#include "function.h" #include "scalar.h" #include "tdatablock.h" #include "ttime.h" #include "sclInt.h" #include "sclvector.h" typedef float (*_float_fn)(float); typedef double (*_double_fn)(double); typedef double (*_double_fn_2)(double, double); typedef int (*_conv_fn)(int); typedef void (*_trim_fn)(char *, char*, int32_t, int32_t); typedef int16_t (*_len_fn)(char *, int32_t); /** Math functions **/ static double tlog(double v, double base) { return log(v) / log(base); } int32_t absFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; int32_t type = GET_PARAM_TYPE(pInput); if (!IS_NUMERIC_TYPE(type)) { return TSDB_CODE_FAILED; } switch (type) { case TSDB_DATA_TYPE_FLOAT: { float *in = (float *)pInputData->pData; float *out = (float *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = (in[i] >= 0)? in[i] : -in[i]; } break; } case TSDB_DATA_TYPE_DOUBLE: { double *in = (double *)pInputData->pData; double *out = (double *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = (in[i] >= 0)? in[i] : -in[i]; } break; } case TSDB_DATA_TYPE_TINYINT: { int8_t *in = (int8_t *)pInputData->pData; int8_t *out = (int8_t *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = (in[i] >= 0)? in[i] : -in[i]; } break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t *in = (int16_t *)pInputData->pData; int16_t *out = (int16_t *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = (in[i] >= 0)? in[i] : -in[i]; } break; } case TSDB_DATA_TYPE_INT: { int32_t *in = (int32_t *)pInputData->pData; int32_t *out = (int32_t *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = (in[i] >= 0)? in[i] : -in[i]; } break; } case TSDB_DATA_TYPE_BIGINT: { int64_t *in = (int64_t *)pInputData->pData; int64_t *out = (int64_t *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = (in[i] >= 0)? in[i] : -in[i]; } break; } default: { colDataAssign(pOutputData, pInputData, pInput->numOfRows); } } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } static int32_t doScalarFunctionUnique(SScalarParam *pInput, int32_t inputNum, SScalarParam* pOutput, _double_fn valFn) { int32_t type = GET_PARAM_TYPE(pInput); if (inputNum != 1 || !IS_NUMERIC_TYPE(type)) { return TSDB_CODE_FAILED; } SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; _getDoubleValue_fn_t getValueFn = getVectorDoubleValueFn(type); double *out = (double *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = valFn(getValueFn(pInputData->pData, i)); } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } static int32_t doScalarFunctionUnique2(SScalarParam *pInput, int32_t inputNum, SScalarParam* pOutput, _double_fn_2 valFn) { if (inputNum != 2 || !IS_NUMERIC_TYPE(GET_PARAM_TYPE(&pInput[0])) || !IS_NUMERIC_TYPE(GET_PARAM_TYPE(&pInput[1]))) { return TSDB_CODE_FAILED; } SColumnInfoData *pInputData[2]; SColumnInfoData *pOutputData = pOutput->columnData; _getDoubleValue_fn_t getValueFn[2]; for (int32_t i = 0; i < inputNum; ++i) { pInputData[i] = pInput[i].columnData; getValueFn[i]= getVectorDoubleValueFn(GET_PARAM_TYPE(&pInput[i])); } double *out = (double *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData[0]->nullbitmap, i) || colDataIsNull_f(pInputData[1]->nullbitmap, 0)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = valFn(getValueFn[0](pInputData[0]->pData, i), getValueFn[1](pInputData[1]->pData, 0)); } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } static int32_t doScalarFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam* pOutput, _float_fn f1, _double_fn d1) { int32_t type = GET_PARAM_TYPE(pInput); if (inputNum != 1 || !IS_NUMERIC_TYPE(type)) { return TSDB_CODE_FAILED; } SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; switch (type) { case TSDB_DATA_TYPE_FLOAT: { float *in = (float *)pInputData->pData; float *out = (float *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = f1(in[i]); } break; } case TSDB_DATA_TYPE_DOUBLE: { double *in = (double *)pInputData->pData; double *out = (double *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_f(pInputData->nullbitmap, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = d1(in[i]); } break; } default: { colDataAssign(pOutputData, pInputData, pInput->numOfRows); } } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } /** String functions **/ static int16_t tlength(char *input, int32_t type) { return varDataLen(input); } static int16_t tcharlength(char *input, int32_t type) { if (type == TSDB_DATA_TYPE_VARCHAR) { return varDataLen(input); } else { //NCHAR return varDataLen(input) / TSDB_NCHAR_SIZE; } } static void tltrim(char *input, char *output, int32_t type, int32_t charLen) { int32_t numOfSpaces = 0; if (type == TSDB_DATA_TYPE_VARCHAR) { for (int32_t i = 0; i < charLen; ++i) { if (!isspace(*(varDataVal(input) + i))) { break; } numOfSpaces++; } } else { //NCHAR for (int32_t i = 0; i < charLen; ++i) { if (!iswspace(*((uint32_t *)varDataVal(input) + i))) { break; } numOfSpaces++; } } int32_t resLen; if (type == TSDB_DATA_TYPE_VARCHAR) { resLen = charLen - numOfSpaces; memcpy(varDataVal(output), varDataVal(input) + numOfSpaces, resLen); } else { resLen = (charLen - numOfSpaces) * TSDB_NCHAR_SIZE; memcpy(varDataVal(output), varDataVal(input) + numOfSpaces * TSDB_NCHAR_SIZE, resLen); } varDataSetLen(output, resLen); } static void trtrim(char *input, char *output, int32_t type, int32_t charLen) { int32_t numOfSpaces = 0; if (type == TSDB_DATA_TYPE_VARCHAR) { for (int32_t i = charLen - 1; i >= 0; --i) { if (!isspace(*(varDataVal(input) + i))) { break; } numOfSpaces++; } } else { //NCHAR for (int32_t i = charLen - 1; i >= 0; --i) { if (!iswspace(*((uint32_t *)varDataVal(input) + i))) { break; } numOfSpaces++; } } int32_t resLen; if (type == TSDB_DATA_TYPE_VARCHAR) { resLen = charLen - numOfSpaces; } else { resLen = (charLen - numOfSpaces) * TSDB_NCHAR_SIZE; } memcpy(varDataVal(output), varDataVal(input), resLen); varDataSetLen(output, resLen); } static int32_t doLengthFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput, _len_fn lenFn) { int32_t type = GET_PARAM_TYPE(pInput); if (inputNum != 1 || !IS_VAR_DATA_TYPE(type)) { return TSDB_CODE_FAILED; } SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; char *in = pInputData->pData + pInputData->varmeta.offset[0]; int16_t *out = (int16_t *)pOutputData->pData; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_s(pInputData, i)) { colDataSetNull_f(pOutputData->nullbitmap, i); continue; } out[i] = lenFn(in, type); in += varDataTLen(in); } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } static int32_t concatCopyHelper(const char *input, char *output, bool hasNcharCol, int32_t type, int16_t *dataLen) { if (hasNcharCol && type == TSDB_DATA_TYPE_VARCHAR) { TdUcs4 *newBuf = taosMemoryCalloc((varDataLen(input) + 1) * TSDB_NCHAR_SIZE, 1); bool ret = taosMbsToUcs4(varDataVal(input), varDataLen(input), newBuf, (varDataLen(input) + 1) * TSDB_NCHAR_SIZE, NULL); if (!ret) { taosMemoryFree(newBuf); return TSDB_CODE_FAILED; } memcpy(varDataVal(output) + *dataLen, newBuf, varDataLen(input) * TSDB_NCHAR_SIZE); *dataLen += varDataLen(input) * TSDB_NCHAR_SIZE; taosMemoryFree(newBuf); } else { memcpy(varDataVal(output) + *dataLen, varDataVal(input), varDataLen(input)); *dataLen += varDataLen(input); } return TSDB_CODE_SUCCESS; } static int32_t getNumOfNullEntries(SColumnInfoData *pColumnInfoData, int32_t numOfRows) { int32_t numOfNulls = 0; if (!pColumnInfoData->hasNull) { return numOfNulls; } for (int i = 0; i < numOfRows; ++i) { if (pColumnInfoData->varmeta.offset[i] == -1) { numOfNulls++; } } return numOfNulls; } int32_t concatFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { if (inputNum < 2 || inputNum > 8) { // concat accpet 2-8 input strings return TSDB_CODE_FAILED; } SColumnInfoData **pInputData = taosMemoryCalloc(inputNum, sizeof(SColumnInfoData *)); SColumnInfoData *pOutputData = pOutput->columnData; char **input = taosMemoryCalloc(inputNum, POINTER_BYTES); char *outputBuf = NULL; int32_t inputLen = 0; int32_t numOfRows = 0; bool hasNcharCol = false; for (int32_t i = 0; i < inputNum; ++i) { int32_t type = GET_PARAM_TYPE(&pInput[i]); if (!IS_VAR_DATA_TYPE(type)) { return TSDB_CODE_FAILED; } if (type == TSDB_DATA_TYPE_NCHAR) { hasNcharCol = true; } if (pInput[i].numOfRows > numOfRows) { numOfRows = pInput[i].numOfRows; } } for (int32_t i = 0; i < inputNum; ++i) { pInputData[i] = pInput[i].columnData; input[i] = pInputData[i]->pData + pInputData[i]->varmeta.offset[0]; int32_t factor = 1; if (hasNcharCol && (GET_PARAM_TYPE(&pInput[i]) == TSDB_DATA_TYPE_VARCHAR)) { factor = TSDB_NCHAR_SIZE; } int32_t numOfNulls = getNumOfNullEntries(pInputData[i], pInput[i].numOfRows); if (pInput[i].numOfRows == 1) { inputLen += (pInputData[i]->varmeta.length - VARSTR_HEADER_SIZE) * factor * (numOfRows - numOfNulls); } else { inputLen += pInputData[i]->varmeta.length - (numOfRows - numOfNulls) * VARSTR_HEADER_SIZE; } } int32_t outputLen = inputLen + numOfRows * VARSTR_HEADER_SIZE; outputBuf = taosMemoryCalloc(outputLen, 1); char *output = outputBuf; bool hasNull = false; for (int32_t k = 0; k < numOfRows; ++k) { for (int32_t i = 0; i < inputNum; ++i) { if (colDataIsNull_s(pInputData[i], k)) { colDataAppendNULL(pOutputData, k); hasNull = true; break; } } if (hasNull) { continue; } int16_t dataLen = 0; for (int32_t i = 0; i < inputNum; ++i) { int32_t ret = concatCopyHelper(input[i], output, hasNcharCol, GET_PARAM_TYPE(&pInput[i]), &dataLen); if (ret != TSDB_CODE_SUCCESS) { return ret; } if (pInput[i].numOfRows != 1) { input[i] += varDataTLen(input[i]); } } varDataSetLen(output, dataLen); colDataAppend(pOutputData, k, output, false); output += varDataTLen(output); } pOutput->numOfRows = numOfRows; taosMemoryFree(input); taosMemoryFree(outputBuf); taosMemoryFree(pInputData); return TSDB_CODE_SUCCESS; } int32_t concatWsFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { if (inputNum < 3 || inputNum > 9) { // concat accpet 3-9 input strings including the separator return TSDB_CODE_FAILED; } SColumnInfoData **pInputData = taosMemoryCalloc(inputNum, sizeof(SColumnInfoData *)); SColumnInfoData *pOutputData = pOutput->columnData; char **input = taosMemoryCalloc(inputNum, POINTER_BYTES); char *outputBuf = NULL; int32_t inputLen = 0; int32_t numOfRows = 0; bool hasNcharCol = false; for (int32_t i = 1; i < inputNum; ++i) { int32_t type = GET_PARAM_TYPE(&pInput[i]); if (!IS_VAR_DATA_TYPE(GET_PARAM_TYPE(&pInput[i]))) { return TSDB_CODE_FAILED; } if (type == TSDB_DATA_TYPE_NCHAR) { hasNcharCol = true; } if (pInput[i].numOfRows > numOfRows) { numOfRows = pInput[i].numOfRows; } } for (int32_t i = 0; i < inputNum; ++i) { pInputData[i] = pInput[i].columnData; input[i] = pInputData[i]->pData + pInputData[i]->varmeta.offset[0]; int32_t factor = 1; if (hasNcharCol && (GET_PARAM_TYPE(&pInput[i]) == TSDB_DATA_TYPE_VARCHAR)) { factor = TSDB_NCHAR_SIZE; } int32_t numOfNulls = getNumOfNullEntries(pInputData[i], pInput[i].numOfRows); if (i == 0) { // calculate required separator space inputLen += (pInputData[0]->varmeta.length - VARSTR_HEADER_SIZE) * (numOfRows - numOfNulls) * (inputNum - 2) * factor; } else if (pInput[i].numOfRows == 1) { inputLen += (pInputData[i]->varmeta.length - VARSTR_HEADER_SIZE) * (numOfRows - numOfNulls) * factor; } else { inputLen += pInputData[i]->varmeta.length - (numOfRows - numOfNulls) * VARSTR_HEADER_SIZE; } } int32_t outputLen = inputLen + numOfRows * VARSTR_HEADER_SIZE; outputBuf = taosMemoryCalloc(outputLen, 1); char *output = outputBuf; for (int32_t k = 0; k < numOfRows; ++k) { if (colDataIsNull_s(pInputData[0], k)) { colDataAppendNULL(pOutputData, k); continue; } int16_t dataLen = 0; for (int32_t i = 1; i < inputNum; ++i) { if (colDataIsNull_s(pInputData[i], k)) { continue; } int32_t ret = concatCopyHelper(input[i], output, hasNcharCol, GET_PARAM_TYPE(&pInput[i]), &dataLen); if (ret != TSDB_CODE_SUCCESS) { return ret; } if (pInput[i].numOfRows != 1) { input[i] += varDataTLen(input[i]); } if (i < inputNum - 1) { //insert the separator char *sep = pInputData[0]->pData; int32_t ret = concatCopyHelper(sep, output, hasNcharCol, GET_PARAM_TYPE(&pInput[0]), &dataLen); if (ret != TSDB_CODE_SUCCESS) { return ret; } } } varDataSetLen(output, dataLen); colDataAppend(pOutputData, k, output, false); output += varDataTLen(output); } pOutput->numOfRows = numOfRows; taosMemoryFree(input); taosMemoryFree(outputBuf); taosMemoryFree(pInputData); return TSDB_CODE_SUCCESS; } static int32_t doCaseConvFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput, _conv_fn convFn) { int32_t type = GET_PARAM_TYPE(pInput); if (inputNum != 1 || !IS_VAR_DATA_TYPE(type)) { return TSDB_CODE_FAILED; } SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; char *input = pInputData->pData + pInputData->varmeta.offset[0]; char *output = NULL; int32_t outputLen = pInputData->varmeta.length; char *outputBuf = taosMemoryCalloc(outputLen, 1); output = outputBuf; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_s(pInputData, i)) { colDataAppendNULL(pOutputData, i); continue; } int32_t len = varDataLen(input); if (type == TSDB_DATA_TYPE_VARCHAR) { for (int32_t j = 0; j < len; ++j) { *(varDataVal(output) + j) = convFn(*(varDataVal(input) + j)); } } else { //NCHAR for (int32_t j = 0; j < len / TSDB_NCHAR_SIZE; ++j) { *((uint32_t *)varDataVal(output) + j) = convFn(*((uint32_t *)varDataVal(input) + j)); } } varDataSetLen(output, len); colDataAppend(pOutputData, i, output, false); input += varDataTLen(input); output += varDataTLen(output); } pOutput->numOfRows = pInput->numOfRows; taosMemoryFree(outputBuf); return TSDB_CODE_SUCCESS; } static int32_t doTrimFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput, _trim_fn trimFn) { int32_t type = GET_PARAM_TYPE(pInput); if (inputNum != 1 || !IS_VAR_DATA_TYPE(type)) { return TSDB_CODE_FAILED; } SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; char *input = pInputData->pData + pInputData->varmeta.offset[0]; char *output = NULL; int32_t outputLen = pInputData->varmeta.length; char *outputBuf = taosMemoryCalloc(outputLen, 1); output = outputBuf; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_s(pInputData, i)) { colDataAppendNULL(pOutputData, i); continue; } int32_t len = varDataLen(input); int32_t charLen = (type == TSDB_DATA_TYPE_VARCHAR) ? len : len / TSDB_NCHAR_SIZE; trimFn(input, output, type, charLen); varDataSetLen(output, len); colDataAppend(pOutputData, i, output, false); input += varDataTLen(input); output += varDataTLen(output); } pOutput->numOfRows = pInput->numOfRows; taosMemoryFree(outputBuf); return TSDB_CODE_SUCCESS; } int32_t substrFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { if (inputNum != 2 && inputNum!