/* * 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 "builtinsimpl.h" #include "cJSON.h" #include "function.h" #include "query.h" #include "querynodes.h" #include "streamState.h" #include "tcompare.h" #include "tdatablock.h" #include "tdigest.h" #include "tfunctionInt.h" #include "tglobal.h" #include "thistogram.h" #include "tpercentile.h" #define HISTOGRAM_MAX_BINS_NUM 1000 #define MAVG_MAX_POINTS_NUM 1000 #define TAIL_MAX_POINTS_NUM 100 #define TAIL_MAX_OFFSET 100 #define UNIQUE_MAX_RESULT_SIZE (1024 * 1024 * 10) #define MODE_MAX_RESULT_SIZE UNIQUE_MAX_RESULT_SIZE #define HLL_BUCKET_BITS 14 // The bits of the bucket #define HLL_DATA_BITS (64 - HLL_BUCKET_BITS) #define HLL_BUCKETS (1 << HLL_BUCKET_BITS) #define HLL_BUCKET_MASK (HLL_BUCKETS - 1) #define HLL_ALPHA_INF 0.721347520444481703680 // constant for 0.5/ln(2) typedef struct SSumRes { union { int64_t isum; uint64_t usum; double dsum; }; int16_t type; } SSumRes; typedef struct SAvgRes { double result; SSumRes sum; int64_t count; int16_t type; // store the original input type, used in merge function } SAvgRes; typedef struct SMinmaxResInfo { bool assign; // assign the first value or not int64_t v; STuplePos tuplePos; STuplePos nullTuplePos; bool nullTupleSaved; int16_t type; } SMinmaxResInfo; typedef struct STopBotResItem { SVariant v; uint64_t uid; // it is a table uid, used to extract tag data during building of the final result for the tag data STuplePos tuplePos; // tuple data of this chosen row } STopBotResItem; typedef struct STopBotRes { int32_t maxSize; int16_t type; STuplePos nullTuplePos; bool nullTupleSaved; STopBotResItem* pItems; } STopBotRes; typedef struct SStddevRes { double result; int64_t count; union { double quadraticDSum; int64_t quadraticISum; uint64_t quadraticUSum; }; union { double dsum; int64_t isum; uint64_t usum; }; int16_t type; } SStddevRes; typedef struct SLeastSQRInfo { double matrix[2][3]; double startVal; double stepVal; int64_t num; } SLeastSQRInfo; typedef struct SPercentileInfo { double result; tMemBucket* pMemBucket; int32_t stage; double minval; double maxval; int64_t numOfElems; } SPercentileInfo; typedef struct SAPercentileInfo { double result; double percent; int8_t algo; SHistogramInfo* pHisto; TDigest* pTDigest; } SAPercentileInfo; typedef enum { APERCT_ALGO_UNKNOWN = 0, APERCT_ALGO_DEFAULT, APERCT_ALGO_TDIGEST, } EAPerctAlgoType; typedef struct SDiffInfo { bool hasPrev; bool includeNull; bool ignoreNegative; // replace the ignore with case when bool firstOutput; union { int64_t i64; double d64; } prev; int64_t prevTs; } SDiffInfo; typedef struct SSpreadInfo { double result; bool hasResult; double min; double max; } SSpreadInfo; typedef struct SElapsedInfo { double result; TSKEY min; TSKEY max; int64_t timeUnit; } SElapsedInfo; typedef struct STwaInfo { double dOutput; bool isNull; SPoint1 p; STimeWindow win; } STwaInfo; typedef struct SHistoFuncBin { double lower; double upper; int64_t count; double percentage; } SHistoFuncBin; typedef struct SHistoFuncInfo { int32_t numOfBins; int32_t totalCount; bool normalized; SHistoFuncBin bins[]; } SHistoFuncInfo; typedef enum { UNKNOWN_BIN = 0, USER_INPUT_BIN, LINEAR_BIN, LOG_BIN } EHistoBinType; typedef struct SHLLFuncInfo { uint64_t result; uint64_t totalCount; uint8_t buckets[HLL_BUCKETS]; } SHLLInfo; typedef struct SStateInfo { union { int64_t count; int64_t durationStart; }; } SStateInfo; typedef enum { STATE_OPER_INVALID = 0, STATE_OPER_LT, STATE_OPER_GT, STATE_OPER_LE, STATE_OPER_GE, STATE_OPER_NE, STATE_OPER_EQ, } EStateOperType; typedef struct SMavgInfo { int32_t pos; double sum; int32_t numOfPoints; bool pointsMeet; double points[]; } SMavgInfo; typedef struct SSampleInfo { int32_t samples; int32_t totalPoints; int32_t numSampled; uint8_t colType; int16_t colBytes; STuplePos nullTuplePos; bool nullTupleSaved; char* data; STuplePos* tuplePos; } SSampleInfo; typedef struct STailItem { int64_t timestamp; bool isNull; char data[]; } STailItem; typedef struct STailInfo { int32_t numOfPoints; int32_t numAdded; int32_t offset; uint8_t colType; int16_t colBytes; STailItem** pItems; } STailInfo; typedef struct SUniqueItem { int64_t timestamp; bool isNull; char data[]; } SUniqueItem; typedef struct SUniqueInfo { int32_t numOfPoints; uint8_t colType; int16_t colBytes; bool hasNull; // null is not hashable, handle separately SHashObj* pHash; char pItems[]; } SUniqueInfo; typedef struct SModeItem { int64_t count; STuplePos tuplePos; char data[]; } SModeItem; typedef struct SModeInfo { int32_t numOfPoints; uint8_t colType; int16_t colBytes; SHashObj* pHash; STuplePos nullTuplePos; bool nullTupleSaved; char pItems[]; } SModeInfo; typedef struct SDerivInfo { double prevValue; // previous value TSKEY prevTs; // previous timestamp bool ignoreNegative; // ignore the negative value int64_t tsWindow; // time window for derivative bool valueSet; // the value has been set already } SDerivInfo; typedef struct SRateInfo { double firstValue; TSKEY firstKey; double lastValue; TSKEY lastKey; int8_t hasResult; // flag to denote has value } SRateInfo; typedef struct SGroupKeyInfo { bool hasResult; bool isNull; char data[]; } SGroupKeyInfo; #define SET_VAL(_info, numOfElem, res) \ do { \ if ((numOfElem) <= 0) { \ break; \ } \ (_info)->numOfRes = (res); \ } while (0) #define GET_TS_LIST(x) ((TSKEY*)((x)->ptsList)) #define GET_TS_DATA(x, y) (GET_TS_LIST(x)[(y)]) #define DO_UPDATE_SUBSID_RES(ctx, ts) \ do { \ for (int32_t _i = 0; _i < (ctx)->subsidiaries.num; ++_i) { \ SqlFunctionCtx* __ctx = (ctx)->subsidiaries.pCtx[_i]; \ if (__ctx->functionId == FUNCTION_TS_DUMMY) { \ __ctx->tag.i = (ts); \ __ctx->tag.nType = TSDB_DATA_TYPE_BIGINT; \ } \ __ctx->fpSet.process(__ctx); \ } \ } while (0) #define UPDATE_DATA(ctx, left, right, num, sign, _ts) \ do { \ if (((left) < (right)) ^ (sign)) { \ (left) = (right); \ DO_UPDATE_SUBSID_RES(ctx, _ts); \ (num) += 1; \ } \ } while (0) #define LOOPCHECK_N(val, _col, ctx, _t, _nrow, _start, sign, num) \ do { \ _t* d = (_t*)((_col)->pData); \ for (int32_t i = (_start); i < (_nrow) + (_start); ++i) { \ if (((_col)->hasNull) && colDataIsNull_f((_col)->nullbitmap, i)) { \ continue; \ } \ TSKEY ts = (ctx)->ptsList != NULL ? GET_TS_DATA(ctx, i) : 0; \ UPDATE_DATA(ctx, val, d[i], num, sign, ts); \ } \ } while (0) #define LIST_ADD_N(_res, _col, _start, _rows, _t, numOfElem) \ do { \ _t* d = (_t*)(_col->pData); \ for (int32_t i = (_start); i < (_rows) + (_start); ++i) { \ if (((_col)->hasNull) && colDataIsNull_f((_col)->nullbitmap, i)) { \ continue; \ }; \ (_res) += (d)[i]; \ (numOfElem)++; \ } \ } while (0) #define LIST_SUB_N(_res, _col, _start, _rows, _t, numOfElem) \ do { \ _t* d = (_t*)(_col->pData); \ for (int32_t i = (_start); i < (_rows) + (_start); ++i) { \ if (((_col)->hasNull) && colDataIsNull_f((_col)->nullbitmap, i)) { \ continue; \ }; \ (_res) -= (d)[i]; \ (numOfElem)++; \ } \ } while (0) #define LIST_AVG_N(sumT, T) \ do { \ T* plist = (T*)pCol->pData; \ for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { \ if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { \ continue; \ } \ \ numOfElem += 1; \ pAvgRes->count -= 1; \ sumT -= plist[i]; \ } \ } while (0) #define LIST_STDDEV_SUB_N(sumT, T) \ do { \ T* plist = (T*)pCol->pData; \ for (int32_t i = start; i < numOfRows + start; ++i) { \ if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { \ continue; \ } \ numOfElem += 1; \ pStddevRes->count -= 1; \ sumT -= plist[i]; \ pStddevRes->quadraticISum -= (int64_t)(plist[i] * plist[i]); \ } \ } while (0) #define LEASTSQR_CAL(p, x, y, index, step) \ do { \ (p)[0][0] += (double)(x) * (x); \ (p)[0][1] += (double)(x); \ (p)[0][2] += (double)(x) * (y)[index]; \ (p)[1][2] += (y)[index]; \ (x) += step; \ } while (0) #define STATE_COMP(_op, _lval, _param) STATE_COMP_IMPL(_op, _lval, GET_STATE_VAL(_param)) #define GET_STATE_VAL(param) ((param.nType == TSDB_DATA_TYPE_BIGINT) ? (param.i) : (param.d)) #define STATE_COMP_IMPL(_op, _lval, _rval) \ do { \ switch (_op) { \ case STATE_OPER_LT: \ return ((_lval) < (_rval)); \ break; \ case STATE_OPER_GT: \ return ((_lval) > (_rval)); \ break; \ case STATE_OPER_LE: \ return ((_lval) <= (_rval)); \ break; \ case STATE_OPER_GE: \ return ((_lval) >= (_rval)); \ break; \ case STATE_OPER_NE: \ return ((_lval) != (_rval)); \ break; \ case STATE_OPER_EQ: \ return ((_lval) == (_rval)); \ break; \ default: \ break; \ } \ } while (0) #define INIT_INTP_POINT(_p, _k, _v) \ do { \ (_p).key = (_k); \ (_p).val = (_v); \ } while (0) bool functionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (pResultInfo->initialized) { return false; } if (pCtx->pOutput != NULL) { memset(pCtx->pOutput, 0, (size_t)pCtx->resDataInfo.bytes); } initResultRowEntry(pResultInfo, pCtx->resDataInfo.interBufSize); return true; } int32_t functionFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); pResInfo->isNullRes = (pResInfo->numOfRes == 0) ? 1 : 0; char* in = GET_ROWCELL_INTERBUF(pResInfo); colDataAppend(pCol, pBlock->info.rows, in, pResInfo->isNullRes); return pResInfo->numOfRes; } int32_t firstCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SFirstLastRes* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); int32_t bytes = pDBuf->bytes; SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SFirstLastRes* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); if (pSResInfo->numOfRes != 0 && (pDResInfo->numOfRes == 0 || pDBuf->ts > pSBuf->ts)) { memcpy(pDBuf->buf, pSBuf->buf, bytes); pDBuf->ts = pSBuf->ts; pDResInfo->numOfRes = 1; } return TSDB_CODE_SUCCESS; } int32_t functionFinalizeWithResultBuf(SqlFunctionCtx* pCtx, SSDataBlock* pBlock, char* finalResult) { int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); pResInfo->isNullRes = (pResInfo->numOfRes == 0) ? 