column do not need to check parameters pFunc->node.resType = (SDataType){.bytes = sizeof(int64_t), .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateNowToday(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { // pseudo column do not need to check parameters // add database precision as param uint8_t dbPrec = pFunc->node.resType.precision; addDbPrecisonParam(&pFunc->pParameterList, dbPrec); pFunc->node.resType = (SDataType){.bytes = sizeof(int64_t), .type = TSDB_DATA_TYPE_TIMESTAMP}; return TSDB_CODE_SUCCESS; } static int32_t translateTimePseudoColumn(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { // pseudo column do not need to check parameters pFunc->node.resType = (SDataType){.bytes = sizeof(int64_t), .type = TSDB_DATA_TYPE_TIMESTAMP}; return TSDB_CODE_SUCCESS; } static int32_t translateTimezone(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = TD_TIMEZONE_LEN, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } static int32_t translatePercentile(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (2 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } // param1 SValueNode* pValue = (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1); if (pValue->datum.i < 0 || pValue->datum.i > 100) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pValue->notReserved = true; uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_NUMERIC_TYPE(para1Type) || (!IS_SIGNED_NUMERIC_TYPE(para2Type) && !IS_UNSIGNED_NUMERIC_TYPE(para2Type))) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // set result type pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static bool validateApercentileAlgo(const SValueNode* pVal) { if (TSDB_DATA_TYPE_BINARY != pVal->node.resType.type) { return false; } return (0 == strcasecmp(varDataVal(pVal->datum.p), "default") || 0 == strcasecmp(varDataVal(pVal->datum.p), "t-digest")); } static int32_t translateApercentile(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (2 != numOfParams && 3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } // param1 SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (nodeType(pParamNode1) != QUERY_NODE_VALUE) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; if (pValue->datum.i < 0 || pValue->datum.i > 100) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pValue->notReserved = true; uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_NUMERIC_TYPE(para1Type) || !IS_INTEGER_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param2 if (3 == numOfParams) { uint8_t para3Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type; if (!IS_STR_DATA_TYPE(para3Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SNode* pParamNode2 = nodesListGetNode(pFunc->pParameterList, 2); if (QUERY_NODE_VALUE != nodeType(pParamNode2) || !validateApercentileAlgo((SValueNode*)pParamNode2)) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "Third parameter algorithm of apercentile must be 'default' or 't-digest'"); } pValue = (SValueNode*)pParamNode2; pValue->notReserved = true; } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateApercentileImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isPartial) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (isPartial) { if (2 != numOfParams && 3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } // param1 SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (nodeType(pParamNode1) != QUERY_NODE_VALUE) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; if (pValue->datum.i < 0 || pValue->datum.i > 100) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pValue->notReserved = true; uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_NUMERIC_TYPE(para1Type) || !IS_INTEGER_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param2 if (3 == numOfParams) { uint8_t para3Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type; if (!IS_STR_DATA_TYPE(para3Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SNode* pParamNode2 = nodesListGetNode(pFunc->pParameterList, 2); if (QUERY_NODE_VALUE != nodeType(pParamNode2) || !validateApercentileAlgo((SValueNode*)pParamNode2)) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "Third parameter algorithm of apercentile must be 'default' or 't-digest'"); } pValue = (SValueNode*)pParamNode2; pValue->notReserved = true; } pFunc->node.resType = (SDataType){.bytes = getApercentileMaxSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; } else { // original percent param is reserved if (2 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (TSDB_DATA_TYPE_BINARY != para1Type || !IS_INTEGER_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; } return TSDB_CODE_SUCCESS; } static int32_t translateApercentilePartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateApercentileImpl(pFunc, pErrBuf, len, true); } static int32_t translateApercentileMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateApercentileImpl(pFunc, pErrBuf, len, false); } static int32_t translateTbnameColumn(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { // pseudo column do not need to check parameters pFunc->node.resType = (SDataType){.bytes = TSDB_TABLE_FNAME_LEN - 1 + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateTopBot(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (2 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_NUMERIC_TYPE(para1Type) || !IS_INTEGER_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1 SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (nodeType(pParamNode1) != QUERY_NODE_VALUE) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; if (!IS_INTEGER_TYPE(pValue->node.resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (pValue->datum.i < 1 || pValue->datum.i > 100) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pValue->notReserved = true; // set result type SDataType* pType = &((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType; pFunc->node.resType = (SDataType){.bytes = pType->bytes, .type = pType->type}; return TSDB_CODE_SUCCESS; } static int32_t reserveFirstMergeParam(SNodeList* pRawParameters, SNode* pPartialRes, SNodeList** pParameters) { int32_t code = nodesListMakeAppend(pParameters, pPartialRes); if (TSDB_CODE_SUCCESS == code) { code = nodesListStrictAppend(*pParameters, nodesCloneNode(nodesListGetNode(pRawParameters, 1))); } return TSDB_CODE_SUCCESS; } int32_t topBotCreateMergeParam(SNodeList* pRawParameters, SNode* pPartialRes, SNodeList** pParameters) { return reserveFirstMergeParam(pRawParameters, pPartialRes, pParameters); } int32_t apercentileCreateMergeParam(SNodeList* pRawParameters, SNode* pPartialRes, SNodeList** pParameters) { return reserveFirstMergeParam(pRawParameters, pPartialRes, pParameters); } static int32_t translateSpread(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) && !IS_TIMESTAMP_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateSpreadImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isPartial) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (isPartial) { if (!IS_NUMERIC_TYPE(paraType) && !IS_TIMESTAMP_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = getSpreadInfoSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; } else { if (TSDB_DATA_TYPE_BINARY != paraType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; } return TSDB_CODE_SUCCESS; } static int32_t translateSpreadPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateSpreadImpl(pFunc, pErrBuf, len, true); } static int32_t translateSpreadMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateSpreadImpl(pFunc, pErrBuf, len, false); } static int32_t translateElapsed(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (1 != numOfParams && 2 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SNode* pPara1 = nodesListGetNode(pFunc->pParameterList, 0); if (QUERY_NODE_COLUMN != nodeType(pPara1) || PRIMARYKEY_TIMESTAMP_COL_ID != ((SColumnNode*)pPara1)->colId) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "The first parameter of the ELAPSED function can only be the timestamp primary key"); } // param1 if (2 == numOfParams) { SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (QUERY_NODE_VALUE != nodeType(pParamNode1)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; pValue->notReserved = true; if (!IS_INTEGER_TYPE(pValue->node.resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t dbPrec = pFunc->node.resType.precision; int32_t ret = validateTimeUnitParam(dbPrec, (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1)); if (ret == TIME_UNIT_TOO_SMALL) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "ELAPSED function time unit parameter should be greater than db precision"); } else if (ret == TIME_UNIT_INVALID) { return buildFuncErrMsg( pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "ELAPSED function time unit parameter should be one of the following: [1b, 1u, 1a, 1s, 1m, 1h, 1d, 1w]"); } } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateElapsedImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isPartial) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (isPartial) { if (1 != numOfParams && 2 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_TIMESTAMP_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1 if (2 == numOfParams) { SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (QUERY_NODE_VALUE != nodeType(pParamNode1)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; pValue->notReserved = true; paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_INTEGER_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (pValue->datum.i == 0) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "ELAPSED function time unit parameter should be greater than db precision"); } } pFunc->node.resType = (SDataType){.bytes = getElapsedInfoSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; } else { if (1 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (TSDB_DATA_TYPE_BINARY != paraType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; } return TSDB_CODE_SUCCESS; } static int32_t translateElapsedPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateElapsedImpl(pFunc, pErrBuf, len, true); } static int32_t translateElapsedMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateElapsedImpl(pFunc, pErrBuf, len, false); } static int32_t translateLeastSQR(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } for (int32_t i = 0; i < numOfParams; ++i) { SNode* pParamNode = nodesListGetNode(pFunc->pParameterList, i); if (i > 0) { // param1 & param2 if (QUERY_NODE_VALUE != nodeType(pParamNode)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode; pValue->notReserved = true; } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, i))->resType.type; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } pFunc->node.resType = (SDataType){.bytes = 64, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } typedef enum { UNKNOWN_BIN = 0, USER_INPUT_BIN, LINEAR_BIN, LOG_BIN } EHistoBinType; static int8_t validateHistogramBinType(char* binTypeStr) { int8_t binType; if (strcasecmp(binTypeStr, "user_input") == 0) { binType = USER_INPUT_BIN; } else if (strcasecmp(binTypeStr, "linear_bin") == 0) { binType = LINEAR_BIN; } else if (strcasecmp(binTypeStr, "log_bin") == 0) { binType = LOG_BIN; } else { binType = UNKNOWN_BIN; } return binType; } static bool validateHistogramBinDesc(char* binDescStr, int8_t binType, char* errMsg, int32_t msgLen) { const char* msg1 = "HISTOGRAM function requires four parameters"; const char* msg3 = "HISTOGRAM function invalid format for binDesc parameter"; const char* msg4 = "HISTOGRAM function binDesc parameter \"count\" should be in range [1, 1000]"; const char* msg5 = "HISTOGRAM function bin/parameter should be in range [-DBL_MAX, DBL_MAX]"; const char* msg6 = "HISTOGRAM function binDesc parameter \"width\" cannot be 0"; const char* msg7 = "HISTOGRAM function binDesc parameter \"start\" cannot be 0 with \"log_bin\" type"; const char* msg8 = "HISTOGRAM function binDesc parameter \"factor\" cannot be negative or equal to 0/1"; cJSON* binDesc = cJSON_Parse(binDescStr); int32_t numOfBins; double* intervals; if (cJSON_IsObject(binDesc)) { /* linaer/log bins */ int32_t numOfParams = cJSON_GetArraySize(binDesc); int32_t startIndex; if (numOfParams != 4) { snprintf(errMsg, msgLen, "%s", msg1); return false; } cJSON* start = cJSON_GetObjectItem(binDesc, "start"); cJSON* factor = cJSON_GetObjectItem(binDesc, "factor"); cJSON* width = cJSON_GetObjectItem(binDesc, "width"); cJSON* count = cJSON_GetObjectItem(binDesc, "count"); cJSON* infinity = cJSON_GetObjectItem(binDesc, "infinity"); if (!cJSON_IsNumber(start) || !cJSON_IsNumber(count) || !cJSON_IsBool(infinity)) { snprintf(errMsg, msgLen, "%s", msg3); return false; } if (count->valueint <= 0 || count->valueint > 1000) { // limit count to 1000 snprintf(errMsg, msgLen, "%s", msg4); return false; } if (isinf(start->valuedouble) || (width != NULL && isinf(width->valuedouble)) || (factor != NULL && isinf(factor->valuedouble)) || (count != NULL && isinf(count->valuedouble))) { snprintf(errMsg, msgLen, "%s", msg5); return false; } int32_t counter = (int32_t)count->valueint; if (infinity->valueint == false) { startIndex = 0; numOfBins = counter + 1; } else { startIndex = 1; numOfBins = counter + 3; } intervals = taosMemoryCalloc(numOfBins, sizeof(double)); if (cJSON_IsNumber(width) && factor == NULL && binType == LINEAR_BIN) { // linear bin process if (width->valuedouble == 0) { snprintf(errMsg, msgLen, "%s", msg6); taosMemoryFree(intervals); return false; } for (int i = 0; i < counter + 1; ++i) { intervals[startIndex] = start->valuedouble + i * width->valuedouble; if (isinf(intervals[startIndex])) { snprintf(errMsg, msgLen, "%s", msg5); taosMemoryFree(intervals); return false; } startIndex++; } } else if (cJSON_IsNumber(factor) && width == NULL && binType == LOG_BIN) { // log bin process if (start->valuedouble == 0) { snprintf(errMsg, msgLen, "%s", msg7); taosMemoryFree(intervals); return false; } if (factor->valuedouble < 0 || factor->valuedouble == 0 || factor->valuedouble == 1) { snprintf(errMsg, msgLen, "%s", msg8); taosMemoryFree(intervals); return false; } for (int i = 0; i < counter + 1; ++i) { intervals[startIndex] = start->valuedouble * pow(factor->valuedouble, i * 1.0); if (isinf(intervals[startIndex])) { snprintf(errMsg, msgLen, "%s", msg5); taosMemoryFree(intervals); return false; } startIndex++; } } else { snprintf(errMsg, msgLen, "%s", msg3); taosMemoryFree(intervals); return false; } if (infinity->valueint == true) { intervals[0] = -INFINITY; intervals[numOfBins - 1] = INFINITY; // in case of desc bin orders, -inf/inf should be swapped ASSERT(numOfBins >= 4); if (intervals[1] > intervals[numOfBins - 2]) { TSWAP(intervals[0], intervals[numOfBins - 1]); } } } else if (cJSON_IsArray(binDesc)) { /* user input bins */ if (binType != USER_INPUT_BIN) { snprintf(errMsg, msgLen, "%s", msg3); return false; } numOfBins = cJSON_GetArraySize(binDesc); intervals = taosMemoryCalloc(numOfBins, sizeof(double)); cJSON* bin = binDesc->child; if (bin == NULL) { snprintf(errMsg, msgLen, "%s", msg3); taosMemoryFree(intervals); return false; } int i = 0; while (bin) { intervals[i] = bin->valuedouble; if (!cJSON_IsNumber(bin)) { snprintf(errMsg, msgLen, "%s", msg3); taosMemoryFree(intervals); return false; } if (i != 0 && intervals[i] <= intervals[i - 1]) { snprintf(errMsg, msgLen, "%s", msg3); taosMemoryFree(intervals); return false; } bin = bin->next; i++; } } else { snprintf(errMsg, msgLen, "%s", msg3); return false; } cJSON_Delete(binDesc); taosMemoryFree(intervals); return true; } static int32_t translateHistogram(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (4 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1 ~ param3 if (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type != TSDB_DATA_TYPE_BINARY || ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type != TSDB_DATA_TYPE_BINARY || !IS_INTEGER_TYPE(((SExprNode*)nodesListGetNode(pFunc->pParameterList, 3))->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } int8_t binType; char* binDesc; for (int32_t i = 1; i < numOfParams; ++i) { SNode* pParamNode = nodesListGetNode(pFunc->pParameterList, i); if (QUERY_NODE_VALUE != nodeType(pParamNode)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode; pValue->notReserved = true; if (i == 1) { binType = validateHistogramBinType(varDataVal(pValue->datum.p)); if (binType == UNKNOWN_BIN) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "HISTOGRAM function binType parameter should be " "\"user_input\", \"log_bin\" or \"linear_bin\""); } } if (i == 2) { char errMsg[128] = {0}; binDesc = varDataVal(pValue->datum.p); if (!validateHistogramBinDesc(binDesc, binType, errMsg, (int32_t)sizeof(errMsg))) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, errMsg); } } if (i == 3 && pValue->datum.i != 1 && pValue->datum.i != 0) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "HISTOGRAM function normalized parameter should be 0/1"); } } pFunc->node.resType = (SDataType){.bytes = 512, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } static int32_t translateHistogramImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isPartial) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (isPartial) { if (4 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1 ~ param3 if (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type != TSDB_DATA_TYPE_BINARY || ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type != TSDB_DATA_TYPE_BINARY || !IS_INTEGER_TYPE(((SExprNode*)nodesListGetNode(pFunc->pParameterList, 3))->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } int8_t binType; char* binDesc; for (int32_t i = 1; i < numOfParams; ++i) { SNode* pParamNode = nodesListGetNode(pFunc->pParameterList, i); if (QUERY_NODE_VALUE != nodeType(pParamNode)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode; pValue->notReserved = true; if (i == 1) { binType = validateHistogramBinType(varDataVal(pValue->datum.p)); if (binType == UNKNOWN_BIN) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "HISTOGRAM function binType parameter should be " "\"user_input\", \"log_bin\" or \"linear_bin\""); } } if (i == 2) { char errMsg[128] = {0}; binDesc = varDataVal(pValue->datum.p); if (!validateHistogramBinDesc(binDesc, binType, errMsg, (int32_t)sizeof(errMsg))) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, errMsg); } } if (i == 3 && pValue->datum.i != 1 && pValue->datum.i != 0) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "HISTOGRAM function normalized parameter should be 0/1"); } } pFunc->node.resType = (SDataType){.bytes = getHistogramInfoSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; } else { if (1 