= 3) { return TSDB_CODE_FAILED; } int32_t subPos = 0; GET_TYPED_DATA(subPos, int32_t, GET_PARAM_TYPE(&pInput[1]), pInput[1].columnData->pData); if (subPos == 0) { //subPos needs to be positive or negative values; return TSDB_CODE_FAILED; } int32_t subLen = INT16_MAX; if (inputNum == 3) { GET_TYPED_DATA(subLen, int32_t, GET_PARAM_TYPE(&pInput[2]), pInput[2].columnData->pData); if (subLen < 0) { //subLen cannot be negative return TSDB_CODE_FAILED; } subLen = (GET_PARAM_TYPE(pInput) == TSDB_DATA_TYPE_VARCHAR) ? subLen : subLen * TSDB_NCHAR_SIZE; } SColumnInfoData *pInputData = pInput->columnData; SColumnInfoData *pOutputData = pOutput->columnData; char *input = pInputData->pData + pInputData->varmeta.offset[0]; char *output = NULL; int32_t outputLen = pInputData->varmeta.length * pInput->numOfRows; char *outputBuf = taosMemoryCalloc(outputLen, 1); output = outputBuf; for (int32_t i = 0; i < pInput->numOfRows; ++i) { if (colDataIsNull_s(pInputData, i)) { colDataAppendNULL(pOutputData, i); continue; } int32_t len = varDataLen(input); int32_t startPosBytes; if (subPos > 0) { startPosBytes = (GET_PARAM_TYPE(pInput) == TSDB_DATA_TYPE_VARCHAR) ? subPos - 1 : (subPos - 1) * TSDB_NCHAR_SIZE; startPosBytes = MIN(startPosBytes, len); } else { startPosBytes = (GET_PARAM_TYPE(pInput) == TSDB_DATA_TYPE_VARCHAR) ? len + subPos : len + subPos * TSDB_NCHAR_SIZE; startPosBytes = MAX(startPosBytes, 0); } int32_t resLen = MIN(subLen, len - startPosBytes); if (resLen > 0) { memcpy(varDataVal(output), varDataVal(input) + startPosBytes, resLen); } varDataSetLen(output, resLen); colDataAppend(pOutputData, i , output, false); input += varDataTLen(input); output += varDataTLen(output); } pOutput->numOfRows = pInput->numOfRows; taosMemoryFree(outputBuf); return TSDB_CODE_SUCCESS; } int32_t castFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { if (inputNum!= 3) { return TSDB_CODE_FAILED; } int16_t inputType = pInput[0].columnData->info.type; int16_t outputType = *(int16_t *)pInput[1].columnData->pData; if (outputType != TSDB_DATA_TYPE_BIGINT && outputType != TSDB_DATA_TYPE_UBIGINT && outputType != TSDB_DATA_TYPE_VARCHAR && outputType != TSDB_DATA_TYPE_NCHAR && outputType != TSDB_DATA_TYPE_TIMESTAMP) { return TSDB_CODE_FAILED; } int64_t outputLen = *(int64_t *)pInput[2].columnData->pData; char *input = NULL; char *outputBuf = taosMemoryCalloc(outputLen * pInput[0].numOfRows, 1); char *output = outputBuf; if (IS_VAR_DATA_TYPE(inputType)) { input = pInput[0].columnData->pData + pInput[0].columnData->varmeta.offset[0]; } else { input = pInput[0].columnData->pData; } for (int32_t i = 0; i < pInput[0].numOfRows; ++i) { if (colDataIsNull_s(pInput[0].columnData, i)) { colDataAppendNULL(pOutput->columnData, i); continue; } switch(outputType) { case TSDB_DATA_TYPE_BIGINT: { if (inputType == TSDB_DATA_TYPE_BINARY) { memcpy(output, varDataVal(input), varDataLen(input)); *(int64_t *)output = strtoll(output, NULL, 10); } else if (inputType == TSDB_DATA_TYPE_NCHAR) { char *newBuf = taosMemoryCalloc(1, outputLen * TSDB_NCHAR_SIZE + 1); int32_t len = taosUcs4ToMbs((TdUcs4 *)varDataVal(input), varDataLen(input), newBuf); if (len < 0) { taosMemoryFree(newBuf); return TSDB_CODE_FAILED; } newBuf[len] = 0; *(int64_t *)output = strtoll(newBuf, NULL, 10); taosMemoryFree(newBuf); } else { GET_TYPED_DATA(*(int64_t *)output, int64_t, inputType, input); } break; } case TSDB_DATA_TYPE_UBIGINT: { if (inputType == TSDB_DATA_TYPE_BINARY) { memcpy(output, varDataVal(input), varDataLen(input)); *(uint64_t *)output = strtoull(output, NULL, 10); } else if (inputType == TSDB_DATA_TYPE_NCHAR) { char *newBuf = taosMemoryCalloc(1, outputLen * TSDB_NCHAR_SIZE + 1); int32_t len = taosUcs4ToMbs((TdUcs4 *)varDataVal(input), varDataLen(input), newBuf); if (len < 0) { taosMemoryFree(newBuf); return TSDB_CODE_FAILED; } newBuf[len] = 0; *(uint64_t *)output = strtoull(newBuf, NULL, 10); taosMemoryFree(newBuf); } else { GET_TYPED_DATA(*(uint64_t *)output, uint64_t, inputType, input); } break; } case TSDB_DATA_TYPE_TIMESTAMP: { if (inputType == TSDB_DATA_TYPE_BINARY || inputType == TSDB_DATA_TYPE_NCHAR) { //not support return TSDB_CODE_FAILED; } else { GET_TYPED_DATA(*(int64_t *)output, int64_t, inputType, input); } break; } case TSDB_DATA_TYPE_BINARY: { if (inputType == TSDB_DATA_TYPE_BOOL) { int32_t len = sprintf(varDataVal(output), "%.