1 : 0; char* in = finalResult; colDataAppend(pCol, pBlock->info.rows, in, pResInfo->isNullRes); return pResInfo->numOfRes; } EFuncDataRequired countDataRequired(SFunctionNode* pFunc, STimeWindow* pTimeWindow) { SNode* pParam = nodesListGetNode(pFunc->pParameterList, 0); if (QUERY_NODE_COLUMN == nodeType(pParam) && PRIMARYKEY_TIMESTAMP_COL_ID == ((SColumnNode*)pParam)->colId) { return FUNC_DATA_REQUIRED_NOT_LOAD; } return FUNC_DATA_REQUIRED_SMA_LOAD; } bool getCountFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(int64_t); return true; } static int32_t getNumOfElems(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; /* * 1. column data missing (schema modified) causes pInputCol->hasNull == true. pInput->colDataAggIsSet == true; * 2. for general non-primary key columns, pInputCol->hasNull may be true or false, pInput->colDataAggIsSet == true; * 3. for primary key column, pInputCol->hasNull always be false, pInput->colDataAggIsSet == false; */ SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; if (pInput->colDataAggIsSet && pInput->totalRows == pInput->numOfRows) { numOfElem = pInput->numOfRows - pInput->pColumnDataAgg[0]->numOfNull; ASSERT(numOfElem >= 0); } else { if (pInputCol->hasNull) { for (int32_t i = pInput->startRowIndex; i < pInput->startRowIndex + pInput->numOfRows; ++i) { if (colDataIsNull(pInputCol, pInput->totalRows, i, NULL)) { continue; } numOfElem += 1; } } else { // when counting on the primary time stamp column and no statistics data is presented, use the size value // directly. numOfElem = pInput->numOfRows; } } return numOfElem; } /* * count function does need the finalize, if data is missing, the default value, which is 0, is used * count function does not use the pCtx->interResBuf to keep the intermediate buffer */ int32_t countFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = getNumOfElems(pCtx); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SInputColumnInfoData* pInput = &pCtx->input; int32_t type = pInput->pData[0]->info.type; char* buf = GET_ROWCELL_INTERBUF(pResInfo); if (IS_NULL_TYPE(type)) { // select count(NULL) returns 0 numOfElem = 1; *((int64_t*)buf) = 0; } else { *((int64_t*)buf) += numOfElem; } if (tsCountAlwaysReturnValue) { pResInfo->numOfRes = 1; } else { SET_VAL(pResInfo, *((int64_t*)buf), 1); } return TSDB_CODE_SUCCESS; } int32_t countInvertFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = getNumOfElems(pCtx); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); char* buf = GET_ROWCELL_INTERBUF(pResInfo); *((int64_t*)buf) -= numOfElem; SET_VAL(pResInfo, *((int64_t*)buf), 1); return TSDB_CODE_SUCCESS; } int32_t combineFunction(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); char* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); char* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); *((int64_t*)pDBuf) += *((int64_t*)pSBuf); SET_VAL(pDResInfo, *((int64_t*)pDBuf), 1); return TSDB_CODE_SUCCESS; } int32_t sumFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; int32_t type = pInput->pData[0]->info.type; SSumRes* pSumRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); pSumRes->type = type; if (IS_NULL_TYPE(type)) { numOfElem = 0; goto _sum_over; } if (pInput->colDataAggIsSet) { numOfElem = pInput->numOfRows - pAgg->numOfNull; ASSERT(numOfElem >= 0); if (IS_SIGNED_NUMERIC_TYPE(type)) { pSumRes->isum += pAgg->sum; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pSumRes->usum += pAgg->sum; } else if (IS_FLOAT_TYPE(type)) { pSumRes->dsum += GET_DOUBLE_VAL((const char*)&(pAgg->sum)); } } else { // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; if (IS_SIGNED_NUMERIC_TYPE(type) || type == TSDB_DATA_TYPE_BOOL) { if (type == TSDB_DATA_TYPE_TINYINT || type == TSDB_DATA_TYPE_BOOL) { LIST_ADD_N(pSumRes->isum, pCol, start, numOfRows, int8_t, numOfElem); } else if (type == TSDB_DATA_TYPE_SMALLINT) { LIST_ADD_N(pSumRes->isum, pCol, start, numOfRows, int16_t, numOfElem); } else if (type == TSDB_DATA_TYPE_INT) { LIST_ADD_N(pSumRes->isum, pCol, start, numOfRows, int32_t, numOfElem); } else if (type == TSDB_DATA_TYPE_BIGINT) { LIST_ADD_N(pSumRes->isum, pCol, start, numOfRows, int64_t, numOfElem); } } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { if (type == TSDB_DATA_TYPE_UTINYINT) { LIST_ADD_N(pSumRes->usum, pCol, start, numOfRows, uint8_t, numOfElem); } else if (type == TSDB_DATA_TYPE_USMALLINT) { LIST_ADD_N(pSumRes->usum, pCol, start, numOfRows, uint16_t, numOfElem); } else if (type == TSDB_DATA_TYPE_UINT) { LIST_ADD_N(pSumRes->usum, pCol, start, numOfRows, uint32_t, numOfElem); } else if (type == TSDB_DATA_TYPE_UBIGINT) { LIST_ADD_N(pSumRes->usum, pCol, start, numOfRows, uint64_t, numOfElem); } } else if (type == TSDB_DATA_TYPE_DOUBLE) { LIST_ADD_N(pSumRes->dsum, pCol, start, numOfRows, double, numOfElem); } else if (type == TSDB_DATA_TYPE_FLOAT) { LIST_ADD_N(pSumRes->dsum, pCol, start, numOfRows, float, numOfElem); } } // check for overflow if (IS_FLOAT_TYPE(type) && (isinf(pSumRes->dsum) || isnan(pSumRes->dsum))) { numOfElem = 0; } _sum_over: // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } int32_t sumInvertFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; int32_t type = pInput->pData[0]->info.type; SSumRes* pSumRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); if (pInput->colDataAggIsSet) { numOfElem = pInput->numOfRows - pAgg->numOfNull; ASSERT(numOfElem >= 0); if (IS_SIGNED_NUMERIC_TYPE(type)) { pSumRes->isum -= pAgg->sum; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pSumRes->usum -= pAgg->sum; } else if (IS_FLOAT_TYPE(type)) { pSumRes->dsum -= GET_DOUBLE_VAL((const char*)&(pAgg->sum)); } } else { // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; if (IS_SIGNED_NUMERIC_TYPE(type) || type == TSDB_DATA_TYPE_BOOL) { if (type == TSDB_DATA_TYPE_TINYINT || type == TSDB_DATA_TYPE_BOOL) { LIST_SUB_N(pSumRes->isum, pCol, start, numOfRows, int8_t, numOfElem); } else if (type == TSDB_DATA_TYPE_SMALLINT) { LIST_SUB_N(pSumRes->isum, pCol, start, numOfRows, int16_t, numOfElem); } else if (type == TSDB_DATA_TYPE_INT) { LIST_SUB_N(pSumRes->isum, pCol, start, numOfRows, int32_t, numOfElem); } else if (type == TSDB_DATA_TYPE_BIGINT) { LIST_SUB_N(pSumRes->isum, pCol, start, numOfRows, int64_t, numOfElem); } } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { if (type == TSDB_DATA_TYPE_UTINYINT) { LIST_SUB_N(pSumRes->usum, pCol, start, numOfRows, uint8_t, numOfElem); } else if (type == TSDB_DATA_TYPE_USMALLINT) { LIST_SUB_N(pSumRes->usum, pCol, start, numOfRows, uint16_t, numOfElem); } else if (type == TSDB_DATA_TYPE_UINT) { LIST_SUB_N(pSumRes->usum, pCol, start, numOfRows, uint32_t, numOfElem); } else if (type == TSDB_DATA_TYPE_UBIGINT) { LIST_SUB_N(pSumRes->usum, pCol, start, numOfRows, uint64_t, numOfElem); } } else if (type == TSDB_DATA_TYPE_DOUBLE) { LIST_SUB_N(pSumRes->dsum, pCol, start, numOfRows, double, numOfElem); } else if (type == TSDB_DATA_TYPE_FLOAT) { LIST_SUB_N(pSumRes->dsum, pCol, start, numOfRows, float, numOfElem); } } // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } int32_t sumCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SSumRes* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SSumRes* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); int16_t type = pDBuf->type == TSDB_DATA_TYPE_NULL ? pSBuf->type : pDBuf->type; if (IS_SIGNED_NUMERIC_TYPE(type) || type == TSDB_DATA_TYPE_BOOL) { pDBuf->isum += pSBuf->isum; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pDBuf->usum += pSBuf->usum; } else if (type == TSDB_DATA_TYPE_DOUBLE || type == TSDB_DATA_TYPE_FLOAT) { pDBuf->dsum += pSBuf->dsum; } pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } bool getSumFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SSumRes); return true; } int32_t getAvgInfoSize() { return (int32_t)sizeof(SAvgRes); } bool getAvgFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SAvgRes); return true; } bool avgFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SAvgRes* pRes = GET_ROWCELL_INTERBUF(pResultInfo); memset(pRes, 0, sizeof(SAvgRes)); return true; } int32_t avgFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; int32_t type = pInput->pData[0]->info.type; SAvgRes* pAvgRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); pAvgRes->type = type; // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; if (IS_NULL_TYPE(type)) { numOfElem = 0; goto _avg_over; } if (pInput->colDataAggIsSet) { numOfElem = numOfRows - pAgg->numOfNull; ASSERT(numOfElem >= 0); pAvgRes->count += numOfElem; if (IS_SIGNED_NUMERIC_TYPE(type)) { pAvgRes->sum.isum += pAgg->sum; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pAvgRes->sum.usum += pAgg->sum; } else if (IS_FLOAT_TYPE(type)) { pAvgRes->sum.dsum += GET_DOUBLE_VAL((const char*)&(pAgg->sum)); } } else { // computing based on the true data block switch (type) { case TSDB_DATA_TYPE_TINYINT: { int8_t* plist = (int8_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.isum += plist[i]; } break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t* plist = (int16_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.isum += plist[i]; } break; } case TSDB_DATA_TYPE_INT: { int32_t* plist = (int32_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.isum += plist[i]; } break; } case TSDB_DATA_TYPE_BIGINT: { int64_t* plist = (int64_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.isum += plist[i]; } break; } case TSDB_DATA_TYPE_UTINYINT: { uint8_t* plist = (uint8_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.usum += plist[i]; } break; } case TSDB_DATA_TYPE_USMALLINT: { uint16_t* plist = (uint16_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.usum += plist[i]; } break; } case TSDB_DATA_TYPE_UINT: { uint32_t* plist = (uint32_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.usum += plist[i]; } break; } case TSDB_DATA_TYPE_UBIGINT: { uint64_t* plist = (uint64_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.usum += plist[i]; } break; } case TSDB_DATA_TYPE_FLOAT: { float* plist = (float*)pCol->pData; // float val = 0; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.dsum += plist[i]; } // pAvgRes->sum.dsum = val; break; } case TSDB_DATA_TYPE_DOUBLE: { double* plist = (double*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pAvgRes->count += 1; pAvgRes->sum.dsum += plist[i]; } break; } default: break; } } _avg_over: // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } static void avgTransferInfo(SAvgRes* pInput, SAvgRes* pOutput) { pOutput->type = pInput->type; if (IS_SIGNED_NUMERIC_TYPE(pOutput->type)) { pOutput->sum.isum += pInput->sum.isum; } else if (IS_UNSIGNED_NUMERIC_TYPE(pOutput->type)) { pOutput->sum.usum += pInput->sum.usum; } else { pOutput->sum.dsum += pInput->sum.dsum; } pOutput->count += pInput->count; return; } int32_t avgFunctionMerge(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SAvgRes* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t start = pInput->startRowIndex; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SAvgRes* pInputInfo = (SAvgRes*)varDataVal(data); avgTransferInfo(pInputInfo, pInfo); } SET_VAL(GET_RES_INFO(pCtx), 1, 1); return TSDB_CODE_SUCCESS; } int32_t avgInvertFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; int32_t type = pInput->pData[0]->info.type; SAvgRes* pAvgRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; switch (type) { case TSDB_DATA_TYPE_TINYINT: { LIST_AVG_N(pAvgRes->sum.isum, int8_t); break; } case TSDB_DATA_TYPE_SMALLINT: { LIST_AVG_N(pAvgRes->sum.isum, int16_t); break; } case TSDB_DATA_TYPE_INT: { LIST_AVG_N(pAvgRes->sum.isum, int32_t); break; } case TSDB_DATA_TYPE_BIGINT: { LIST_AVG_N(pAvgRes->sum.isum, int64_t); break; } case TSDB_DATA_TYPE_UTINYINT: { LIST_AVG_N(pAvgRes->sum.usum, uint8_t); break; } case TSDB_DATA_TYPE_USMALLINT: { LIST_AVG_N(pAvgRes->sum.usum, uint16_t); break; } case TSDB_DATA_TYPE_UINT: { LIST_AVG_N(pAvgRes->sum.usum, uint32_t); break; } case TSDB_DATA_TYPE_UBIGINT: { LIST_AVG_N(pAvgRes->sum.usum, uint64_t); break; } case TSDB_DATA_TYPE_FLOAT: { LIST_AVG_N(pAvgRes->sum.dsum, float); break; } case TSDB_DATA_TYPE_DOUBLE: { LIST_AVG_N(pAvgRes->sum.dsum, double); break; } default: break; } // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } int32_t avgCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SAvgRes* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SAvgRes* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); int16_t type = pDBuf->type == TSDB_DATA_TYPE_NULL ? pSBuf->type : pDBuf->type; if (IS_SIGNED_NUMERIC_TYPE(type)) { pDBuf->sum.isum += pSBuf->sum.isum; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pDBuf->sum.usum += pSBuf->sum.usum; } else { pDBuf->sum.dsum += pSBuf->sum.dsum; } pDBuf->count += pSBuf->count; return TSDB_CODE_SUCCESS; } int32_t avgFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SInputColumnInfoData* pInput = &pCtx->input; SAvgRes* pAvgRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t type = pAvgRes->type; if (IS_SIGNED_NUMERIC_TYPE(type)) { pAvgRes->result = pAvgRes->sum.isum / ((double)pAvgRes->count); } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pAvgRes->result = pAvgRes->sum.usum / ((double)pAvgRes->count); } else { pAvgRes->result = pAvgRes->sum.dsum / ((double)pAvgRes->count); } // check for overflow if (isinf(pAvgRes->result) || isnan(pAvgRes->result)) { GET_RES_INFO(pCtx)->numOfRes = 0; } return functionFinalize(pCtx, pBlock); } int32_t avgPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SAvgRes* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t resultBytes = getAvgInfoSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } EFuncDataRequired statisDataRequired(SFunctionNode* pFunc, STimeWindow* pTimeWindow) { return FUNC_DATA_REQUIRED_SMA_LOAD; } bool minmaxFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; // not initialized since it has been initialized } SMinmaxResInfo* buf = GET_ROWCELL_INTERBUF(pResultInfo); buf->assign = false; buf->tuplePos.pageId = -1; buf->nullTupleSaved = false; buf->nullTuplePos.pageId = -1; return true; } bool getMinmaxFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SMinmaxResInfo); return true; } static STuplePos saveTupleData(SqlFunctionCtx* pCtx, int32_t rowIndex, const SSDataBlock* pSrcBlock, const STupleKey* pKey); static int32_t updateTupleData(SqlFunctionCtx* pCtx, int32_t rowIndex, const SSDataBlock* pSrcBlock, STuplePos* pPos); static const char* loadTupleData(SqlFunctionCtx* pCtx, const STuplePos* pPos); static int32_t findRowIndex(int32_t start, int32_t num, SColumnInfoData* pCol, const char* tval) { // the data is loaded, not only the block SMA value for (int32_t i = start; i < num + start; ++i) { char* p = colDataGetData(pCol, i); if (memcmp((void*)tval, p, pCol->info.bytes) == 0) { return i; } } // if reach here means real data of block SMA is not set in pCtx->input. return -1; } int32_t doMinMaxHelper(SqlFunctionCtx* pCtx, int32_t isMinFunc) { int32_t numOfElems = 0; SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; SColumnInfoData* pCol = pInput->pData[0]; int32_t type = pCol->info.type; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SMinmaxResInfo* pBuf = GET_ROWCELL_INTERBUF(pResInfo); pBuf->type = type; if (IS_NULL_TYPE(type)) { numOfElems = 0; goto _min_max_over; } // data in current data block are qualified to the query if (pInput->colDataAggIsSet) { numOfElems = pInput->numOfRows - pAgg->numOfNull; ASSERT(pInput->numOfRows == pInput->totalRows && numOfElems >= 0); if (numOfElems == 0) { return numOfElems; } void* tval = NULL; int16_t index = 0; if (isMinFunc) { tval = &pInput->pColumnDataAgg[0]->min; } else { tval = &pInput->pColumnDataAgg[0]->max; } if (!pBuf->assign) { pBuf->v = *(int64_t*)tval; if (pCtx->subsidiaries.num > 0) { index = findRowIndex(pInput->startRowIndex, pInput->numOfRows, pCol, tval); if (index >= 0) { pBuf->tuplePos = saveTupleData(pCtx, index, pCtx->pSrcBlock, NULL); } } } else { if (IS_SIGNED_NUMERIC_TYPE(type)) { int64_t prev = 0; GET_TYPED_DATA(prev, int64_t, type, &pBuf->v); int64_t val = GET_INT64_VAL(tval); if ((prev < val) ^ isMinFunc) { *(int64_t*)&pBuf->v = val; if (pCtx->subsidiaries.num > 0) { index = findRowIndex(pInput->startRowIndex, pInput->numOfRows, pCol, tval); if (index >= 0) { pBuf->tuplePos = saveTupleData(pCtx, index, pCtx->pSrcBlock, NULL); } } } } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { uint64_t prev = 0; GET_TYPED_DATA(prev, uint64_t, type, &pBuf->v); uint64_t val = GET_UINT64_VAL(tval); if ((prev < val) ^ isMinFunc) { *(uint64_t*)&pBuf->v = val; if (pCtx->subsidiaries.num > 0) { index = findRowIndex(pInput->startRowIndex, pInput->numOfRows, pCol, tval); if (index >= 0) { pBuf->tuplePos = saveTupleData(pCtx, index, pCtx->pSrcBlock, NULL); } } } } else if (type == TSDB_DATA_TYPE_DOUBLE) { double prev = 0; GET_TYPED_DATA(prev, double, type, &pBuf->v); double val = GET_DOUBLE_VAL(tval); if ((prev < val) ^ isMinFunc) { *(double*)&pBuf->v = val; if (pCtx->subsidiaries.num > 0) { index = findRowIndex(pInput->startRowIndex, pInput->numOfRows, pCol, tval); if (index >= 0) { pBuf->tuplePos = saveTupleData(pCtx, index, pCtx->pSrcBlock, NULL); } } } } else if (type == TSDB_DATA_TYPE_FLOAT) { float prev = 0; GET_TYPED_DATA(prev, float, type, &pBuf->v); float val = GET_DOUBLE_VAL(tval); if ((prev < val) ^ isMinFunc) { *(float*)&pBuf->v = val; } if (pCtx->subsidiaries.num > 0) { index = findRowIndex(pInput->startRowIndex, pInput->numOfRows, pCol, tval); if (index >= 0) { pBuf->tuplePos = saveTupleData(pCtx, index, pCtx->pSrcBlock, NULL); } } } } pBuf->assign = true; return numOfElems; } int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; if (IS_SIGNED_NUMERIC_TYPE(type) || type == TSDB_DATA_TYPE_BOOL) { if (type == TSDB_DATA_TYPE_TINYINT || type == TSDB_DATA_TYPE_BOOL) { int8_t* pData = (int8_t*)pCol->pData; int8_t* val = (int8_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_SMALLINT) { int16_t* pData = (int16_t*)pCol->pData; int16_t* val = (int16_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_INT) { int32_t* pData = (int32_t*)pCol->pData; int32_t* val = (int32_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_BIGINT) { int64_t* pData = (int64_t*)pCol->pData; int64_t* val = (int64_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { if (type == TSDB_DATA_TYPE_UTINYINT) { uint8_t* pData = (uint8_t*)pCol->pData; uint8_t* val = (uint8_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_USMALLINT) { uint16_t* pData = (uint16_t*)pCol->pData; uint16_t* val = (uint16_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_UINT) { uint32_t* pData = (uint32_t*)pCol->pData; uint32_t* val = (uint32_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_UBIGINT) { uint64_t* pData = (uint64_t*)pCol->pData; uint64_t* val = (uint64_t*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } } else if (type == TSDB_DATA_TYPE_DOUBLE) { double* pData = (double*)pCol->pData; double* val = (double*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { // ignore the equivalent data value // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } else if (type == TSDB_DATA_TYPE_FLOAT) { float* pData = (float*)pCol->pData; float* val = (float*)&pBuf->v; for (int32_t i = start; i < start + numOfRows; ++i) { if ((pCol->hasNull) && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } if (!pBuf->assign) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { pBuf->tuplePos = saveTupleData(pCtx, i, pCtx->pSrcBlock, NULL); } pBuf->assign = true; } else { #if 0 if ((*val) == pData[i]) { continue; } if ((*val < pData[i]) ^ isMinFunc) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } #endif // NOTE: An faster version to avoid one additional comparison with FPU. if (isMinFunc) { // min if (*val > pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } else { // max if (*val < pData[i]) { *val = pData[i]; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, i, pCtx->pSrcBlock, &pBuf->tuplePos); } } } } numOfElems += 1; } } _min_max_over: if (numOfElems == 0 && pCtx->subsidiaries.num > 0 && !pBuf->nullTupleSaved) { pBuf->nullTuplePos = saveTupleData(pCtx, pInput->startRowIndex, pCtx->pSrcBlock, NULL); pBuf->nullTupleSaved = true; } return numOfElems; } int32_t minFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = doMinMaxHelper(pCtx, 1); SET_VAL(GET_RES_INFO(pCtx), numOfElems, 1); return TSDB_CODE_SUCCESS; } int32_t maxFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = doMinMaxHelper(pCtx, 0); SET_VAL(GET_RES_INFO(pCtx), numOfElems, 1); return TSDB_CODE_SUCCESS; } static void setNullSelectivityValue(SqlFunctionCtx* pCtx, SSDataBlock* pBlock, int32_t rowIndex); static void setSelectivityValue(SqlFunctionCtx* pCtx, SSDataBlock* pBlock, const STuplePos* pTuplePos, int32_t rowIndex); int32_t minmaxFunctionFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(pCtx); SMinmaxResInfo* pRes = GET_ROWCELL_INTERBUF(pEntryInfo); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; int32_t currentRow = pBlock->info.rows; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); pEntryInfo->isNullRes = (pEntryInfo->numOfRes == 0) ? 