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } if (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type != TSDB_DATA_TYPE_BINARY) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = 512, .type = TSDB_DATA_TYPE_BINARY}; } return TSDB_CODE_SUCCESS; } static int32_t translateHistogramPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateHistogramImpl(pFunc, pErrBuf, len, true); } static int32_t translateHistogramMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateHistogramImpl(pFunc, pErrBuf, len, false); } static int32_t translateHLL(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateHLLImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isPartial) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } if (isPartial) { pFunc->node.resType = (SDataType){.bytes = getHistogramInfoSize() + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; } else { pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; } return TSDB_CODE_SUCCESS; } static int32_t translateHLLPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateHLLImpl(pFunc, pErrBuf, len, true); } static int32_t translateHLLMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateHLLImpl(pFunc, pErrBuf, len, false); } static bool validateStateOper(const SValueNode* pVal) { if (TSDB_DATA_TYPE_BINARY != pVal->node.resType.type) { return false; } return ( 0 == strncasecmp(varDataVal(pVal->datum.p), "GT", 2) || 0 == strncasecmp(varDataVal(pVal->datum.p), "GE", 2) || 0 == strncasecmp(varDataVal(pVal->datum.p), "LT", 2) || 0 == strncasecmp(varDataVal(pVal->datum.p), "LE", 2) || 0 == strncasecmp(varDataVal(pVal->datum.p), "EQ", 2) || 0 == strncasecmp(varDataVal(pVal->datum.p), "NE", 2)); } static int32_t translateStateCount(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1 & param2 for (int32_t i = 1; i < numOfParams; ++i) { SNode* pParamNode = nodesListGetNode(pFunc->pParameterList, i); if (QUERY_NODE_VALUE != nodeType(pParamNode)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode; if (i == 1 && !validateStateOper(pValue)) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "Second parameter of STATECOUNT function" "must be one of the following: 'GE', 'GT', 'LE', 'LT', 'EQ', 'NE'"); } pValue->notReserved = true; } if (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type != TSDB_DATA_TYPE_BINARY || (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type != TSDB_DATA_TYPE_BIGINT && ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type != TSDB_DATA_TYPE_DOUBLE)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // set result type pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateStateDuration(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (3 != numOfParams && 4 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1, param2 & param3 for (int32_t i = 1; i < numOfParams; ++i) { SNode* pParamNode = nodesListGetNode(pFunc->pParameterList, i); if (QUERY_NODE_VALUE != nodeType(pParamNode)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode; if (i == 1 && !validateStateOper(pValue)) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "Second parameter of STATEDURATION function" "must be one of the following: 'GE', 'GT', 'LE', 'LT', 'EQ', 'NE'"); } else if (i == 3 && pValue->datum.i == 0) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "STATEDURATION function time unit parameter should be greater than db precision"); } pValue->notReserved = true; } if (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type != TSDB_DATA_TYPE_BINARY || (((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type != TSDB_DATA_TYPE_BIGINT && ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type != TSDB_DATA_TYPE_DOUBLE)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (numOfParams == 4 && ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 3))->resType.type != TSDB_DATA_TYPE_BIGINT) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (numOfParams == 4) { uint8_t dbPrec = pFunc->node.resType.precision; int32_t ret = validateTimeUnitParam(dbPrec, (SValueNode*)nodesListGetNode(pFunc->pParameterList, 3)); if (ret == TIME_UNIT_TOO_SMALL) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "STATEDURATION function time unit parameter should be greater than db precision"); } else if (ret == TIME_UNIT_INVALID) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "STATEDURATION function time unit parameter should be one of the following: [1b, 1u, 1a, " "1s, 1m, 1h, 1d, 1w]"); } } // set result type pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateCsum(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t resType; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } else { if (IS_SIGNED_NUMERIC_TYPE(colType)) { resType = TSDB_DATA_TYPE_BIGINT; } else if (IS_UNSIGNED_NUMERIC_TYPE(colType)) { resType = TSDB_DATA_TYPE_UBIGINT; } else if (IS_FLOAT_TYPE(colType)) { resType = TSDB_DATA_TYPE_DOUBLE; } else { ASSERT(0); } } pFunc->node.resType = (SDataType){.bytes = tDataTypes[resType].bytes, .type = resType}; return TSDB_CODE_SUCCESS; } static EFuncReturnRows csumEstReturnRows(SFunctionNode* pFunc) { return FUNC_RETURN_ROWS_N; } static int32_t translateMavg(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (2 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; // param1 SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (QUERY_NODE_VALUE != nodeType(pParamNode1)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; if (pValue->datum.i < 1 || pValue->datum.i > 1000) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pValue->notReserved = true; uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_NUMERIC_TYPE(colType) || !IS_INTEGER_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateSample(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (2 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SExprNode* pCol = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 0); uint8_t colType = pCol->resType.type; // param1 SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (QUERY_NODE_VALUE != nodeType(pParamNode1)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; if (pValue->datum.i < 1 || pValue->datum.i > 1000) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pValue->notReserved = true; uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_INTEGER_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // set result type if (IS_STR_DATA_TYPE(colType)) { pFunc->node.resType = (SDataType){.bytes = pCol->resType.bytes, .type = colType}; } else { pFunc->node.resType = (SDataType){.bytes = tDataTypes[colType].bytes, .type = colType}; } return TSDB_CODE_SUCCESS; } static int32_t translateTail(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (2 != numOfParams && 3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SExprNode* pCol = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 0); uint8_t colType = pCol->resType.type; // param1 & param2 for (int32_t i = 1; i < numOfParams; ++i) { SNode* pParamNode = nodesListGetNode(pFunc->pParameterList, i); if (QUERY_NODE_VALUE != nodeType(pParamNode)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode; if ((IS_SIGNED_NUMERIC_TYPE(pValue->node.resType.type) ? pValue->datum.i : pValue->datum.u) < ((i > 1) ? 0 : 1) || (IS_SIGNED_NUMERIC_TYPE(pValue->node.resType.type) ? pValue->datum.i : pValue->datum.u) > 100) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "TAIL function second parameter should be in range [1, 100], " "third parameter should be in range [0, 100]"); } pValue->notReserved = true; uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, i))->resType.type; if (!IS_INTEGER_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } // set result type if (IS_STR_DATA_TYPE(colType)) { pFunc->node.resType = (SDataType){.bytes = pCol->resType.bytes, .type = colType}; } else { pFunc->node.resType = (SDataType){.bytes = tDataTypes[colType].bytes, .type = colType}; } return TSDB_CODE_SUCCESS; } static int32_t translateDerivative(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (3 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; // param1 SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (QUERY_NODE_VALUE != nodeType(pParamNode1)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; pValue->notReserved = true; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SNode* pParamNode2 = nodesListGetNode(pFunc->pParameterList, 2); SValueNode* pValue2 = (SValueNode*)pParamNode2; pValue2->notReserved = true; if (pValue2->datum.i != 0 && pValue2->datum.i != 1) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static EFuncReturnRows derivativeEstReturnRows(SFunctionNode* pFunc) { return 1 == ((SValueNode*)nodesListGetNode(pFunc->pParameterList, 2))->datum.i ? FUNC_RETURN_ROWS_INDEFINITE : FUNC_RETURN_ROWS_N_MINUS_1; } static int32_t translateIrate(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // add database precision as param uint8_t dbPrec = pFunc->node.resType.precision; addDbPrecisonParam(&pFunc->pParameterList, dbPrec); pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_DOUBLE].bytes, .type = TSDB_DATA_TYPE_DOUBLE}; return TSDB_CODE_SUCCESS; } static int32_t translateInterp(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); uint8_t dbPrec = pFunc->node.resType.precision; if (1 != numOfParams && 3 != numOfParams && 4 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t