*s", (int32_t)(outputLen - VARSTR_HEADER_SIZE), *(int8_t *)input ? "true" : "false"); varDataSetLen(output, len); } else if (inputType == TSDB_DATA_TYPE_BINARY) { int32_t len = sprintf(varDataVal(output), "%.*s", (int32_t)(outputLen - VARSTR_HEADER_SIZE), varDataVal(input)); varDataSetLen(output, len); } else if (inputType == TSDB_DATA_TYPE_BINARY || inputType == TSDB_DATA_TYPE_NCHAR) { //not support return TSDB_CODE_FAILED; } else { char tmp[400] = {0}; NUM_TO_STRING(inputType, input, sizeof(tmp), tmp); int32_t len = (int32_t)strlen(tmp); len = (outputLen - VARSTR_HEADER_SIZE) > len ? len : (outputLen - VARSTR_HEADER_SIZE); memcpy(varDataVal(output), tmp, len); varDataSetLen(output, len); } break; } case TSDB_DATA_TYPE_NCHAR: { int32_t outputCharLen = (outputLen - VARSTR_HEADER_SIZE) / TSDB_NCHAR_SIZE; if (inputType == TSDB_DATA_TYPE_BOOL) { char tmp[8] = {0}; int32_t len = sprintf(tmp, "%.*s", outputCharLen, *(int8_t *)input ? "true" : "false" ); bool ret = taosMbsToUcs4(tmp, len, (TdUcs4 *)varDataVal(output), outputLen - VARSTR_HEADER_SIZE, &len); if (!ret) { return TSDB_CODE_FAILED; } varDataSetLen(output, len); } else if (inputType == TSDB_DATA_TYPE_BINARY) { int32_t len = outputCharLen > varDataLen(input) ? varDataLen(input) : outputCharLen; bool ret = taosMbsToUcs4(input + VARSTR_HEADER_SIZE, len, (TdUcs4 *)varDataVal(output), outputLen - VARSTR_HEADER_SIZE, &len); if (!ret) { return TSDB_CODE_FAILED; } varDataSetLen(output, len); } else if (inputType == TSDB_DATA_TYPE_NCHAR) { int32_t len = MIN(outputLen, varDataLen(input) + VARSTR_HEADER_SIZE); memcpy(output, input, len); varDataSetLen(output, len - VARSTR_HEADER_SIZE); } else { char tmp[400] = {0}; NUM_TO_STRING(inputType, input, sizeof(tmp), tmp); int32_t len = (int32_t)strlen(tmp); len = outputCharLen > len ? len : outputCharLen; bool ret = taosMbsToUcs4(tmp, len, (TdUcs4 *)varDataVal(output), outputLen - VARSTR_HEADER_SIZE, &len); if (!ret) { return TSDB_CODE_FAILED; } varDataSetLen(output, len); } break; } default: { return TSDB_CODE_FAILED; } } colDataAppend(pOutput->columnData, i, output, false); if (IS_VAR_DATA_TYPE(inputType)) { input += varDataTLen(input); } else { input += tDataTypes[inputType].bytes; } if (IS_VAR_DATA_TYPE(outputType)) { output += varDataTLen(output); } else { output += tDataTypes[outputType].bytes; } } pOutput->numOfRows = pInput->numOfRows; taosMemoryFree(outputBuf); return TSDB_CODE_SUCCESS; } int32_t toISO8601Function(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { int32_t type = GET_PARAM_TYPE(pInput); if (type != TSDB_DATA_TYPE_BIGINT && type != TSDB_DATA_TYPE_TIMESTAMP) { return TSDB_CODE_FAILED; } if (inputNum != 1) { return TSDB_CODE_FAILED; } char *input = pInput[0].columnData->pData; for (int32_t i = 0; i < pInput[0].numOfRows; ++i) { if (colDataIsNull_s(pInput[0].columnData, i)) { colDataAppendNULL(pOutput->columnData, i); continue; } char fraction[20] = {0}; bool hasFraction = false; NUM_TO_STRING(type, input, sizeof(fraction), fraction); int32_t tsDigits = (int32_t)strlen(fraction); char buf[64] = {0}; int64_t timeVal; GET_TYPED_DATA(timeVal, int64_t, type, input); if (tsDigits > TSDB_TIME_PRECISION_SEC_DIGITS) { if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal / 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / (1000 * 1000); } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / (1000 * 1000 * 1000); } else { assert(0); } hasFraction = true; memmove(fraction, fraction + TSDB_TIME_PRECISION_SEC_DIGITS, TSDB_TIME_PRECISION_SEC_DIGITS); } struct tm *tmInfo = taosLocalTime((const time_t *)&timeVal, NULL); strftime(buf, sizeof(buf), "%Y-%m-%dT%H:%M:%S%z", tmInfo); int32_t len = (int32_t)strlen(buf); if (hasFraction) { int32_t fracLen = (int32_t)strlen(fraction) + 1; char *tzInfo = strchr(buf, '+'); if (tzInfo) { memmove(tzInfo + fracLen, tzInfo, strlen(tzInfo)); } else { tzInfo = strchr(buf, '-'); memmove(tzInfo + fracLen, tzInfo, strlen(tzInfo)); } char tmp[32]; sprintf(tmp, ".