1 : 0; if (pCol->info.type == TSDB_DATA_TYPE_FLOAT) { float v = *(float*)&pRes->v; colDataAppend(pCol, currentRow, (const char*)&v, pEntryInfo->isNullRes); } else { colDataAppend(pCol, currentRow, (const char*)&pRes->v, pEntryInfo->isNullRes); } if (pEntryInfo->numOfRes > 0) { setSelectivityValue(pCtx, pBlock, &pRes->tuplePos, currentRow); } else { setSelectivityValue(pCtx, pBlock, &pRes->nullTuplePos, currentRow); } return pEntryInfo->numOfRes; } void setNullSelectivityValue(SqlFunctionCtx* pCtx, SSDataBlock* pBlock, int32_t rowIndex) { if (pCtx->subsidiaries.num <= 0) { return; } for (int32_t j = 0; j < pCtx->subsidiaries.num; ++j) { SqlFunctionCtx* pc = pCtx->subsidiaries.pCtx[j]; int32_t dstSlotId = pc->pExpr->base.resSchema.slotId; SColumnInfoData* pDstCol = taosArrayGet(pBlock->pDataBlock, dstSlotId); colDataAppendNULL(pDstCol, rowIndex); } } void setSelectivityValue(SqlFunctionCtx* pCtx, SSDataBlock* pBlock, const STuplePos* pTuplePos, int32_t rowIndex) { if (pCtx->subsidiaries.num <= 0) { return; } if (pCtx->saveHandle.pBuf != NULL) { if (pTuplePos->pageId != -1) { int32_t numOfCols = pCtx->subsidiaries.num; const char* p = loadTupleData(pCtx, pTuplePos); bool* nullList = (bool*)p; char* pStart = (char*)(nullList + numOfCols * sizeof(bool)); // todo set the offset value to optimize the performance. for (int32_t j = 0; j < numOfCols; ++j) { SqlFunctionCtx* pc = pCtx->subsidiaries.pCtx[j]; int32_t dstSlotId = pc->pExpr->base.resSchema.slotId; SColumnInfoData* pDstCol = taosArrayGet(pBlock->pDataBlock, dstSlotId); ASSERT(pc->pExpr->base.resSchema.bytes == pDstCol->info.bytes); if (nullList[j]) { colDataAppendNULL(pDstCol, rowIndex); } else { colDataAppend(pDstCol, rowIndex, pStart, false); } pStart += pDstCol->info.bytes; } } } } void releaseSource(STuplePos* pPos) { if (pPos->pageId == -1) { return; } // Todo(liuyao) relase row } // This function append the selectivity to subsidiaries function context directly, without fetching data // from intermediate disk based buf page void appendSelectivityValue(SqlFunctionCtx* pCtx, int32_t rowIndex, int32_t pos) { if (pCtx->subsidiaries.num <= 0) { return; } for (int32_t j = 0; j < pCtx->subsidiaries.num; ++j) { SqlFunctionCtx* pc = pCtx->subsidiaries.pCtx[j]; // get data from source col SFunctParam* pFuncParam = &pc->pExpr->base.pParam[0]; int32_t srcSlotId = pFuncParam->pCol->slotId; SColumnInfoData* pSrcCol = taosArrayGet(pCtx->pSrcBlock->pDataBlock, srcSlotId); char* pData = colDataGetData(pSrcCol, rowIndex); // append to dest col int32_t dstSlotId = pc->pExpr->base.resSchema.slotId; SColumnInfoData* pDstCol = taosArrayGet(pCtx->pDstBlock->pDataBlock, dstSlotId); ASSERT(pc->pExpr->base.resSchema.bytes == pDstCol->info.bytes); if (colDataIsNull_s(pSrcCol, rowIndex) == true) { colDataAppendNULL(pDstCol, pos); } else { colDataAppend(pDstCol, pos, pData, false); } } } void replaceTupleData(STuplePos* pDestPos, STuplePos* pSourcePos) { releaseSource(pDestPos); *pDestPos = *pSourcePos; } int32_t minMaxCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx, int32_t isMinFunc) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SMinmaxResInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SMinmaxResInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); int16_t type = pDBuf->type == TSDB_DATA_TYPE_NULL ? pSBuf->type : pDBuf->type; if (IS_FLOAT_TYPE(type)) { if (pSBuf->assign && ((((*(double*)&pDBuf->v) < (*(double*)&pSBuf->v)) ^ isMinFunc) || !pDBuf->assign)) { *(double*)&pDBuf->v = *(double*)&pSBuf->v; replaceTupleData(&pDBuf->tuplePos, &pSBuf->tuplePos); pDBuf->assign = true; } } else { if (pSBuf->assign && (((pDBuf->v < pSBuf->v) ^ isMinFunc) || !pDBuf->assign)) { pDBuf->v = pSBuf->v; replaceTupleData(&pDBuf->tuplePos, &pSBuf->tuplePos); pDBuf->assign = true; } } pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } int32_t minCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { return minMaxCombine(pDestCtx, pSourceCtx, 1); } int32_t maxCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { return minMaxCombine(pDestCtx, pSourceCtx, 0); } int32_t getStddevInfoSize() { return (int32_t)sizeof(SStddevRes); } bool getStddevFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SStddevRes); return true; } bool stddevFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SStddevRes* pRes = GET_ROWCELL_INTERBUF(pResultInfo); memset(pRes, 0, sizeof(SStddevRes)); return true; } int32_t stddevFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; int32_t type = pInput->pData[0]->info.type; SStddevRes* pStddevRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); pStddevRes->type = type; // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; if (IS_NULL_TYPE(type)) { numOfElem = 0; goto _stddev_over; } switch (type) { case TSDB_DATA_TYPE_TINYINT: { int8_t* plist = (int8_t*)pCol->pData; for (int32_t i = start; i < numOfRows + start; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->isum += plist[i]; pStddevRes->quadraticISum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t* plist = (int16_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->isum += plist[i]; pStddevRes->quadraticISum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_INT: { int32_t* plist = (int32_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->isum += plist[i]; pStddevRes->quadraticISum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_BIGINT: { int64_t* plist = (int64_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->isum += plist[i]; pStddevRes->quadraticISum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_UTINYINT: { uint8_t* plist = (uint8_t*)pCol->pData; for (int32_t i = start; i < numOfRows + start; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->usum += plist[i]; pStddevRes->quadraticUSum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_USMALLINT: { uint16_t* plist = (uint16_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->usum += plist[i]; pStddevRes->quadraticUSum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_UINT: { uint32_t* plist = (uint32_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->usum += plist[i]; pStddevRes->quadraticUSum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_UBIGINT: { uint64_t* plist = (uint64_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->usum += plist[i]; pStddevRes->quadraticUSum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_FLOAT: { float* plist = (float*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->dsum += plist[i]; pStddevRes->quadraticDSum += plist[i] * plist[i]; } break; } case TSDB_DATA_TYPE_DOUBLE: { double* plist = (double*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem += 1; pStddevRes->count += 1; pStddevRes->dsum += plist[i]; pStddevRes->quadraticDSum += plist[i] * plist[i]; } break; } default: break; } _stddev_over: // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } static void stddevTransferInfo(SStddevRes* pInput, SStddevRes* pOutput) { pOutput->type = pInput->type; if (IS_SIGNED_NUMERIC_TYPE(pOutput->type)) { pOutput->quadraticISum += pInput->quadraticISum; pOutput->isum += pInput->isum; } else if (IS_UNSIGNED_NUMERIC_TYPE(pOutput->type)) { pOutput->quadraticUSum += pInput->quadraticUSum; pOutput->usum += pInput->usum; } else { pOutput->quadraticDSum += pInput->quadraticDSum; pOutput->dsum += pInput->dsum; } pOutput->count += pInput->count; } int32_t stddevFunctionMerge(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SStddevRes* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); for (int32_t i = pInput->startRowIndex; i < pInput->startRowIndex + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SStddevRes* pInputInfo = (SStddevRes*)varDataVal(data); stddevTransferInfo(pInputInfo, pInfo); } SET_VAL(GET_RES_INFO(pCtx), 1, 1); return TSDB_CODE_SUCCESS; } int32_t stddevInvertFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; int32_t type = pInput->pData[0]->info.type; SStddevRes* pStddevRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; switch (type) { case TSDB_DATA_TYPE_TINYINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, int8_t); break; } case TSDB_DATA_TYPE_SMALLINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, int16_t); break; } case TSDB_DATA_TYPE_INT: { LIST_STDDEV_SUB_N(pStddevRes->isum, int32_t); break; } case TSDB_DATA_TYPE_BIGINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, int64_t); break; } case TSDB_DATA_TYPE_UTINYINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, uint8_t); break; } case TSDB_DATA_TYPE_USMALLINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, uint16_t); break; } case TSDB_DATA_TYPE_UINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, uint32_t); break; } case TSDB_DATA_TYPE_UBIGINT: { LIST_STDDEV_SUB_N(pStddevRes->isum, uint64_t); break; } case TSDB_DATA_TYPE_FLOAT: { LIST_STDDEV_SUB_N(pStddevRes->dsum, float); break; } case TSDB_DATA_TYPE_DOUBLE: { LIST_STDDEV_SUB_N(pStddevRes->dsum, double); break; } default: break; } // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } int32_t stddevFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SInputColumnInfoData* pInput = &pCtx->input; SStddevRes* pStddevRes = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t type = pStddevRes->type; double avg; if (IS_SIGNED_NUMERIC_TYPE(type)) { avg = pStddevRes->isum / ((double)pStddevRes->count); pStddevRes->result = sqrt(fabs(pStddevRes->quadraticISum / ((double)pStddevRes->count) - avg * avg)); } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { avg = pStddevRes->usum / ((double)pStddevRes->count); pStddevRes->result = sqrt(fabs(pStddevRes->quadraticUSum / ((double)pStddevRes->count) - avg * avg)); } else { avg = pStddevRes->dsum / ((double)pStddevRes->count); pStddevRes->result = sqrt(fabs(pStddevRes->quadraticDSum / ((double)pStddevRes->count) - avg * avg)); } // check for overflow if (isinf(pStddevRes->result) || isnan(pStddevRes->result)) { GET_RES_INFO(pCtx)->numOfRes = 0; } return functionFinalize(pCtx, pBlock); } int32_t stddevPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SStddevRes* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t