nodeType = nodeType(nodesListGetNode(pFunc->pParameterList, 0)); uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_NUMERIC_TYPE(paraType) || QUERY_NODE_VALUE == nodeType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (3 <= numOfParams) { int64_t timeVal[2] = {0}; for (int32_t i = 1; i < 3; ++i) { nodeType = nodeType(nodesListGetNode(pFunc->pParameterList, i)); paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, i))->resType.type; if (!IS_STR_DATA_TYPE(paraType) || QUERY_NODE_VALUE != nodeType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)nodesListGetNode(pFunc->pParameterList, i); int32_t ret = convertStringToTimestamp(paraType, pValue->datum.p, dbPrec, &timeVal[i - 1]); if (ret != TSDB_CODE_SUCCESS) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } } if (timeVal[0] > timeVal[1]) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "INTERP function invalid time range"); } } if (4 == numOfParams) { nodeType = nodeType(nodesListGetNode(pFunc->pParameterList, 3)); paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 3))->resType.type; if (!IS_INTEGER_TYPE(paraType) || QUERY_NODE_VALUE != nodeType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } int32_t ret = validateTimeUnitParam(dbPrec, (SValueNode*)nodesListGetNode(pFunc->pParameterList, 3)); if (ret == TIME_UNIT_TOO_SMALL) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "INTERP function time interval parameter should be greater than db precision"); } else if (ret == TIME_UNIT_INVALID) { return buildFuncErrMsg( pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "INTERP function time interval parameter should be one of the following: [1b, 1u, 1a, 1s, 1m, 1h, 1d, 1w]"); } } pFunc->node.resType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType; return TSDB_CODE_SUCCESS; } static int32_t translateFirstLast(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { // forbid null as first/last input, since first(c0, null, 1) may have different number of input int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); for (int32_t i = 0; i < numOfParams; ++i) { uint8_t nodeType = nodeType(nodesListGetNode(pFunc->pParameterList, i)); uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, i))->resType.type; if (IS_NULL_TYPE(paraType) && QUERY_NODE_VALUE == nodeType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } pFunc->node.resType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType; return TSDB_CODE_SUCCESS; } static int32_t translateFirstLastImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isPartial) { // first(col_list) will be rewritten as first(col) SNode* pPara = nodesListGetNode(pFunc->pParameterList, 0); uint8_t paraType = ((SExprNode*)pPara)->resType.type; int32_t paraBytes = ((SExprNode*)pPara)->resType.bytes; if (isPartial) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); for (int32_t i = 0; i < numOfParams; ++i) { uint8_t nodeType = nodeType(nodesListGetNode(pFunc->pParameterList, i)); uint8_t pType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, i))->resType.type; if (IS_NULL_TYPE(pType) && QUERY_NODE_VALUE == nodeType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } pFunc->node.resType = (SDataType){.bytes = getFirstLastInfoSize(paraBytes) + VARSTR_HEADER_SIZE, .type = TSDB_DATA_TYPE_BINARY}; } else { if (TSDB_DATA_TYPE_BINARY != paraType) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = ((SExprNode*)pPara)->resType; } return TSDB_CODE_SUCCESS; } static int32_t translateFirstLastPartial(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateFirstLastImpl(pFunc, pErrBuf, len, true); } static int32_t translateFirstLastMerge(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateFirstLastImpl(pFunc, pErrBuf, len, false); } static int32_t translateUniqueMode(SFunctionNode* pFunc, char* pErrBuf, int32_t len, bool isUnique) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SNode* pPara = nodesListGetNode(pFunc->pParameterList, 0); if (!nodesExprHasColumn(pPara)) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "The parameters of %s must contain columns", isUnique ? "UNIQUE" : "MODE"); } pFunc->node.resType = ((SExprNode*)pPara)->resType; return TSDB_CODE_SUCCESS; } static int32_t translateUnique(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateUniqueMode(pFunc, pErrBuf, len, true); } static int32_t translateMode(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateUniqueMode(pFunc, pErrBuf, len, false); } static int32_t translateDiff(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (numOfParams == 0 || numOfParams > 2) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t colType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_SIGNED_NUMERIC_TYPE(colType) && !IS_FLOAT_TYPE(colType) && TSDB_DATA_TYPE_BOOL != colType && !IS_TIMESTAMP_TYPE(colType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // param1 if (numOfParams == 2) { uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if (!IS_INTEGER_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SNode* pParamNode1 = nodesListGetNode(pFunc->pParameterList, 1); if (QUERY_NODE_VALUE != nodeType(pParamNode1)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } SValueNode* pValue = (SValueNode*)pParamNode1; if (pValue->datum.i != 0 && pValue->datum.i != 1) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "Second parameter of DIFF function should be only 0 or 1"); } pValue->notReserved = true; } uint8_t resType; if (IS_SIGNED_NUMERIC_TYPE(colType) || IS_TIMESTAMP_TYPE(colType) || TSDB_DATA_TYPE_BOOL == colType) { resType = TSDB_DATA_TYPE_BIGINT; } else { resType = TSDB_DATA_TYPE_DOUBLE; } pFunc->node.resType = (SDataType){.bytes = tDataTypes[resType].bytes, .type = resType}; return TSDB_CODE_SUCCESS; } static EFuncReturnRows diffEstReturnRows(SFunctionNode* pFunc) { if (1 == LIST_LENGTH(pFunc->pParameterList)) { return FUNC_RETURN_ROWS_N_MINUS_1; } return 1 == ((SValueNode*)nodesListGetNode(pFunc->pParameterList, 1))->datum.i ? FUNC_RETURN_ROWS_INDEFINITE : FUNC_RETURN_ROWS_N_MINUS_1; } static int32_t translateLength(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } if (!IS_STR_DATA_TYPE(((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateConcatImpl(SFunctionNode* pFunc, char* pErrBuf, int32_t len, int32_t minParaNum, int32_t maxParaNum, bool hasSep) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (numOfParams < minParaNum || numOfParams > maxParaNum) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t resultType = TSDB_DATA_TYPE_BINARY; int32_t resultBytes = 0; int32_t sepBytes = 0; // concat_ws separator should be constant string if (hasSep) { SNode* pPara = nodesListGetNode(pFunc->pParameterList, 0); if (nodeType(pPara) != QUERY_NODE_VALUE) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "The first parameter of CONCAT_WS function can only be constant string"); } } /* For concat/concat_ws function, if params have NCHAR type, promote the final result to NCHAR */ for (int32_t i = 0; i < numOfParams; ++i) { SNode* pPara = nodesListGetNode(pFunc->pParameterList, i); uint8_t paraType = ((SExprNode*)pPara)->resType.type; if (!IS_STR_DATA_TYPE(paraType) && !IS_NULL_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (TSDB_DATA_TYPE_NCHAR == paraType) { resultType = paraType; } } for (int32_t i = 0; i < numOfParams; ++i) { SNode* pPara = nodesListGetNode(pFunc->pParameterList, i); uint8_t paraType = ((SExprNode*)pPara)->resType.type; int32_t paraBytes = ((SExprNode*)pPara)->resType.bytes; int32_t factor = 1; if (IS_NULL_TYPE(paraType)) { resultType = TSDB_DATA_TYPE_VARCHAR; resultBytes = 0; sepBytes = 0; break; } if (TSDB_DATA_TYPE_NCHAR == resultType && TSDB_DATA_TYPE_VARCHAR == paraType) { factor *= TSDB_NCHAR_SIZE; } resultBytes += paraBytes * factor; if (i == 0) { sepBytes = paraBytes * factor; } } if (hasSep) { resultBytes += sepBytes * (numOfParams - 3); } pFunc->node.resType = (SDataType){.bytes = resultBytes, .type = resultType}; return TSDB_CODE_SUCCESS; } static int32_t translateConcat(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateConcatImpl(pFunc, pErrBuf, len, 2, 8, false); } static int32_t translateConcatWs(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { return translateConcatImpl(pFunc, pErrBuf, len, 3, 9, true); } static int32_t translateSubstr(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (2 != numOfParams && 3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SExprNode* pPara0 = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 0); SExprNode* pPara1 = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 1); uint8_t para0Type = pPara0->resType.type; uint8_t para1Type = pPara1->resType.type; if (!IS_STR_DATA_TYPE(para0Type) || !IS_INTEGER_TYPE(para1Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (((SValueNode*)pPara1)->datum.i == 0) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } if (3 == numOfParams) { SExprNode* pPara2 = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 2); uint8_t para2Type = pPara2->resType.type; if (!IS_INTEGER_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } int64_t v = ((SValueNode*)pPara2)->datum.i; if (v < 0) { return invaildFuncParaValueErrMsg(pErrBuf, len, pFunc->functionName); } } pFunc->node.resType = (SDataType){.bytes = pPara0->resType.bytes, .type = pPara0->resType.type}; return TSDB_CODE_SUCCESS; } static