%s", fraction); memcpy(tzInfo, tmp, fracLen); len += fracLen; } memmove(buf + VARSTR_HEADER_SIZE, buf, len); varDataSetLen(buf, len); colDataAppend(pOutput->columnData, i, buf, false); input += tDataTypes[type].bytes; } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } int32_t toUnixtimestampFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { int32_t type = GET_PARAM_TYPE(pInput); int32_t timePrec = GET_PARAM_PRECISON(pInput); if (type != TSDB_DATA_TYPE_BINARY && type != TSDB_DATA_TYPE_NCHAR) { return TSDB_CODE_FAILED; } if (inputNum != 1) { return TSDB_CODE_FAILED; } char *input = pInput[0].columnData->pData + pInput[0].columnData->varmeta.offset[0]; for (int32_t i = 0; i < pInput[0].numOfRows; ++i) { if (colDataIsNull_s(pInput[0].columnData, i)) { colDataAppendNULL(pOutput->columnData, i); continue; } int64_t timeVal = 0; convertStringToTimestamp(type, input, timePrec, &timeVal); colDataAppend(pOutput->columnData, i, (char *)&timeVal, false); input += varDataTLen(input); } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } int32_t timeTruncateFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { int32_t type = GET_PARAM_TYPE(&pInput[0]); int32_t timePrec = GET_PARAM_PRECISON(&pInput[0]); if (inputNum != 2) { return TSDB_CODE_FAILED; } if (type != TSDB_DATA_TYPE_BIGINT && type != TSDB_DATA_TYPE_TIMESTAMP && type != TSDB_DATA_TYPE_BINARY && type != TSDB_DATA_TYPE_NCHAR) { return TSDB_CODE_FAILED; } if (GET_PARAM_TYPE(&pInput[1]) != TSDB_DATA_TYPE_BIGINT) { //time_unit return TSDB_CODE_FAILED; } int64_t timeUnit, timeVal = 0; GET_TYPED_DATA(timeUnit, int64_t, GET_PARAM_TYPE(&pInput[1]), pInput[1].columnData->pData); int64_t factor = (timePrec == TSDB_TIME_PRECISION_MILLI) ? 1000 : (timePrec == TSDB_TIME_PRECISION_MICRO ? 1000000 : 1000000000); char *input = NULL; if (IS_VAR_DATA_TYPE(type)) { input = pInput[0].columnData->pData + pInput[0].columnData->varmeta.offset[0]; } else { input = pInput[0].columnData->pData; } for (int32_t i = 0; i < pInput[0].numOfRows; ++i) { if (colDataIsNull_s(pInput[0].columnData, i)) { colDataAppendNULL(pOutput->columnData, i); continue; } if (IS_VAR_DATA_TYPE(type)) { /* datetime format strings */ convertStringToTimestamp(type, input, TSDB_TIME_PRECISION_NANO, &timeVal); //If converted value is less than 10digits in second, use value in second instead int64_t timeValSec = timeVal / 1000000000; if (timeValSec < 1000000000) { timeVal = timeValSec; } } else if (type == TSDB_DATA_TYPE_BIGINT) { /* unix timestamp */ GET_TYPED_DATA(timeVal, int64_t, type, input); } else if (type == TSDB_DATA_TYPE_TIMESTAMP) { /* timestamp column*/ GET_TYPED_DATA(timeVal, int64_t, type, input); int64_t timeValSec = timeVal / factor; if (timeValSec < 1000000000) { timeVal = timeValSec; } } char buf[20] = {0}; NUM_TO_STRING(TSDB_DATA_TYPE_BIGINT, &timeVal, sizeof(buf), buf); int32_t tsDigits = (int32_t)strlen(buf); timeUnit = timeUnit * 1000 / factor; switch (timeUnit) { case 0: { /* 1u */ if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000 * 1000; //} else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { // //timeVal = timeVal / 1000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal = timeVal * factor; } else { timeVal = timeVal * 1; } break; } case 1: { /* 1a */ if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal * 1; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000 * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000 * 1000000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS){ timeVal = timeVal * factor; } else { assert(0); } break; } case 1000: { /* 1s */ if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal / 1000 * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000000 * 1000000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000000 * 1000000000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal = timeVal * factor; } else { assert(0); } break; } case 60000: { /* 1m */ if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal / 1000 / 60 * 60 * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000000 / 60 * 60 * 1000000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000000 / 60 * 60 * 1000000000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal = timeVal * factor / factor / 60 * 60 * factor; } else { assert(0); } break; } case 3600000: { /* 1h */ if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal / 1000 / 3600 * 3600 * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000000 / 3600 * 3600 * 1000000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000000 / 3600 * 3600 * 1000000000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal = timeVal * factor / factor / 3600 * 3600 * factor; } else { assert(0); } break; } case 86400000: { /* 1d */ if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal / 1000 / 86400 * 86400 * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000000 / 86400 * 86400 * 1000000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000000 / 86400 * 86400 * 1000000000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal = timeVal * factor / factor / 86400* 86400 * factor; } else { assert(0); } break; } case 604800000: { /* 1w */ if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal / 1000 / 604800 * 604800 * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000000 / 604800 * 604800 * 1000000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000000 / 604800 * 604800 * 1000000000; } else if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal = timeVal * factor / factor / 604800 * 604800* factor; } else { assert(0); } break; } default: { timeVal = timeVal * 1; break; } } //truncate the timestamp to db precision switch (timePrec) { case TSDB_TIME_PRECISION_MILLI: { if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal / 1000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000000; } break; } case TSDB_TIME_PRECISION_MICRO: { if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal = timeVal / 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal * 1000; } break; } case TSDB_TIME_PRECISION_NANO: { if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal = timeVal * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal = timeVal * 1000000; } break; } } colDataAppend(pOutput->columnData, i, (char *)&timeVal, false); if (IS_VAR_DATA_TYPE(type)) { input += varDataTLen(input); } else { input += tDataTypes[type].bytes; } } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } int32_t timeDiffFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { if (inputNum != 2 && inputNum != 3) { return TSDB_CODE_FAILED; } int32_t timePrec = GET_PARAM_PRECISON(&pInput[0]); int64_t timeUnit = -1, timeVal[2] = {0}; if (inputNum == 3) { if (GET_PARAM_TYPE(&pInput[2]) != TSDB_DATA_TYPE_BIGINT) { return TSDB_CODE_FAILED; } GET_TYPED_DATA(timeUnit, int64_t, GET_PARAM_TYPE(&pInput[2]), pInput[2].columnData->pData); } char *input[2]; for (int32_t k = 0; k < 2; ++k) { int32_t type = GET_PARAM_TYPE(&pInput[k]); if (type != TSDB_DATA_TYPE_BIGINT && type != TSDB_DATA_TYPE_TIMESTAMP && type != TSDB_DATA_TYPE_BINARY && type != TSDB_DATA_TYPE_NCHAR) { return TSDB_CODE_FAILED; } if (IS_VAR_DATA_TYPE(type)) { input[k] = pInput[k].columnData->pData + pInput[k].columnData->varmeta.offset[0]; } else { input[k] = pInput[k].columnData->pData; } } for (int32_t i = 0; i < pInput[0].numOfRows; ++i) { for (int32_t k = 0; k < 2; ++k) { if (colDataIsNull_s(pInput[0].columnData, i)) { colDataAppendNULL(pOutput->columnData, i); continue; } int32_t type = GET_PARAM_TYPE(&pInput[k]); if (IS_VAR_DATA_TYPE(type)) { /* datetime format strings */ convertStringToTimestamp(type, input[k], TSDB_TIME_PRECISION_NANO, &timeVal[k]); } else if (type == TSDB_DATA_TYPE_BIGINT || type == TSDB_DATA_TYPE_TIMESTAMP) { /* unix timestamp or ts column*/ GET_TYPED_DATA(timeVal[k], int64_t, type, input[k]); if (type == TSDB_DATA_TYPE_TIMESTAMP) { int64_t factor = (timePrec == TSDB_TIME_PRECISION_MILLI) ? 1000 : (timePrec == TSDB_TIME_PRECISION_MICRO ? 1000000 : 1000000000); int64_t timeValSec = timeVal[k] / factor; if (timeValSec < 1000000000) { timeVal[k] = timeValSec; } } char buf[20] = {0}; NUM_TO_STRING(TSDB_DATA_TYPE_BIGINT, &timeVal[k], sizeof(buf), buf); int32_t tsDigits = (int32_t)strlen(buf); if (tsDigits <= TSDB_TIME_PRECISION_SEC_DIGITS) { timeVal[k] = timeVal[k] * 1000000000; } else if (tsDigits == TSDB_TIME_PRECISION_MILLI_DIGITS) { timeVal[k] = timeVal[k] * 1000000; } else if (tsDigits == TSDB_TIME_PRECISION_MICRO_DIGITS) { timeVal[k] = timeVal[k] * 1000; } else if (tsDigits == TSDB_TIME_PRECISION_NANO_DIGITS) { timeVal[k] = timeVal[k]; } } if (pInput[k].numOfRows != 1) { if (IS_VAR_DATA_TYPE(type)) { input[k] += varDataTLen(input[k]); } else { input[k] += tDataTypes[type].bytes; } } } int64_t result = (timeVal[0] >= timeVal[1]) ? (timeVal[0] - timeVal[1]) : (timeVal[1] - timeVal[0]); if (timeUnit < 0) { // if no time unit given use db precision switch(timePrec) { case TSDB_TIME_PRECISION_MILLI: { result = result / 1000000; break; } case TSDB_TIME_PRECISION_MICRO: { result = result / 1000; break; } case TSDB_TIME_PRECISION_NANO: { result = result / 1; break; } } } else { int64_t factor = (timePrec == TSDB_TIME_PRECISION_MILLI) ? 1000 : (timePrec == TSDB_TIME_PRECISION_MICRO ? 