resultBytes = getStddevInfoSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } int32_t stddevCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SStddevRes* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SStddevRes* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); int16_t type = pDBuf->type == TSDB_DATA_TYPE_NULL ? pSBuf->type : pDBuf->type; if (IS_SIGNED_NUMERIC_TYPE(type)) { pDBuf->isum += pSBuf->isum; pDBuf->quadraticISum += pSBuf->quadraticISum; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { pDBuf->usum += pSBuf->usum; pDBuf->quadraticUSum += pSBuf->quadraticUSum; } else { pDBuf->dsum += pSBuf->dsum; pDBuf->quadraticDSum += pSBuf->quadraticDSum; } pDBuf->count += pSBuf->count; pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } bool getLeastSQRFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SLeastSQRInfo); return true; } bool leastSQRFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SLeastSQRInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); pInfo->startVal = IS_FLOAT_TYPE(pCtx->param[1].param.nType) ? pCtx->param[1].param.d : (double)pCtx->param[1].param.i; pInfo->stepVal = IS_FLOAT_TYPE(pCtx->param[2].param.nType) ? pCtx->param[2].param.d : (double)pCtx->param[2].param.i; return true; } int32_t leastSQRFunction(SqlFunctionCtx* pCtx) { int32_t numOfElem = 0; SInputColumnInfoData* pInput = &pCtx->input; int32_t type = pInput->pData[0]->info.type; SLeastSQRInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); SColumnInfoData* pCol = pInput->pData[0]; double(*param)[3] = pInfo->matrix; double x = pInfo->startVal; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; switch (type) { case TSDB_DATA_TYPE_TINYINT: { int8_t* plist = (int8_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t* plist = (int16_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_INT: { int32_t* plist = (int32_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_BIGINT: { int64_t* plist = (int64_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_UTINYINT: { uint8_t* plist = (uint8_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_USMALLINT: { uint16_t* plist = (uint16_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_UINT: { uint32_t* plist = (uint32_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_UBIGINT: { uint64_t* plist = (uint64_t*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_FLOAT: { float* plist = (float*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_DOUBLE: { double* plist = (double*)pCol->pData; for (int32_t i = start; i < numOfRows + pInput->startRowIndex; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElem++; LEASTSQR_CAL(param, x, plist, i, pInfo->stepVal); } break; } case TSDB_DATA_TYPE_NULL: { GET_RES_INFO(pCtx)->isNullRes = 1; numOfElem = 1; break; } default: break; } pInfo->startVal = x; pInfo->num += numOfElem; SET_VAL(GET_RES_INFO(pCtx), numOfElem, 1); return TSDB_CODE_SUCCESS; } int32_t leastSQRFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SLeastSQRInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); int32_t currentRow = pBlock->info.rows; if (0 == pInfo->num) { colDataAppendNULL(pCol, currentRow); return 0; } double(*param)[3] = pInfo->matrix; param[1][1] = (double)pInfo->num; param[1][0] = param[0][1]; double param00 = param[0][0] - param[1][0] * (param[0][1] / param[1][1]); double param02 = param[0][2] - param[1][2] * (param[0][1] / param[1][1]); if (0 == param00) { colDataAppendNULL(pCol, currentRow); return 0; } // param[0][1] = 0; double param12 = param[1][2] - param02 * (param[1][0] / param00); // param[1][0] = 0; param02 /= param00; param12 /= param[1][1]; char buf[64] = {0}; size_t len = snprintf(varDataVal(buf), sizeof(buf) - VARSTR_HEADER_SIZE, "{slop:%.6lf, intercept:%.6lf}", param02, param12); varDataSetLen(buf, len); colDataAppend(pCol, currentRow, buf, pResInfo->isNullRes); return pResInfo->numOfRes; } int32_t leastSQRInvertFunction(SqlFunctionCtx* pCtx) { // TODO return TSDB_CODE_SUCCESS; } int32_t leastSQRCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SLeastSQRInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); int32_t type = pDestCtx->input.pData[0]->info.type; double(*pDparam)[3] = pDBuf->matrix; SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SLeastSQRInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); double(*pSparam)[3] = pSBuf->matrix; for (int32_t i = 0; i < pSBuf->num; i++) { pDparam[0][0] += pDBuf->startVal * pDBuf->startVal; pDparam[0][1] += pDBuf->startVal; pDBuf->startVal += pDBuf->stepVal; } pDparam[0][2] += pSparam[0][2] + pDBuf->num * pDBuf->stepVal * pSparam[1][2]; pDparam[1][2] += pSparam[1][2]; pDBuf->num += pSBuf->num; pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } bool getPercentileFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SPercentileInfo); return true; } bool percentileFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } // in the first round, get the min-max value of all involved data SPercentileInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); SET_DOUBLE_VAL(&pInfo->minval, DBL_MAX); SET_DOUBLE_VAL(&pInfo->maxval, -DBL_MAX); pInfo->numOfElems = 0; return true; } int32_t percentileFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; SColumnInfoData* pCol = pInput->pData[0]; int32_t type = pCol->info.type; SPercentileInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); if (pCtx->scanFlag == REPEAT_SCAN && pInfo->stage == 0) { pInfo->stage += 1; // all data are null, set it completed if (pInfo->numOfElems == 0) { pResInfo->complete = true; return 0; } else { pInfo->pMemBucket = tMemBucketCreate(pCol->info.bytes, type, pInfo->minval, pInfo->maxval); } } // the first stage, only acquire the min/max value if (pInfo->stage == 0) { if (pCtx->input.colDataAggIsSet) { double tmin = 0.0, tmax = 0.0; if (IS_SIGNED_NUMERIC_TYPE(type)) { tmin = (double)GET_INT64_VAL(&pAgg->min); tmax = (double)GET_INT64_VAL(&pAgg->max); } else if (IS_FLOAT_TYPE(type)) { tmin = GET_DOUBLE_VAL(&pAgg->min); tmax = GET_DOUBLE_VAL(&pAgg->max); } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { tmin = (double)GET_UINT64_VAL(&pAgg->min); tmax = (double)GET_UINT64_VAL(&pAgg->max); } if (GET_DOUBLE_VAL(&pInfo->minval) > tmin) { SET_DOUBLE_VAL(&pInfo->minval, tmin); } if (GET_DOUBLE_VAL(&pInfo->maxval) < tmax) { SET_DOUBLE_VAL(&pInfo->maxval, tmax); } pInfo->numOfElems += (pInput->numOfRows - pAgg->numOfNull); } else { // check the valid data one by one int32_t start = pInput->startRowIndex; for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (colDataIsNull_f(pCol->nullbitmap, i)) { continue; } char* data = colDataGetData(pCol, i); double v = 0; GET_TYPED_DATA(v, double, type, data); if (v < GET_DOUBLE_VAL(&pInfo->minval)) { SET_DOUBLE_VAL(&pInfo->minval, v); } if (v > GET_DOUBLE_VAL(&pInfo->maxval)) { SET_DOUBLE_VAL(&pInfo->maxval, v); } pInfo->numOfElems += 1; } } } else { // the second stage, calculate the true percentile value int32_t start = pInput->startRowIndex; for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (colDataIsNull_f(pCol->nullbitmap, i)) { continue; } char* data = colDataGetData(pCol, i); numOfElems += 1; tMemBucketPut(pInfo->pMemBucket, data, 1); } SET_VAL(pResInfo, numOfElems, 1); } return TSDB_CODE_SUCCESS; } int32_t percentileFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SVariant* pVal = &pCtx->param[1].param; double v = (IS_SIGNED_NUMERIC_TYPE(pVal->nType) ? pVal->i : (IS_UNSIGNED_NUMERIC_TYPE(pVal->nType) ? pVal->u : pVal->d)); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SPercentileInfo* ppInfo = (SPercentileInfo*)GET_ROWCELL_INTERBUF(pResInfo); tMemBucket* pMemBucket = ppInfo->pMemBucket; if (pMemBucket != NULL && pMemBucket->total > 0) { // check for null SET_DOUBLE_VAL(&ppInfo->result, getPercentile(pMemBucket, v)); } tMemBucketDestroy(pMemBucket); return functionFinalize(pCtx, pBlock); } bool getApercentileFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { int32_t bytesHist = (int32_t)(sizeof(SAPercentileInfo) + sizeof(SHistogramInfo) + sizeof(SHistBin) * (MAX_HISTOGRAM_BIN + 1)); int32_t bytesDigest = (int32_t)(sizeof(SAPercentileInfo) + TDIGEST_SIZE(COMPRESSION)); pEnv->calcMemSize = TMAX(bytesHist, bytesDigest); return true; } int32_t getApercentileMaxSize() { int32_t bytesHist = (int32_t)(sizeof(SAPercentileInfo) + sizeof(SHistogramInfo) + sizeof(SHistBin) * (MAX_HISTOGRAM_BIN + 1)); int32_t bytesDigest = (int32_t)(sizeof(SAPercentileInfo) + TDIGEST_SIZE(COMPRESSION)); return TMAX(bytesHist, bytesDigest); } static int8_t getApercentileAlgo(char* algoStr) { int8_t algoType; if (strcasecmp(algoStr, "default") == 0) { algoType = APERCT_ALGO_DEFAULT; } else if (strcasecmp(algoStr, "t-digest") == 0) { algoType = APERCT_ALGO_TDIGEST; } else { algoType = APERCT_ALGO_UNKNOWN; } return algoType; } static void buildHistogramInfo(SAPercentileInfo* pInfo) { pInfo->pHisto = (SHistogramInfo*)((char*)pInfo + sizeof(SAPercentileInfo)); pInfo->pHisto->elems = (SHistBin*)((char*)pInfo->pHisto + sizeof(SHistogramInfo)); } static void buildTDigestInfo(SAPercentileInfo* pInfo) { pInfo->pTDigest = (TDigest*)((char*)pInfo + sizeof(SAPercentileInfo)); } bool apercentileFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SAPercentileInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); SVariant* pVal = &pCtx->param[1].param; pInfo->percent = (IS_SIGNED_NUMERIC_TYPE(pVal->nType) ? pVal->i : (IS_UNSIGNED_NUMERIC_TYPE(pVal->nType) ? pVal->u : pVal->d)); if (pCtx->numOfParams == 2) { pInfo->algo = APERCT_ALGO_DEFAULT; } else if (pCtx->numOfParams == 3) { pInfo->algo = getApercentileAlgo(varDataVal(pCtx->param[2].param.pz)); if (pInfo->algo == APERCT_ALGO_UNKNOWN) { return false; } } char* tmp = (char*)pInfo + sizeof(SAPercentileInfo); if (pInfo->algo == APERCT_ALGO_TDIGEST) { pInfo->pTDigest = tdigestNewFrom(tmp, COMPRESSION); } else { buildHistogramInfo(pInfo); pInfo->pHisto = tHistogramCreateFrom(tmp, MAX_HISTOGRAM_BIN); qDebug("%s set up histogram, numOfElems:%" PRId64 ", numOfEntry:%d, pHisto:%p, elems:%p", __FUNCTION__, pInfo->pHisto->numOfElems, pInfo->pHisto->numOfEntries, pInfo->pHisto, pInfo->pHisto->elems); } return true; } int32_t apercentileFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; int32_t