int32_t translateCast(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { // The number of parameters has been limited by the syntax definition // The function return type has been set during syntax parsing uint8_t para2Type = pFunc->node.resType.type; int32_t para2Bytes = pFunc->node.resType.bytes; if (IS_STR_DATA_TYPE(para2Type)) { para2Bytes -= VARSTR_HEADER_SIZE; } if (para2Bytes <= 0 || para2Bytes > 4096) { // cast dst var type length limits to 4096 bytes return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "CAST function converted length should be in range [0, 4096] bytes"); } // add database precision as param uint8_t dbPrec = pFunc->node.resType.precision; addDbPrecisonParam(&pFunc->pParameterList, dbPrec); return TSDB_CODE_SUCCESS; } static int32_t translateToIso8601(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (1 != numOfParams && 2 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } // param0 uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; if (!IS_INTEGER_TYPE(paraType) && !IS_TIMESTAMP_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } if (QUERY_NODE_VALUE == nodeType(nodesListGetNode(pFunc->pParameterList, 0))) { SValueNode* pValue = (SValueNode*)nodesListGetNode(pFunc->pParameterList, 0); if (!validateTimestampDigits(pValue)) { pFunc->node.resType = (SDataType){.bytes = 0, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } } // param1 if (numOfParams == 2) { SValueNode* pValue = (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1); if (!validateTimezoneFormat(pValue)) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "Invalid timzone format"); } } else { // add default client timezone addTimezoneParam(pFunc->pParameterList); } // set result type pFunc->node.resType = (SDataType){.bytes = 64, .type = TSDB_DATA_TYPE_BINARY}; return TSDB_CODE_SUCCESS; } static int32_t translateToUnixtimestamp(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } if (!IS_STR_DATA_TYPE(((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // add database precision as param uint8_t dbPrec = pFunc->node.resType.precision; addDbPrecisonParam(&pFunc->pParameterList, dbPrec); pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateTimeTruncate(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (2 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } uint8_t para1Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType.type; uint8_t para2Type = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 1))->resType.type; if ((!IS_STR_DATA_TYPE(para1Type) && !IS_INTEGER_TYPE(para1Type) && !IS_TIMESTAMP_TYPE(para1Type)) || !IS_INTEGER_TYPE(para2Type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } // add database precision as param uint8_t dbPrec = pFunc->node.resType.precision; int32_t ret = validateTimeUnitParam(dbPrec, (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1)); if (ret == TIME_UNIT_TOO_SMALL) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "TIMETRUNCATE function time unit parameter should be greater than db precision"); } else if (ret == TIME_UNIT_INVALID) { return buildFuncErrMsg( pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "TIMETRUNCATE function time unit parameter should be one of the following: [1b, 1u, 1a, 1s, 1m, 1h, 1d, 1w]"); } addDbPrecisonParam(&pFunc->pParameterList, dbPrec); pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_TIMESTAMP].bytes, .type = TSDB_DATA_TYPE_TIMESTAMP}; return TSDB_CODE_SUCCESS; } static int32_t translateTimeDiff(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { int32_t numOfParams = LIST_LENGTH(pFunc->pParameterList); if (2 != numOfParams && 3 != numOfParams) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } for (int32_t i = 0; i < 2; ++i) { uint8_t paraType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, i))->resType.type; if (!IS_STR_DATA_TYPE(paraType) && !IS_INTEGER_TYPE(paraType) && !IS_TIMESTAMP_TYPE(paraType)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } if (3 == numOfParams) { if (!IS_INTEGER_TYPE(((SExprNode*)nodesListGetNode(pFunc->pParameterList, 2))->resType.type)) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } } // add database precision as param uint8_t dbPrec = pFunc->node.resType.precision; if (3 == numOfParams) { int32_t ret = validateTimeUnitParam(dbPrec, (SValueNode*)nodesListGetNode(pFunc->pParameterList, 2)); if (ret == TIME_UNIT_TOO_SMALL) { return buildFuncErrMsg(pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "TIMEDIFF function time unit parameter should be greater than db precision"); } else if (ret == TIME_UNIT_INVALID) { return buildFuncErrMsg( pErrBuf, len, TSDB_CODE_FUNC_FUNTION_ERROR, "TIMEDIFF function time unit parameter should be one of the following: [1b, 1u, 1a, 1s, 1m, 1h, 1d, 1w]"); } } addDbPrecisonParam(&pFunc->pParameterList, dbPrec); pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes, .type = TSDB_DATA_TYPE_BIGINT}; return TSDB_CODE_SUCCESS; } static int32_t translateToJson(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return invaildFuncParaNumErrMsg(pErrBuf, len, pFunc->functionName); } SExprNode* pPara = (SExprNode*)nodesListGetNode(pFunc->pParameterList, 0); if (QUERY_NODE_VALUE != nodeType(pPara) || (!IS_VAR_DATA_TYPE(pPara->resType.type))) { return invaildFuncParaTypeErrMsg(pErrBuf, len, pFunc->functionName); } pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_JSON].bytes, .type = TSDB_DATA_TYPE_JSON}; return TSDB_CODE_SUCCESS; } static int32_t translateSelectValue(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType; return TSDB_CODE_SUCCESS; } static int32_t translateBlockDistFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = 128, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateBlockDistInfoFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = 128, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateGroupKeyFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = ((SExprNode*)nodesListGetNode(pFunc->pParameterList, 0))->resType; return TSDB_CODE_SUCCESS; } static bool getBlockDistFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(STableBlockDistInfo); return true; } static int32_t translateGroupKey(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { if (1 != LIST_LENGTH(pFunc->pParameterList)) { return TSDB_CODE_SUCCESS; } SNode* pPara = nodesListGetNode(pFunc->pParameterList, 0); pFunc->node.resType = ((SExprNode*)pPara)->resType; return TSDB_CODE_SUCCESS; } static int32_t translateDatabaseFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = TSDB_DB_NAME_LEN, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateClientVersionFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = TSDB_VERSION_LEN, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateServerVersionFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = TSDB_VERSION_LEN, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateServerStatusFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = tDataTypes[TSDB_DATA_TYPE_INT].bytes, .type = TSDB_DATA_TYPE_INT}; return TSDB_CODE_SUCCESS; } static int32_t translateCurrentUserFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = TSDB_USER_LEN, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } static int32_t translateUserFunc(SFunctionNode* pFunc, char* pErrBuf, int32_t len) { pFunc->node.resType = (SDataType){.bytes = TSDB_USER_LEN, .type = TSDB_DATA_TYPE_VARCHAR}; return TSDB_CODE_SUCCESS; } // clang-format off const SBuiltinFuncDefinition funcMgtBuiltins[] = { { .name = "count", .type = FUNCTION_TYPE_COUNT, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SPECIAL_DATA_REQUIRED, .translateFunc = translateCount, .dataRequiredFunc = countDataRequired, .getEnvFunc = getCountFuncEnv, .initFunc = functionSetup, .processFunc = countFunction, .sprocessFunc = countScalarFunction, .finalizeFunc = functionFinalize, .invertFunc = countInvertFunction, .combineFunc = combineFunction, .pPartialFunc = "count", .pMergeFunc = "sum" }, { .name = "sum", .type = FUNCTION_TYPE_SUM, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SPECIAL_DATA_REQUIRED, .translateFunc = translateSum, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getSumFuncEnv, .initFunc = functionSetup, .processFunc = sumFunction, .sprocessFunc = sumScalarFunction, .finalizeFunc = functionFinalize, .invertFunc = sumInvertFunction, .combineFunc = sumCombine, .pPartialFunc = "sum", .pMergeFunc = "sum" }, { .name = "min", .type = FUNCTION_TYPE_MIN, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SPECIAL_DATA_REQUIRED | FUNC_MGT_SELECT_FUNC, .translateFunc = translateMinMax, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getMinmaxFuncEnv, .initFunc = minmaxFunctionSetup, .processFunc = minFunction, .sprocessFunc = minScalarFunction, .finalizeFunc = minmaxFunctionFinalize, .combineFunc = minCombine, .pPartialFunc = "min", .pMergeFunc = "min" }, { .name = "max", .type = FUNCTION_TYPE_MAX, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SPECIAL_DATA_REQUIRED | FUNC_MGT_SELECT_FUNC, .translateFunc = translateMinMax, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getMinmaxFuncEnv, .initFunc = minmaxFunctionSetup, .processFunc = maxFunction, .sprocessFunc = maxScalarFunction, .finalizeFunc = minmaxFunctionFinalize, .combineFunc = maxCombine, .pPartialFunc = "max", .pMergeFunc = "max" }, { .name = "stddev", .type = FUNCTION_TYPE_STDDEV, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = getStddevFuncEnv, .initFunc = stddevFunctionSetup, .processFunc = stddevFunction, .sprocessFunc = stddevScalarFunction, .finalizeFunc = stddevFinalize, .invertFunc = stddevInvertFunction, .combineFunc = stddevCombine, .pPartialFunc = "_stddev_partial", .pMergeFunc = "_stddev_merge" }, { .name = "_stddev_partial", .type = FUNCTION_TYPE_STDDEV_PARTIAL, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateStddevPartial, .getEnvFunc = getStddevFuncEnv, .initFunc = stddevFunctionSetup, .processFunc = stddevFunction, .finalizeFunc = stddevPartialFinalize, .invertFunc = stddevInvertFunction, .combineFunc = stddevCombine, }, { .name = "_stddev_merge", .type = FUNCTION_TYPE_STDDEV_MERGE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateStddevMerge, .getEnvFunc = getStddevFuncEnv, .initFunc = stddevFunctionSetup, .processFunc = stddevFunctionMerge, .finalizeFunc = stddevFinalize, .invertFunc = stddevInvertFunction, .combineFunc = stddevCombine, }, { .name = "leastsquares", .type = FUNCTION_TYPE_LEASTSQUARES, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateLeastSQR, .getEnvFunc = getLeastSQRFuncEnv, .initFunc = leastSQRFunctionSetup, .processFunc = leastSQRFunction, .sprocessFunc = leastSQRScalarFunction, .finalizeFunc = leastSQRFinalize, .invertFunc = NULL, .combineFunc = leastSQRCombine, }, { .name = "avg", .type = FUNCTION_TYPE_AVG, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateInNumOutDou, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getAvgFuncEnv, .initFunc = avgFunctionSetup, .processFunc = avgFunction, .sprocessFunc = avgScalarFunction, .finalizeFunc = avgFinalize, .invertFunc = avgInvertFunction, .combineFunc = avgCombine, .pPartialFunc = "_avg_partial", .pMergeFunc = "_avg_merge" }, { .name = "_avg_partial", .type = FUNCTION_TYPE_AVG_PARTIAL, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateAvgPartial, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getAvgFuncEnv, .initFunc = avgFunctionSetup, .processFunc = avgFunction, .finalizeFunc = avgPartialFinalize, .invertFunc = avgInvertFunction, .combineFunc = avgCombine, }, { .name = "_avg_merge", .type = FUNCTION_TYPE_AVG_MERGE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateAvgMerge, .getEnvFunc = getAvgFuncEnv, .initFunc = avgFunctionSetup, .processFunc = avgFunctionMerge, .finalizeFunc = avgFinalize, .invertFunc = avgInvertFunction, .combineFunc = avgCombine, }, { .name = "percentile", .type = FUNCTION_TYPE_PERCENTILE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_REPEAT_SCAN_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translatePercentile, .getEnvFunc = getPercentileFuncEnv, .initFunc = percentileFunctionSetup, .processFunc = percentileFunction, .sprocessFunc = percentileScalarFunction, .finalizeFunc = percentileFinalize, .invertFunc = NULL, .combineFunc = NULL, }, { .name = "apercentile", .type = FUNCTION_TYPE_APERCENTILE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateApercentile, .getEnvFunc = getApercentileFuncEnv, .initFunc = apercentileFunctionSetup, .processFunc = apercentileFunction, .sprocessFunc = apercentileScalarFunction, .finalizeFunc = apercentileFinalize, .invertFunc = NULL, .combineFunc = apercentileCombine, .pPartialFunc = "_apercentile_partial", .pMergeFunc = "_apercentile_merge", .createMergeParaFuc = apercentileCreateMergeParam }, { .name = "_apercentile_partial", .type = FUNCTION_TYPE_APERCENTILE_PARTIAL, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateApercentilePartial, .getEnvFunc = getApercentileFuncEnv, .initFunc = apercentileFunctionSetup, .processFunc = apercentileFunction, .finalizeFunc = apercentilePartialFinalize, .invertFunc = NULL, .combineFunc = apercentileCombine, }, { .name = "_apercentile_merge", .type = FUNCTION_TYPE_APERCENTILE_MERGE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateApercentileMerge, .getEnvFunc = getApercentileFuncEnv, .initFunc = apercentileFunctionSetup, .processFunc = apercentileFunctionMerge, .finalizeFunc = apercentileFinalize, .invertFunc = NULL, .combineFunc = apercentileCombine, }, { .name = "top", .type = FUNCTION_TYPE_TOP, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_ROWS_FUNC | FUNC_MGT_KEEP_ORDER_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_FORBID_FILL_FUNC, .translateFunc = translateTopBot, .getEnvFunc = getTopBotFuncEnv, .initFunc = topBotFunctionSetup, .processFunc = topFunction, .sprocessFunc = topBotScalarFunction, .finalizeFunc = topBotFinalize, .combineFunc = topCombine, .pPartialFunc = "top", .pMergeFunc = "top", .createMergeParaFuc = topBotCreateMergeParam }, { .name = "bottom", .type = FUNCTION_TYPE_BOTTOM, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_ROWS_FUNC | FUNC_MGT_KEEP_ORDER_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_FORBID_FILL_FUNC, .translateFunc = translateTopBot, .getEnvFunc = getTopBotFuncEnv, .initFunc = topBotFunctionSetup, .processFunc = bottomFunction, .sprocessFunc = topBotScalarFunction, .finalizeFunc = topBotFinalize, .combineFunc = bottomCombine, .pPartialFunc = "bottom", .pMergeFunc = "bottom", .createMergeParaFuc = topBotCreateMergeParam }, { .name = "spread", .type = FUNCTION_TYPE_SPREAD, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateSpread, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getSpreadFuncEnv, .initFunc = spreadFunctionSetup, .processFunc = spreadFunction, .sprocessFunc = spreadScalarFunction, .finalizeFunc = spreadFinalize, .invertFunc = NULL, .combineFunc = spreadCombine, .pPartialFunc = "_spread_partial", .pMergeFunc = "_spread_merge" }, { .name = "_spread_partial", .type = FUNCTION_TYPE_SPREAD_PARTIAL, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateSpreadPartial, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getSpreadFuncEnv, .initFunc = spreadFunctionSetup, .processFunc = spreadFunction, .finalizeFunc = spreadPartialFinalize, .invertFunc = NULL, .combineFunc = spreadCombine, }, { .name = "_spread_merge", .type = FUNCTION_TYPE_SPREAD_MERGE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateSpreadMerge, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getSpreadFuncEnv, .initFunc = spreadFunctionSetup, .processFunc = spreadFunctionMerge, .finalizeFunc = spreadFinalize, .invertFunc = NULL, .combineFunc = spreadCombine, }, { .name = "elapsed", .type = FUNCTION_TYPE_ELAPSED, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_INTERVAL_INTERPO_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .dataRequiredFunc = statisDataRequired, .translateFunc = translateElapsed, .getEnvFunc = getElapsedFuncEnv, .initFunc = elapsedFunctionSetup, .processFunc = elapsedFunction, .finalizeFunc = elapsedFinalize, .invertFunc = NULL, .combineFunc = elapsedCombine, }, { .name = "_elapsed_partial", .type = FUNCTION_TYPE_ELAPSED, .classification = FUNC_MGT_AGG_FUNC, .dataRequiredFunc = statisDataRequired, .translateFunc = translateElapsedPartial, .getEnvFunc = getElapsedFuncEnv, .initFunc = elapsedFunctionSetup, .processFunc = elapsedFunction, .finalizeFunc = elapsedPartialFinalize, .invertFunc = NULL, .combineFunc = elapsedCombine, }, { .name = "_elapsed_merge", .type = FUNCTION_TYPE_ELAPSED, .classification = FUNC_MGT_AGG_FUNC, .dataRequiredFunc = statisDataRequired, .translateFunc = translateElapsedMerge, .getEnvFunc = getElapsedFuncEnv, .initFunc = elapsedFunctionSetup, .processFunc = elapsedFunctionMerge, .finalizeFunc = elapsedFinalize, .invertFunc = NULL, .combineFunc = elapsedCombine, }, { .name = "interp", .type = FUNCTION_TYPE_INTERP, .classification = FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_INTERVAL_INTERPO_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_FORBID_STABLE_FUNC, .translateFunc = translateInterp, .getEnvFunc = getSelectivityFuncEnv, .initFunc = functionSetup, .processFunc = NULL, .finalizeFunc = NULL }, { .name = "derivative", .type = FUNCTION_TYPE_DERIVATIVE, .classification = FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC | FUNC_MGT_KEEP_ORDER_FUNC | FUNC_MGT_CUMULATIVE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateDerivative, .getEnvFunc = getDerivativeFuncEnv, .initFunc = derivativeFuncSetup, .processFunc = derivativeFunction, .sprocessFunc = derivativeScalarFunction, .finalizeFunc = functionFinalize, .estimateReturnRowsFunc = derivativeEstReturnRows }, { .name = "irate", .type = FUNCTION_TYPE_IRATE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateIrate, .getEnvFunc = getIrateFuncEnv, .initFunc = irateFuncSetup, .processFunc = irateFunction, .sprocessFunc = irateScalarFunction, .finalizeFunc = irateFinalize }, { .name = "last_row", .type = FUNCTION_TYPE_LAST_ROW, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLast, .dynDataRequiredFunc = lastDynDataReq, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = lastRowFunction, .sprocessFunc = firstLastScalarFunction, .pPartialFunc = "_last_row_partial", .pMergeFunc = "_last_row_merge", .finalizeFunc = firstLastFinalize }, { .name = "_cache_last_row", .type = FUNCTION_TYPE_CACHE_LAST_ROW, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateFirstLast, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = cachedLastRowFunction, .finalizeFunc = firstLastFinalize }, { .name = "_last_row_partial", .type = FUNCTION_TYPE_LAST_PARTIAL, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLastPartial, .dynDataRequiredFunc = lastDynDataReq, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = lastRowFunction, .finalizeFunc = firstLastPartialFinalize, }, { .name = "_last_row_merge", .type = FUNCTION_TYPE_LAST_MERGE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLastMerge, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = lastFunctionMerge, .finalizeFunc = firstLastFinalize, }, { .name = "first", .type = FUNCTION_TYPE_FIRST, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLast, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = firstFunction, .sprocessFunc = firstLastScalarFunction, .finalizeFunc = firstLastFinalize, .pPartialFunc = "_first_partial", .pMergeFunc = "_first_merge", .combineFunc = firstCombine, }, { .name = "_first_partial", .type = FUNCTION_TYPE_FIRST_PARTIAL, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLastPartial, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = firstFunction, .finalizeFunc = firstLastPartialFinalize, .combineFunc = firstCombine, }, { .name = "_first_merge", .type = FUNCTION_TYPE_FIRST_MERGE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLastMerge, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = firstFunctionMerge, .finalizeFunc = firstLastFinalize, .combineFunc = firstCombine, }, { .name = "last", .type = FUNCTION_TYPE_LAST, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLast, .dynDataRequiredFunc = lastDynDataReq, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = lastFunction, .sprocessFunc = firstLastScalarFunction, .finalizeFunc = firstLastFinalize, .pPartialFunc = "_last_partial", .pMergeFunc = "_last_merge", .combineFunc = lastCombine, }, { .name = "_last_partial", .type = FUNCTION_TYPE_LAST_PARTIAL, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLastPartial, .dynDataRequiredFunc = lastDynDataReq, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = lastFunction, .finalizeFunc = firstLastPartialFinalize, .combineFunc = lastCombine, }, { .name = "_last_merge", .type = FUNCTION_TYPE_LAST_MERGE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_RES_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateFirstLastMerge, .getEnvFunc = getFirstLastFuncEnv, .initFunc = functionSetup, .processFunc = lastFunctionMerge, .finalizeFunc = firstLastFinalize, .combineFunc = lastCombine, }, { .name = "twa", .type = FUNCTION_TYPE_TWA, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_INTERVAL_INTERPO_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateInNumOutDou, .dataRequiredFunc = statisDataRequired, .getEnvFunc = getTwaFuncEnv, .initFunc = twaFunctionSetup, .processFunc = twaFunction, .sprocessFunc = twaScalarFunction, .finalizeFunc = twaFinalize }, { .name = "histogram", .type = FUNCTION_TYPE_HISTOGRAM, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_MULTI_ROWS_FUNC | FUNC_MGT_FORBID_FILL_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateHistogram, .getEnvFunc = getHistogramFuncEnv, .initFunc = histogramFunctionSetup, .processFunc = histogramFunction, .sprocessFunc = histogramScalarFunction, .finalizeFunc = histogramFinalize, .invertFunc = NULL, .combineFunc = histogramCombine, .pPartialFunc = "_histogram_partial", .pMergeFunc = "_histogram_merge", }, { .name = "_histogram_partial", .type = FUNCTION_TYPE_HISTOGRAM_PARTIAL, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_MULTI_ROWS_FUNC | FUNC_MGT_FORBID_FILL_FUNC, .translateFunc = translateHistogramPartial, .getEnvFunc = getHistogramFuncEnv, .initFunc = histogramFunctionSetup, .processFunc = histogramFunctionPartial, .finalizeFunc = histogramPartialFinalize, .invertFunc = NULL, .combineFunc = histogramCombine, }, { .name = "_histogram_merge", .type = FUNCTION_TYPE_HISTOGRAM_MERGE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_MULTI_ROWS_FUNC | FUNC_MGT_FORBID_FILL_FUNC, .translateFunc = translateHistogramMerge, .getEnvFunc = getHistogramFuncEnv, .initFunc = functionSetup, .processFunc = histogramFunctionMerge, .finalizeFunc = histogramFinalize, .invertFunc = NULL, .combineFunc = histogramCombine, }, { .name = "hyperloglog", .type = FUNCTION_TYPE_HYPERLOGLOG, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateHLL, .getEnvFunc = getHLLFuncEnv, .initFunc = functionSetup, .processFunc = hllFunction, .sprocessFunc = hllScalarFunction, .finalizeFunc = hllFinalize, .invertFunc = NULL, .combineFunc = hllCombine, .pPartialFunc = "_hyperloglog_partial", .pMergeFunc = "_hyperloglog_merge" }, { .name = "_hyperloglog_partial", .type = FUNCTION_TYPE_HYPERLOGLOG_PARTIAL, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateHLLPartial, .getEnvFunc = getHLLFuncEnv, .initFunc = functionSetup, .processFunc = hllFunction, .finalizeFunc = hllPartialFinalize, .invertFunc = NULL, .combineFunc = hllCombine, }, { .name = "_hyperloglog_merge", .type = FUNCTION_TYPE_HYPERLOGLOG_MERGE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateHLLMerge, .getEnvFunc = getHLLFuncEnv, .initFunc = functionSetup, .processFunc = hllFunctionMerge, .finalizeFunc = hllFinalize, .invertFunc = NULL, .combineFunc = hllCombine, }, { .name = "diff", .type = FUNCTION_TYPE_DIFF, .classification = FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_KEEP_ORDER_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_CUMULATIVE_FUNC, .translateFunc = translateDiff, .getEnvFunc = getDiffFuncEnv, .initFunc = diffFunctionSetup, .processFunc = diffFunction, .sprocessFunc = diffScalarFunction, .finalizeFunc = functionFinalize, .estimateReturnRowsFunc = diffEstReturnRows, }, { .name = "statecount", .type = FUNCTION_TYPE_STATE_COUNT, .classification = FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateStateCount, .getEnvFunc = getStateFuncEnv, .initFunc = functionSetup, .processFunc = stateCountFunction, .sprocessFunc = stateCountScalarFunction, .finalizeFunc = NULL }, { .name = "stateduration", .type = FUNCTION_TYPE_STATE_DURATION, .classification = FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateStateDuration, .getEnvFunc = getStateFuncEnv, .initFunc = functionSetup, .processFunc = stateDurationFunction, .sprocessFunc = stateDurationScalarFunction, .finalizeFunc = NULL }, { .name = "csum", .type = FUNCTION_TYPE_CSUM, .classification = FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_CUMULATIVE_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateCsum, .getEnvFunc = getCsumFuncEnv, .initFunc = functionSetup, .processFunc = csumFunction, .sprocessFunc = csumScalarFunction, .finalizeFunc = NULL, .estimateReturnRowsFunc = csumEstReturnRows, }, { .name = "mavg", .type = FUNCTION_TYPE_MAVG, .classification = FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC, .translateFunc = translateMavg, .getEnvFunc = getMavgFuncEnv, .initFunc = mavgFunctionSetup, .processFunc = mavgFunction, .sprocessFunc = mavgScalarFunction, .finalizeFunc = NULL }, { .name = "sample", .type = FUNCTION_TYPE_SAMPLE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_MULTI_ROWS_FUNC | FUNC_MGT_KEEP_ORDER_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_FORBID_FILL_FUNC, .translateFunc = translateSample, .getEnvFunc = getSampleFuncEnv, .initFunc = sampleFunctionSetup, .processFunc = sampleFunction, .sprocessFunc = sampleScalarFunction, .finalizeFunc = sampleFinalize }, { .name = "tail", .type = FUNCTION_TYPE_TAIL, .classification = FUNC_MGT_SELECT_FUNC | FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateTail, .getEnvFunc = getTailFuncEnv, .initFunc = tailFunctionSetup, .processFunc = tailFunction, .sprocessFunc = tailScalarFunction, .finalizeFunc = NULL }, { .name = "unique", .type = FUNCTION_TYPE_UNIQUE, .classification = FUNC_MGT_SELECT_FUNC | FUNC_MGT_INDEFINITE_ROWS_FUNC | FUNC_MGT_TIMELINE_FUNC | FUNC_MGT_FORBID_STREAM_FUNC | FUNC_MGT_IMPLICIT_TS_FUNC, .translateFunc = translateUnique, .getEnvFunc = getUniqueFuncEnv, .initFunc = uniqueFunctionSetup, .processFunc = uniqueFunction, .sprocessFunc = uniqueScalarFunction, .finalizeFunc = NULL }, { .name = "mode", .type = FUNCTION_TYPE_MODE, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateMode, .getEnvFunc = getModeFuncEnv, .initFunc = modeFunctionSetup, .processFunc = modeFunction, .sprocessFunc = modeScalarFunction, .finalizeFunc = modeFinalize, }, { .name = "abs", .type = FUNCTION_TYPE_ABS, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInOutNum, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = absFunction, .finalizeFunc = NULL }, { .name = "log", .type = FUNCTION_TYPE_LOG, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateLogarithm, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = logFunction, .finalizeFunc = NULL }, { .name = "pow", .type = FUNCTION_TYPE_POW, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateIn2NumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = powFunction, .finalizeFunc = NULL }, { .name = "sqrt", .type = FUNCTION_TYPE_SQRT, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = sqrtFunction, .finalizeFunc = NULL }, { .name = "ceil", .type = FUNCTION_TYPE_CEIL, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInOutNum, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = ceilFunction, .finalizeFunc = NULL }, { .name = "floor", .type = FUNCTION_TYPE_FLOOR, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInOutNum, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = floorFunction, .finalizeFunc = NULL }, { .name = "round", .type = FUNCTION_TYPE_ROUND, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInOutNum, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = roundFunction, .finalizeFunc = NULL }, { .name = "sin", .type = FUNCTION_TYPE_SIN, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = sinFunction, .finalizeFunc = NULL }, { .name = "cos", .type = FUNCTION_TYPE_COS, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = cosFunction, .finalizeFunc = NULL }, { .name = "tan", .type = FUNCTION_TYPE_TAN, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = tanFunction, .finalizeFunc = NULL }, { .name = "asin", .type = FUNCTION_TYPE_ASIN, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = asinFunction, .finalizeFunc = NULL }, { .name = "acos", .type = FUNCTION_TYPE_ACOS, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = acosFunction, .finalizeFunc = NULL }, { .name = "atan", .type = FUNCTION_TYPE_ATAN, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateInNumOutDou, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = atanFunction, .finalizeFunc = NULL }, { .name = "length", .type = FUNCTION_TYPE_LENGTH, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateLength, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = lengthFunction, .finalizeFunc = NULL }, { .name = "char_length", .type = FUNCTION_TYPE_CHAR_LENGTH, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateLength, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = charLengthFunction, .finalizeFunc = NULL }, { .name = "concat", .type = FUNCTION_TYPE_CONCAT, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateConcat, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = concatFunction, .finalizeFunc = NULL }, { .name = "concat_ws", .type = FUNCTION_TYPE_CONCAT_WS, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateConcatWs, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = concatWsFunction, .finalizeFunc = NULL }, { .name = "lower", .type = FUNCTION_TYPE_LOWER, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateInOutStr, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = lowerFunction, .finalizeFunc = NULL }, { .name = "upper", .type = FUNCTION_TYPE_UPPER, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateInOutStr, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = upperFunction, .finalizeFunc = NULL }, { .name = "ltrim", .type = FUNCTION_TYPE_LTRIM, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateLtrim, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = ltrimFunction, .finalizeFunc = NULL }, { .name = "rtrim", .type = FUNCTION_TYPE_RTRIM, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateRtrim, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = rtrimFunction, .finalizeFunc = NULL }, { .name = "substr", .type = FUNCTION_TYPE_SUBSTR, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_STRING_FUNC, .translateFunc = translateSubstr, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = substrFunction, .finalizeFunc = NULL }, { .name = "cast", .type = FUNCTION_TYPE_CAST, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateCast, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = castFunction, .finalizeFunc = NULL }, { .name = "to_iso8601", .type = FUNCTION_TYPE_TO_ISO8601, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateToIso8601, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = toISO8601Function, .finalizeFunc = NULL }, { .name = "to_unixtimestamp", .type = FUNCTION_TYPE_TO_UNIXTIMESTAMP, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateToUnixtimestamp, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = toUnixtimestampFunction, .finalizeFunc = NULL }, { .name = "timetruncate", .type = FUNCTION_TYPE_TIMETRUNCATE, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateTimeTruncate, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = timeTruncateFunction, .finalizeFunc = NULL }, { .name = "timediff", .type = FUNCTION_TYPE_TIMEDIFF, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateTimeDiff, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = timeDiffFunction, .finalizeFunc = NULL }, { .name = "now", .type = FUNCTION_TYPE_NOW, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_DATETIME_FUNC, .translateFunc = translateNowToday, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = nowFunction, .finalizeFunc = NULL }, { .name = "today", .type = FUNCTION_TYPE_TODAY, .classification = FUNC_MGT_SCALAR_FUNC | FUNC_MGT_DATETIME_FUNC, .translateFunc = translateNowToday, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = todayFunction, .finalizeFunc = NULL }, { .name = "timezone", .type = FUNCTION_TYPE_TIMEZONE, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateTimezone, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = timezoneFunction, .finalizeFunc = NULL }, { .name = "tbname", .type = FUNCTION_TYPE_TBNAME, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_SCAN_PC_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateTbnameColumn, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = qTbnameFunction, .finalizeFunc = NULL }, { .name = "_qstart", .type = FUNCTION_TYPE_QSTART, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_CLIENT_PC_FUNC, .translateFunc = translateTimePseudoColumn, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = NULL, .finalizeFunc = NULL }, { .name = "_qend", .type = FUNCTION_TYPE_QEND, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_CLIENT_PC_FUNC, .translateFunc = translateTimePseudoColumn, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = NULL, .finalizeFunc = NULL }, { .name = "_qduration", .type = FUNCTION_TYPE_QDURATION, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_CLIENT_PC_FUNC, .translateFunc = translateWduration, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = NULL, .finalizeFunc = NULL }, { .name = "_wstart", .type = FUNCTION_TYPE_WSTART, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_WINDOW_PC_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateTimePseudoColumn, .getEnvFunc = getTimePseudoFuncEnv, .initFunc = NULL, .sprocessFunc = winStartTsFunction, .finalizeFunc = NULL }, { .name = "_wend", .type = FUNCTION_TYPE_WEND, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_WINDOW_PC_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateTimePseudoColumn, .getEnvFunc = getTimePseudoFuncEnv, .initFunc = NULL, .sprocessFunc = winEndTsFunction, .finalizeFunc = NULL }, { .name = "_wduration", .type = FUNCTION_TYPE_WDURATION, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_WINDOW_PC_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateWduration, .getEnvFunc = getTimePseudoFuncEnv, .initFunc = NULL, .sprocessFunc = winDurFunction, .finalizeFunc = NULL }, { .name = "to_json", .type = FUNCTION_TYPE_TO_JSON, .classification = FUNC_MGT_SCALAR_FUNC, .translateFunc = translateToJson, .getEnvFunc = NULL, .initFunc = NULL, .sprocessFunc = toJsonFunction, .finalizeFunc = NULL }, { .name = "_select_value", .type = FUNCTION_TYPE_SELECT_VALUE, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateSelectValue, .getEnvFunc = getSelectivityFuncEnv, // todo remove this function later. .initFunc = functionSetup, .processFunc = NULL, .finalizeFunc = NULL, .pPartialFunc = "_select_value", .pMergeFunc = "_select_value" }, { .name = "_block_dist", .type = FUNCTION_TYPE_BLOCK_DIST, .classification = FUNC_MGT_AGG_FUNC, .translateFunc = translateBlockDistFunc, .getEnvFunc = getBlockDistFuncEnv, .initFunc = blockDistSetup, .processFunc = blockDistFunction, .finalizeFunc = blockDistFinalize }, { .name = "_block_dist_info", .type = FUNCTION_TYPE_BLOCK_DIST_INFO, .classification = FUNC_MGT_PSEUDO_COLUMN_FUNC | FUNC_MGT_SCAN_PC_FUNC, .translateFunc = translateBlockDistInfoFunc, }, { .name = "_group_key", .type = FUNCTION_TYPE_GROUP_KEY, .classification = FUNC_MGT_AGG_FUNC | FUNC_MGT_SELECT_FUNC | FUNC_MGT_KEEP_ORDER_FUNC, .translateFunc = translateGroupKey, .getEnvFunc = getGroupKeyFuncEnv, .initFunc = functionSetup, .processFunc = groupKeyFunction, .finalizeFunc = groupKeyFinalize, .pPartialFunc = "_group_key", .pMergeFunc = "_group_key" }, { .name = "database", .type = FUNCTION_TYPE_DATABASE, .classification = FUNC_MGT_SYSTEM_INFO_FUNC | FUNC_MGT_SCALAR_FUNC, .translateFunc = translateDatabaseFunc, }, { .name = "client_version", .type = FUNCTION_TYPE_CLIENT_VERSION, .classification = FUNC_MGT_SYSTEM_INFO_FUNC | FUNC_MGT_SCALAR_FUNC, .translateFunc = translateClientVersionFunc, }, { .name = "server_version", .type = FUNCTION_TYPE_SERVER_VERSION, .classification = FUNC_MGT_SYSTEM_INFO_FUNC | FUNC_MGT_SCALAR_FUNC, .translateFunc = translateServerVersionFunc, }, { .name = "server_status", .type = FUNCTION_TYPE_SERVER_STATUS, .classification = FUNC_MGT_SYSTEM_INFO_FUNC | FUNC_MGT_SCALAR_FUNC, .translateFunc = translateServerStatusFunc, }, { .name = "current_user", .type = FUNCTION_TYPE_CURRENT_USER, .classification = FUNC_MGT_SYSTEM_INFO_FUNC | FUNC_MGT_SCALAR_FUNC, .translateFunc = translateCurrentUserFunc, }, { .name = "user", .type = FUNCTION_TYPE_USER, .classification = FUNC_MGT_SYSTEM_INFO_FUNC | FUNC_MGT_SCALAR_FUNC, .translateFunc = translateUserFunc, }, }; // clang-format on const int32_t funcMgtBuiltinsNum = (sizeof(funcMgtBuiltins) / sizeof(SBuiltinFuncDefinition));