1000000 : 1000000000); timeUnit = timeUnit * 1000 / factor; switch(timeUnit) { case 0: { /* 1u */ result = result / 1000; break; } case 1: { /* 1a */ result = result / 1000000; break; } case 1000: { /* 1s */ result = result / 1000000000; break; } case 60000: { /* 1m */ result = result / 1000000000 / 60; break; } case 3600000: { /* 1h */ result = result / 1000000000 / 3600; break; } case 86400000: { /* 1d */ result = result / 1000000000 / 86400; break; } case 604800000: { /* 1w */ result = result / 1000000000 / 604800; break; } default: { break; } } } colDataAppend(pOutput->columnData, i, (char *)&result, false); } pOutput->numOfRows = pInput->numOfRows; return TSDB_CODE_SUCCESS; } int32_t atanFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, atan); } int32_t sinFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, sin); } int32_t cosFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, cos); } int32_t tanFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, tan); } int32_t asinFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, asin); } int32_t acosFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, acos); } int32_t powFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique2(pInput, inputNum, pOutput, pow); } int32_t logFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique2(pInput, inputNum, pOutput, tlog); } int32_t sqrtFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunctionUnique(pInput, inputNum, pOutput, sqrt); } int32_t ceilFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunction(pInput, inputNum, pOutput, ceilf, ceil); } int32_t floorFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunction(pInput, inputNum, pOutput, floorf, floor); } int32_t roundFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doScalarFunction(pInput, inputNum, pOutput, roundf, round); } int32_t lowerFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doCaseConvFunction(pInput, inputNum, pOutput, tolower); } int32_t upperFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doCaseConvFunction(pInput, inputNum, pOutput, toupper); } int32_t ltrimFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doTrimFunction(pInput, inputNum, pOutput, tltrim); } int32_t rtrimFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doTrimFunction(pInput, inputNum, pOutput, trtrim); } int32_t lengthFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doLengthFunction(pInput, inputNum, pOutput, tlength); } int32_t charLengthFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { return doLengthFunction(pInput, inputNum, pOutput, tcharlength); } #if 0 static void reverseCopy(char* dest, const char* src, int16_t type, int32_t numOfRows) { switch(type) { case TSDB_DATA_TYPE_TINYINT: case TSDB_DATA_TYPE_UTINYINT:{ int8_t* p = (int8_t*) dest; int8_t* pSrc = (int8_t*) src; for(int32_t i = 0; i < numOfRows; ++i) { p[i] = pSrc[numOfRows - i - 1]; } return; } case TSDB_DATA_TYPE_SMALLINT: case TSDB_DATA_TYPE_USMALLINT:{ int16_t* p = (int16_t*) dest; int16_t* pSrc = (int16_t*) src; for(int32_t i = 0; i < numOfRows; ++i) { p[i] = pSrc[numOfRows - i - 1]; } return; } case TSDB_DATA_TYPE_INT: case TSDB_DATA_TYPE_UINT: { int32_t* p = (int32_t*) dest; int32_t* pSrc = (int32_t*) src; for(int32_t i = 0; i < numOfRows; ++i) { p[i] = pSrc[numOfRows - i - 1]; } return; } case TSDB_DATA_TYPE_BIGINT: case TSDB_DATA_TYPE_UBIGINT: { int64_t* p = (int64_t*) dest; int64_t* pSrc = (int64_t*) src; for(int32_t i = 0; i < numOfRows; ++i) { p[i] = pSrc[numOfRows - i - 1]; } return; } case TSDB_DATA_TYPE_FLOAT: { float* p = (float*) dest; float* pSrc = (float*) src; for(int32_t i = 0; i < numOfRows; ++i) { p[i] = pSrc[numOfRows - i - 1]; } return; } case TSDB_DATA_TYPE_DOUBLE: { double* p = (double*) dest; double* pSrc = (double*) src; for(int32_t i = 0; i < numOfRows; ++i) { p[i] = pSrc[numOfRows - i - 1]; } return; } default: assert(0); } } #endif bool getTimePseudoFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(int64_t); return true; } int32_t qStartTsFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { ASSERT(inputNum == 1); colDataAppendInt64(pOutput->columnData, pOutput->numOfRows, (int64_t *)colDataGetData(pInput->columnData, 0)); return TSDB_CODE_SUCCESS; } int32_t qEndTsFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { ASSERT(inputNum == 1); colDataAppendInt64(pOutput->columnData, pOutput->numOfRows, (int64_t *)colDataGetData(pInput->columnData, 1)); return TSDB_CODE_SUCCESS; } int32_t winDurFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { ASSERT(inputNum == 1); colDataAppendInt64(pOutput->columnData, pOutput->numOfRows, (int64_t *)colDataGetData(pInput->columnData, 2)); return TSDB_CODE_SUCCESS; } int32_t winStartTsFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { ASSERT(inputNum == 1); colDataAppendInt64(pOutput->columnData, pOutput->numOfRows, (int64_t*) colDataGetData(pInput->columnData, 3)); return TSDB_CODE_SUCCESS; } int32_t winEndTsFunction(SScalarParam *pInput, int32_t inputNum, SScalarParam *pOutput) { ASSERT(inputNum == 1); colDataAppendInt64(pOutput->columnData, pOutput->numOfRows, (int64_t*) colDataGetData(pInput->columnData, 4)); return TSDB_CODE_SUCCESS; }