type = pCol->info.type; SAPercentileInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); int32_t start = pInput->startRowIndex; if (pInfo->algo == APERCT_ALGO_TDIGEST) { buildTDigestInfo(pInfo); tdigestAutoFill(pInfo->pTDigest, COMPRESSION); for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElems += 1; char* data = colDataGetData(pCol, i); double v = 0; // value int64_t w = 1; // weigth GET_TYPED_DATA(v, double, type, data); tdigestAdd(pInfo->pTDigest, v, w); } } else { // might be a race condition here that pHisto can be overwritten or setup function // has not been called, need to relink the buffer pHisto points to. buildHistogramInfo(pInfo); qDebug("%s before add %d elements into histogram, total:%" PRId64 ", numOfEntry:%d, pHisto:%p, elems: %p", __FUNCTION__, numOfElems, pInfo->pHisto->numOfElems, pInfo->pHisto->numOfEntries, pInfo->pHisto, pInfo->pHisto->elems); for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElems += 1; char* data = colDataGetData(pCol, i); double v = 0; GET_TYPED_DATA(v, double, type, data); tHistogramAdd(&pInfo->pHisto, v); } qDebug("%s after add %d elements into histogram, total:%" PRId64 ", numOfEntry:%d, pHisto:%p, elems: %p", __FUNCTION__, numOfElems, pInfo->pHisto->numOfElems, pInfo->pHisto->numOfEntries, pInfo->pHisto, pInfo->pHisto->elems); } SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; } static void apercentileTransferInfo(SAPercentileInfo* pInput, SAPercentileInfo* pOutput) { pOutput->percent = pInput->percent; pOutput->algo = pInput->algo; if (pOutput->algo == APERCT_ALGO_TDIGEST) { buildTDigestInfo(pInput); tdigestAutoFill(pInput->pTDigest, COMPRESSION); if (pInput->pTDigest->num_centroids == 0 && pInput->pTDigest->num_buffered_pts == 0) { return; } buildTDigestInfo(pOutput); TDigest* pTDigest = pOutput->pTDigest; tdigestAutoFill(pTDigest, COMPRESSION); if (pTDigest->num_centroids <= 0 && pTDigest->num_buffered_pts == 0) { memcpy(pTDigest, pInput->pTDigest, (size_t)TDIGEST_SIZE(COMPRESSION)); tdigestAutoFill(pTDigest, COMPRESSION); } else { tdigestMerge(pTDigest, pInput->pTDigest); } } else { buildHistogramInfo(pInput); if (pInput->pHisto->numOfElems <= 0) { return; } buildHistogramInfo(pOutput); SHistogramInfo* pHisto = pOutput->pHisto; if (pHisto->numOfElems <= 0) { memcpy(pHisto, pInput->pHisto, sizeof(SHistogramInfo) + sizeof(SHistBin) * (MAX_HISTOGRAM_BIN + 1)); pHisto->elems = (SHistBin*)((char*)pHisto + sizeof(SHistogramInfo)); qDebug("%s merge histo, total:%" PRId64 ", entry:%d, %p", __FUNCTION__, pHisto->numOfElems, pHisto->numOfEntries, pHisto); } else { pHisto->elems = (SHistBin*)((char*)pHisto + sizeof(SHistogramInfo)); qDebug("%s input histogram, elem:%" PRId64 ", entry:%d, %p", __FUNCTION__, pHisto->numOfElems, pHisto->numOfEntries, pInput->pHisto); SHistogramInfo* pRes = tHistogramMerge(pHisto, pInput->pHisto, MAX_HISTOGRAM_BIN); memcpy(pHisto, pRes, sizeof(SHistogramInfo) + sizeof(SHistBin) * MAX_HISTOGRAM_BIN); pHisto->elems = (SHistBin*)((char*)pHisto + sizeof(SHistogramInfo)); qDebug("%s merge histo, total:%" PRId64 ", entry:%d, %p", __FUNCTION__, pHisto->numOfElems, pHisto->numOfEntries, pHisto); tHistogramDestroy(&pRes); } } } int32_t apercentileFunctionMerge(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SAPercentileInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); qDebug("%s total %d rows will merge, %p", __FUNCTION__, pInput->numOfRows, pInfo->pHisto); int32_t start = pInput->startRowIndex; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SAPercentileInfo* pInputInfo = (SAPercentileInfo*)varDataVal(data); apercentileTransferInfo(pInputInfo, pInfo); } if (pInfo->algo != APERCT_ALGO_TDIGEST) { qDebug("%s after merge, total:%" PRId64 ", numOfEntry:%d, %p", __FUNCTION__, pInfo->pHisto->numOfElems, pInfo->pHisto->numOfEntries, pInfo->pHisto); } SET_VAL(pResInfo, 1, 1); return TSDB_CODE_SUCCESS; } int32_t apercentileFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SAPercentileInfo* pInfo = (SAPercentileInfo*)GET_ROWCELL_INTERBUF(pResInfo); if (pInfo->algo == APERCT_ALGO_TDIGEST) { buildTDigestInfo(pInfo); tdigestAutoFill(pInfo->pTDigest, COMPRESSION); if (pInfo->pTDigest->size > 0) { pInfo->result = tdigestQuantile(pInfo->pTDigest, pInfo->percent / 100); } else { // no need to free // setNull(pCtx->pOutput, pCtx->outputType, pCtx->outputBytes); return TSDB_CODE_SUCCESS; } } else { buildHistogramInfo(pInfo); if (pInfo->pHisto->numOfElems > 0) { qDebug("%s get the final res, elements:%" PRId64 ", numOfEntry:%d, pHisto:%p, elems:%p", __FUNCTION__, pInfo->pHisto->numOfElems, pInfo->pHisto->numOfEntries, pInfo->pHisto, pInfo->pHisto->elems); double ratio[] = {pInfo->percent}; double* res = tHistogramUniform(pInfo->pHisto, ratio, 1); pInfo->result = *res; // memcpy(pCtx->pOutput, res, sizeof(double)); taosMemoryFree(res); } else { // no need to free // setNull(pCtx->pOutput, pCtx->outputType, pCtx->outputBytes); // return TSDB_CODE_SUCCESS; qDebug("%s get the final res, elements:%" PRId64 ", numOfEntry:%d. result is null", __FUNCTION__, pInfo->pHisto->numOfElems, pInfo->pHisto->numOfEntries); } } return functionFinalize(pCtx, pBlock); } int32_t apercentilePartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SAPercentileInfo* pInfo = (SAPercentileInfo*)GET_ROWCELL_INTERBUF(pResInfo); int32_t resultBytes = getApercentileMaxSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); if (pInfo->algo == APERCT_ALGO_TDIGEST) { memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); } else { memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); } int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } int32_t apercentileCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SAPercentileInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SAPercentileInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); qDebug("%s start to combine apercentile, %p", __FUNCTION__, pDBuf->pHisto); apercentileTransferInfo(pSBuf, pDBuf); pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } EFuncDataRequired firstDynDataReq(void* pRes, STimeWindow* pTimeWindow) { SResultRowEntryInfo* pEntry = (SResultRowEntryInfo*)pRes; // not initialized yet, data is required if (pEntry == NULL) { return FUNC_DATA_REQUIRED_DATA_LOAD; } SFirstLastRes* pResult = GET_ROWCELL_INTERBUF(pEntry); if (pResult->hasResult && pResult->ts <= pTimeWindow->skey) { return FUNC_DATA_REQUIRED_NOT_LOAD; } else { return FUNC_DATA_REQUIRED_DATA_LOAD; } } EFuncDataRequired lastDynDataReq(void* pRes, STimeWindow* pTimeWindow) { SResultRowEntryInfo* pEntry = (SResultRowEntryInfo*)pRes; // not initialized yet, data is required if (pEntry == NULL) { return FUNC_DATA_REQUIRED_DATA_LOAD; } SFirstLastRes* pResult = GET_ROWCELL_INTERBUF(pEntry); if (pResult->hasResult && pResult->ts >= pTimeWindow->ekey) { return FUNC_DATA_REQUIRED_NOT_LOAD; } else { return FUNC_DATA_REQUIRED_DATA_LOAD; } } int32_t getFirstLastInfoSize(int32_t resBytes) { return sizeof(SFirstLastRes) + resBytes; } bool getFirstLastFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { SColumnNode* pNode = (SColumnNode*)nodesListGetNode(pFunc->pParameterList, 0); pEnv->calcMemSize = getFirstLastInfoSize(pNode->node.resType.bytes); return true; } bool getSelectivityFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { SColumnNode* pNode = (SColumnNode*)nodesListGetNode(pFunc->pParameterList, 0); pEnv->calcMemSize = pNode->node.resType.bytes; return true; } bool getGroupKeyFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { SColumnNode* pNode = (SColumnNode*)nodesListGetNode(pFunc->pParameterList, 0); pEnv->calcMemSize = sizeof(SGroupKeyInfo) + pNode->node.resType.bytes; return true; } static FORCE_INLINE TSKEY getRowPTs(SColumnInfoData* pTsColInfo, int32_t rowIndex) { if (pTsColInfo == NULL) { return 0; } return *(TSKEY*)colDataGetData(pTsColInfo, rowIndex); } static void firstlastSaveTupleData(const SSDataBlock* pSrcBlock, int32_t rowIndex, SqlFunctionCtx* pCtx, SFirstLastRes* pInfo) { if (pCtx->subsidiaries.num <= 0) { return; } if (!pInfo->hasResult) { pInfo->pos = saveTupleData(pCtx, rowIndex, pSrcBlock, NULL); } else { updateTupleData(pCtx, rowIndex, pSrcBlock, &pInfo->pos); } } static void doSaveCurrentVal(SqlFunctionCtx* pCtx, int32_t rowIndex, int64_t currentTs, int32_t type, char* pData) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SFirstLastRes* pInfo = GET_ROWCELL_INTERBUF(pResInfo); if (IS_VAR_DATA_TYPE(type)) { pInfo->bytes = varDataTLen(pData); } memcpy(pInfo->buf, pData, pInfo->bytes); pInfo->ts = currentTs; firstlastSaveTupleData(pCtx->pSrcBlock, rowIndex, pCtx, pInfo); pInfo->hasResult = true; } // This ordinary first function does not care if current scan is ascending order or descending order scan // the OPTIMIZED version of first function will only handle the ascending order scan int32_t firstFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SFirstLastRes* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; pInfo->bytes = pInputCol->info.bytes; // All null data column, return directly. if (pInput->colDataAggIsSet && (pInput->pColumnDataAgg[0]->numOfNull == pInput->totalRows)) { ASSERT(pInputCol->hasNull == true); // save selectivity value for column consisted of all null values firstlastSaveTupleData(pCtx->pSrcBlock, pInput->startRowIndex, pCtx, pInfo); return 0; } SColumnDataAgg* pColAgg = (pInput->colDataAggIsSet) ? pInput->pColumnDataAgg[0] : NULL; TSKEY startKey = getRowPTs(pInput->pPTS, 0); TSKEY endKey = getRowPTs(pInput->pPTS, pInput->totalRows - 1); int32_t blockDataOrder = (startKey <= endKey) ? TSDB_ORDER_ASC : TSDB_ORDER_DESC; // please ref. to the comment in lastRowFunction for the reason why disabling the opt version of last/first function. // we will use this opt implementation in an new version that is only available in scan subplan #if 0 if (blockDataOrder == TSDB_ORDER_ASC) { // filter according to current result firstly if (pResInfo->numOfRes > 0) { if (pInfo->ts < startKey) { return TSDB_CODE_SUCCESS; } } for (int32_t i = pInput->startRowIndex; i < pInput->startRowIndex + pInput->numOfRows; ++i) { if (pInputCol->hasNull && colDataIsNull(pInputCol, pInput->totalRows, i, pColAgg)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); if (pResInfo->numOfRes == 0 || pInfo->ts > cts) { doSaveCurrentVal(pCtx, i, cts, pInputCol->info.type, data); break; } } } else { // in case of descending order time stamp serial, which usually happens as the results of the nest query, // all data needs to be check. if (pResInfo->numOfRes > 0) { if (pInfo->ts < endKey) { return TSDB_CODE_SUCCESS; } } for (int32_t i = pInput->numOfRows + pInput->startRowIndex - 1; i >= pInput->startRowIndex; --i) { if (pInputCol->hasNull && colDataIsNull(pInputCol, pInput->totalRows, i, pColAgg)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); if (pResInfo->numOfRes == 0 || pInfo->ts > cts) { doSaveCurrentVal(pCtx, i, cts, pInputCol->info.type, data); break; } } } #else for (int32_t i = pInput->startRowIndex; i < pInput->startRowIndex + pInput->numOfRows; ++i) { if (pInputCol->hasNull && colDataIsNull(pInputCol, pInput->totalRows, i, pColAgg)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); if (pResInfo->numOfRes == 0 || pInfo->ts > cts) { doSaveCurrentVal(pCtx, i, cts, pInputCol->info.type, data); pResInfo->numOfRes = 1; } } #endif if (numOfElems == 0) { // save selectivity value for column consisted of all null values firstlastSaveTupleData(pCtx->pSrcBlock, pInput->startRowIndex, pCtx, pInfo); } SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; } int32_t lastFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SFirstLastRes* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t type = pInputCol->info.type; int32_t bytes = pInputCol->info.bytes; pInfo->bytes = bytes; // All null data column, return directly. if (pInput->colDataAggIsSet && (pInput->pColumnDataAgg[0]->numOfNull == pInput->totalRows)) { ASSERT(pInputCol->hasNull == true); // save selectivity value for column consisted of all null values firstlastSaveTupleData(pCtx->pSrcBlock, pInput->startRowIndex, pCtx, pInfo); return 0; } SColumnDataAgg* pColAgg = (pInput->colDataAggIsSet) ? pInput->pColumnDataAgg[0] : NULL; TSKEY startKey = getRowPTs(pInput->pPTS, 0); TSKEY endKey = getRowPTs(pInput->pPTS, pInput->totalRows - 1); int32_t blockDataOrder = (startKey <= endKey) ? TSDB_ORDER_ASC : TSDB_ORDER_DESC; // please ref. to the comment in lastRowFunction for the reason why disabling the opt version of last/first function. #if 0 if (blockDataOrder == TSDB_ORDER_ASC) { for (int32_t i = pInput->numOfRows + pInput->startRowIndex - 1; i >= pInput->startRowIndex; --i) { if (pInputCol->hasNull && colDataIsNull(pInputCol, pInput->totalRows, i, pColAgg)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveCurrentVal(pCtx, i, cts, type, data); } break; } } else { // descending order for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; ++i) { if (pInputCol->hasNull && colDataIsNull(pInputCol, pInput->totalRows, i, pColAgg)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveCurrentVal(pCtx, i, cts, type, data); } break; } } #else int64_t* pts = (int64_t*)pInput->pPTS->pData; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; ++i) { if (pInputCol->hasNull && colDataIsNull(pInputCol, pInput->totalRows, i, pColAgg)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = pts[i]; if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveCurrentVal(pCtx, i, cts, type, data); pResInfo->numOfRes = 1; } } #endif // save selectivity value for column consisted of all null values if (numOfElems == 0) { firstlastSaveTupleData(pCtx->pSrcBlock, pInput->startRowIndex, pCtx, pInfo); } SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; } static void firstLastTransferInfo(SqlFunctionCtx* pCtx, SFirstLastRes* pInput, SFirstLastRes* pOutput, bool isFirst, int32_t rowIndex) { if (pOutput->hasResult) { if (isFirst) { if (pInput->ts > pOutput->ts) { return; } } else { if (pInput->ts < pOutput->ts) { return; } } } pOutput->isNull = pInput->isNull; pOutput->ts = pInput->ts; pOutput->bytes = pInput->bytes; memcpy(pOutput->buf, pInput->buf, pOutput->bytes); firstlastSaveTupleData(pCtx->pSrcBlock, rowIndex, pCtx, pOutput); pOutput->hasResult = true; } static int32_t firstLastFunctionMergeImpl(SqlFunctionCtx* pCtx, bool isFirstQuery) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SFirstLastRes* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t start = pInput->startRowIndex; int32_t numOfElems = 0; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SFirstLastRes* pInputInfo = (SFirstLastRes*)varDataVal(data); firstLastTransferInfo(pCtx, pInputInfo, pInfo, isFirstQuery, i); if (!numOfElems) { numOfElems = pInputInfo->hasResult ? 1 : 0; } } SET_VAL(GET_RES_INFO(pCtx), numOfElems, 1); return TSDB_CODE_SUCCESS; } int32_t firstFunctionMerge(SqlFunctionCtx* pCtx) { return firstLastFunctionMergeImpl(pCtx, true); } int32_t lastFunctionMerge(SqlFunctionCtx* pCtx) { return firstLastFunctionMergeImpl(pCtx, false); } int32_t firstLastFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); pResInfo->isNullRes = (pResInfo->numOfRes == 0) ? 1 : 0; SFirstLastRes* pRes = GET_ROWCELL_INTERBUF(pResInfo); colDataAppend(pCol, pBlock->info.rows, pRes->buf, pRes->isNull || pResInfo->isNullRes); // handle selectivity setSelectivityValue(pCtx, pBlock, &pRes->pos, pBlock->info.rows); return pResInfo->numOfRes; } int32_t firstLastPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(pCtx); SFirstLastRes* pRes = GET_ROWCELL_INTERBUF(pEntryInfo); int32_t resultBytes = getFirstLastInfoSize(pRes->bytes); // todo check for failure char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pRes, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); setSelectivityValue(pCtx, pBlock, &pRes->pos, pBlock->info.rows); taosMemoryFree(res); return 1; } // todo rewrite: int32_t lastCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SFirstLastRes* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); int32_t bytes = pDBuf->bytes; SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SFirstLastRes* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); if (pSResInfo->numOfRes != 0 && (pDResInfo->numOfRes == 0 || pDBuf->ts < pSBuf->ts)) { memcpy(pDBuf->buf, pSBuf->buf, bytes); pDBuf->ts = pSBuf->ts; pDResInfo->numOfRes = 1; } return TSDB_CODE_SUCCESS; } static void doSaveLastrow(SqlFunctionCtx* pCtx, char* pData, int32_t rowIndex, int64_t cts, SFirstLastRes* pInfo) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; if (colDataIsNull_s(pInputCol, rowIndex)) { pInfo->isNull = true; } else { pInfo->isNull = false; if (IS_VAR_DATA_TYPE(pInputCol->info.type)) { pInfo->bytes = varDataTLen(pData); } memcpy(pInfo->buf, pData, pInfo->bytes); } pInfo->ts = cts; firstlastSaveTupleData(pCtx->pSrcBlock, rowIndex, pCtx, pInfo); pInfo->hasResult = true; } int32_t lastRowFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SFirstLastRes* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t bytes = pInputCol->info.bytes; pInfo->bytes = bytes; TSKEY startKey = getRowPTs(pInput->pPTS, 0); TSKEY endKey = getRowPTs(pInput->pPTS, pInput->totalRows - 1); #if 0 int32_t blockDataOrder = (startKey <= endKey) ? TSDB_ORDER_ASC : TSDB_ORDER_DESC; // the optimized version only function if all tuples in one block are monotonious increasing or descreasing. // this is NOT always works if project operator exists in downstream. if (blockDataOrder == TSDB_ORDER_ASC) { for (int32_t i = pInput->numOfRows + pInput->startRowIndex - 1; i >= pInput->startRowIndex; --i) { char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); numOfElems++; if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveLastrow(pCtx, data, i, cts, pInfo); } break; } } else { // descending order for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; ++i) { char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); numOfElems++; if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveLastrow(pCtx, data, i, cts, pInfo); } break; } } #else int64_t* pts = (int64_t*)pInput->pPTS->pData; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; ++i) { char* data = colDataGetData(pInputCol, i); TSKEY cts = pts[i]; numOfElems++; if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveLastrow(pCtx, data, i, cts, pInfo); pResInfo->numOfRes = 1; } } #endif SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; } bool getDiffFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SDiffInfo); return true; } bool diffFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResInfo) { if (!functionSetup(pCtx, pResInfo)) { return false; } SDiffInfo* pDiffInfo = GET_ROWCELL_INTERBUF(pResInfo); pDiffInfo->hasPrev = false; pDiffInfo->prev.i64 = 0; if (pCtx->numOfParams > 1) { pDiffInfo->ignoreNegative = pCtx->param[1].param.i; // TODO set correct param } else { pDiffInfo->ignoreNegative = false; } pDiffInfo->includeNull = false; pDiffInfo->firstOutput = false; return true; } static void doSetPrevVal(SDiffInfo* pDiffInfo, int32_t type, const char* pv) { switch (type) { case TSDB_DATA_TYPE_BOOL: pDiffInfo->prev.i64 = *(bool*)pv ? 1 : 0; break; case TSDB_DATA_TYPE_TINYINT: pDiffInfo->prev.i64 = *(int8_t*)pv; break; case TSDB_DATA_TYPE_INT: pDiffInfo->prev.i64 = *(int32_t*)pv; break; case TSDB_DATA_TYPE_SMALLINT: pDiffInfo->prev.i64 = *(int16_t*)pv; break; case TSDB_DATA_TYPE_TIMESTAMP: case TSDB_DATA_TYPE_BIGINT: pDiffInfo->prev.i64 = *(int64_t*)pv; break; case TSDB_DATA_TYPE_FLOAT: pDiffInfo->prev.d64 = *(float*)pv; break; case TSDB_DATA_TYPE_DOUBLE: pDiffInfo->prev.d64 = *(double*)pv; break; default: ASSERT(0); } } static void doHandleDiff(SDiffInfo* pDiffInfo, int32_t type, const char* pv, SColumnInfoData* pOutput, int32_t pos, int32_t order) { int32_t factor = (order == TSDB_ORDER_ASC) ? 1 : -1; switch (type) { case TSDB_DATA_TYPE_INT: { int32_t v = *(int32_t*)pv; int64_t delta = factor * (v - pDiffInfo->prev.i64); // direct previous may be null if (delta < 0 && pDiffInfo->ignoreNegative) { colDataSetNull_f(pOutput->nullbitmap, pos); } else { colDataAppendInt64(pOutput, pos, &delta); } pDiffInfo->prev.i64 = v; break; } case TSDB_DATA_TYPE_BOOL: case TSDB_DATA_TYPE_TINYINT: { int8_t v = *(int8_t*)pv; int64_t delta = factor * (v - pDiffInfo->prev.i64); // direct previous may be null if (delta < 0 && pDiffInfo->ignoreNegative) { colDataSetNull_f(pOutput->nullbitmap, pos); } else { colDataAppendInt64(pOutput, pos, &delta); } pDiffInfo->prev.i64 = v; break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t v = *(int16_t*)pv; int64_t delta = factor * (v - pDiffInfo->prev.i64); // direct previous may be null if (delta < 0 && pDiffInfo->ignoreNegative) { colDataSetNull_f(pOutput->nullbitmap, pos); } else { colDataAppendInt64(pOutput, pos, &delta); } pDiffInfo->prev.i64 = v; break; } case TSDB_DATA_TYPE_TIMESTAMP: case TSDB_DATA_TYPE_BIGINT: { int64_t v = *(int64_t*)pv; int64_t delta = factor * (v - pDiffInfo->prev.i64); // direct previous may be null if (delta < 0 && pDiffInfo->ignoreNegative) { colDataSetNull_f(pOutput->nullbitmap, pos); } else { colDataAppendInt64(pOutput, pos, &delta); } pDiffInfo->prev.i64 = v; break; } case TSDB_DATA_TYPE_FLOAT: { float v = *(float*)pv; double delta = factor * (v - pDiffInfo->prev.d64); // direct previous may be null if ((delta < 0 && pDiffInfo->ignoreNegative) || isinf(delta) || isnan(delta)) { // check for overflow colDataSetNull_f(pOutput->nullbitmap, pos); } else { colDataAppendDouble(pOutput, pos, &delta); } pDiffInfo->prev.d64 = v; break; } case TSDB_DATA_TYPE_DOUBLE: { double v = *(double*)pv; double delta = factor * (v - pDiffInfo->prev.d64); // direct previous may be null if ((delta < 0 && pDiffInfo->ignoreNegative) || isinf(delta) || isnan(delta)) { // check for overflow colDataSetNull_f(pOutput->nullbitmap, pos); } else { colDataAppendDouble(pOutput, pos, &delta); } pDiffInfo->prev.d64 = v; break; } default: ASSERT(0); } } int32_t diffFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SDiffInfo* pDiffInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t numOfElems = 0; int32_t startOffset = pCtx->offset; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; if (pCtx->order == TSDB_ORDER_ASC) { for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { int32_t pos = startOffset + numOfElems; if (colDataIsNull_f(pInputCol->nullbitmap, i)) { if (pDiffInfo->includeNull) { colDataSetNull_f(pOutput->nullbitmap, pos); numOfElems += 1; } continue; } char* pv = colDataGetData(pInputCol, i); if (pDiffInfo->hasPrev) { doHandleDiff(pDiffInfo, pInputCol->info.type, pv, pOutput, pos, pCtx->order); // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pos); } numOfElems++; } else { doSetPrevVal(pDiffInfo, pInputCol->info.type, pv); } pDiffInfo->hasPrev = true; } } else { for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { int32_t pos = startOffset + numOfElems; if (colDataIsNull_f(pInputCol->nullbitmap, i)) { if (pDiffInfo->includeNull) { colDataSetNull_f(pOutput->nullbitmap, pos); numOfElems += 1; } continue; } char* pv = colDataGetData(pInputCol, i); // there is a row of previous data block to be handled in the first place. if (pDiffInfo->hasPrev) { doHandleDiff(pDiffInfo, pInputCol->info.type, pv, pOutput, pos, pCtx->order); // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pos); } numOfElems++; } else { doSetPrevVal(pDiffInfo, pInputCol->info.type, pv); } pDiffInfo->hasPrev = true; } } // initial value is not set yet return numOfElems; } int32_t getTopBotInfoSize(int64_t numOfItems) { return sizeof(STopBotRes) + numOfItems * sizeof(STopBotResItem); } bool getTopBotFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { SValueNode* pkNode = (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1); pEnv->calcMemSize = sizeof(STopBotRes) + pkNode->datum.i * sizeof(STopBotResItem); return true; } bool topBotFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResInfo) { if (!functionSetup(pCtx, pResInfo)) { return false; } STopBotRes* pRes = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; pRes->maxSize = pCtx->param[1].param.i; pRes->nullTupleSaved = false; pRes->nullTuplePos.pageId = -1; return true; } static STopBotRes* getTopBotOutputInfo(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); STopBotRes* pRes = GET_ROWCELL_INTERBUF(pResInfo); pRes->pItems = (STopBotResItem*)((char*)pRes + sizeof(STopBotRes)); return pRes; } static void doAddIntoResult(SqlFunctionCtx* pCtx, void* pData, int32_t rowIndex, SSDataBlock* pSrcBlock, uint16_t type, uint64_t uid, SResultRowEntryInfo* pEntryInfo, bool isTopQuery); static void addResult(SqlFunctionCtx* pCtx, STopBotResItem* pSourceItem, int16_t type, bool isTopQuery); int32_t topFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; STopBotRes* pRes = getTopBotOutputInfo(pCtx); pRes->type = pInput->pData[0]->info.type; int32_t start = pInput->startRowIndex; for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElems++; char* data = colDataGetData(pCol, i); doAddIntoResult(pCtx, data, i, pCtx->pSrcBlock, pRes->type, pInput->uid, pResInfo, true); } if (numOfElems == 0 && pCtx->subsidiaries.num > 0 && !pRes->nullTupleSaved) { pRes->nullTuplePos = saveTupleData(pCtx, pInput->startRowIndex, pCtx->pSrcBlock, NULL); pRes->nullTupleSaved = true; } return TSDB_CODE_SUCCESS; } int32_t bottomFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; STopBotRes* pRes = getTopBotOutputInfo(pCtx); pRes->type = pInput->pData[0]->info.type; int32_t start = pInput->startRowIndex; for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElems++; char* data = colDataGetData(pCol, i); doAddIntoResult(pCtx, data, i, pCtx->pSrcBlock, pRes->type, pInput->uid, pResInfo, false); } if (numOfElems == 0 && pCtx->subsidiaries.num > 0 && !pRes->nullTupleSaved) { pRes->nullTuplePos = saveTupleData(pCtx, pInput->startRowIndex, pCtx->pSrcBlock, NULL); pRes->nullTupleSaved = true; } return TSDB_CODE_SUCCESS; } static int32_t topBotResComparFn(const void* p1, const void* p2, const void* param) { uint16_t type = *(uint16_t*)param; STopBotResItem* val1 = (STopBotResItem*)p1; STopBotResItem* val2 = (STopBotResItem*)p2; if (IS_SIGNED_NUMERIC_TYPE(type)) { if (val1->v.i == val2->v.i) { return 0; } return (val1->v.i > val2->v.i) ? 1 : -1; } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { if (val1->v.u == val2->v.u) { return 0; } return (val1->v.u > val2->v.u) ? 1 : -1; } if (val1->v.d == val2->v.d) { return 0; } return (val1->v.d > val2->v.d) ? 1 : -1; } void doAddIntoResult(SqlFunctionCtx* pCtx, void* pData, int32_t rowIndex, SSDataBlock* pSrcBlock, uint16_t type, uint64_t uid, SResultRowEntryInfo* pEntryInfo, bool isTopQuery) { STopBotRes* pRes = getTopBotOutputInfo(pCtx); SVariant val = {0}; taosVariantCreateFromBinary(&val, pData, tDataTypes[type].bytes, type); STopBotResItem* pItems = pRes->pItems; assert(pItems != NULL); // not full yet if (pEntryInfo->numOfRes < pRes->maxSize) { STopBotResItem* pItem = &pItems[pEntryInfo->numOfRes]; pItem->v = val; pItem->uid = uid; // save the data of this tuple if (pCtx->subsidiaries.num > 0) { pItem->tuplePos = saveTupleData(pCtx, rowIndex, pSrcBlock, NULL); } #ifdef BUF_PAGE_DEBUG qDebug("page_saveTuple i:%d, item:%p,pageId:%d, offset:%d\n", pEntryInfo->numOfRes, pItem, pItem->tuplePos.pageId, pItem->tuplePos.offset); #endif // allocate the buffer and keep the data of this row into the new allocated buffer pEntryInfo->numOfRes++; taosheapsort((void*)pItems, sizeof(STopBotResItem), pEntryInfo->numOfRes, (const void*)&type, topBotResComparFn, !isTopQuery); } else { // replace the minimum value in the result if ((isTopQuery && ((IS_SIGNED_NUMERIC_TYPE(type) && val.i > pItems[0].v.i) || (IS_UNSIGNED_NUMERIC_TYPE(type) && val.u > pItems[0].v.u) || (IS_FLOAT_TYPE(type) && val.d > pItems[0].v.d))) || (!isTopQuery && ((IS_SIGNED_NUMERIC_TYPE(type) && val.i < pItems[0].v.i) || (IS_UNSIGNED_NUMERIC_TYPE(type) && val.u < pItems[0].v.u) || (IS_FLOAT_TYPE(type) && val.d < pItems[0].v.d)))) { // replace the old data and the coresponding tuple data STopBotResItem* pItem = &pItems[0]; pItem->v = val; pItem->uid = uid; // save the data of this tuple by over writing the old data if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, rowIndex, pSrcBlock, &pItem->tuplePos); } #ifdef BUF_PAGE_DEBUG qDebug("page_copyTuple pageId:%d, offset:%d", pItem->tuplePos.pageId, pItem->tuplePos.offset); #endif taosheapadjust((void*)pItems, sizeof(STopBotResItem), 0, pEntryInfo->numOfRes - 1, (const void*)&type, topBotResComparFn, NULL, !isTopQuery); } } } /* * +------------------------------------+--------------+--------------+ * | null bitmap | | | * |(n columns, one bit for each column)| src column #1| src column #2| * +------------------------------------+--------------+--------------+ */ void* serializeTupleData(const SSDataBlock* pSrcBlock, int32_t rowIndex, SSubsidiaryResInfo* pSubsidiaryies, char* buf) { char* nullList = buf; char* pStart = (char*)(nullList + sizeof(bool) * pSubsidiaryies->num); int32_t offset = 0; for (int32_t i = 0; i < pSubsidiaryies->num; ++i) { SqlFunctionCtx* pc = pSubsidiaryies->pCtx[i]; SFunctParam* pFuncParam = &pc->pExpr->base.pParam[0]; int32_t srcSlotId = pFuncParam->pCol->slotId; SColumnInfoData* pCol = taosArrayGet(pSrcBlock->pDataBlock, srcSlotId); if ((nullList[i] = colDataIsNull_s(pCol, rowIndex)) == true) { offset += pCol->info.bytes; continue; } char* p = colDataGetData(pCol, rowIndex); if (IS_VAR_DATA_TYPE(pCol->info.type)) { memcpy(pStart + offset, p, (pCol->info.type == TSDB_DATA_TYPE_JSON) ? getJsonValueLen(p) : varDataTLen(p)); } else { memcpy(pStart + offset, p, pCol->info.bytes); } offset += pCol->info.bytes; } return buf; } static STuplePos doSaveTupleData(SSerializeDataHandle* pHandle, const void* pBuf, size_t length, const STupleKey* pKey) { STuplePos p = {0}; if (pHandle->pBuf != NULL) { SFilePage* pPage = NULL; if (pHandle->currentPage == -1) { pPage = getNewBufPage(pHandle->pBuf, &pHandle->currentPage); pPage->num = sizeof(SFilePage); } else { pPage = getBufPage(pHandle->pBuf, pHandle->currentPage); if (pPage->num + length > getBufPageSize(pHandle->pBuf)) { // current page is all used, let's prepare a new buffer page releaseBufPage(pHandle->pBuf, pPage); pPage = getNewBufPage(pHandle->pBuf, &pHandle->currentPage); pPage->num = sizeof(SFilePage); } } p = (STuplePos){.pageId = pHandle->currentPage, .offset = pPage->num}; memcpy(pPage->data + pPage->num, pBuf, length); pPage->num += length; setBufPageDirty(pPage, true); releaseBufPage(pHandle->pBuf, pPage); } else { // other tuple save policy if (streamStateFuncPut(pHandle->pState, pKey, pBuf, length) < 0) { ASSERT(0); } p.streamTupleKey = *pKey; } return p; } STuplePos saveTupleData(SqlFunctionCtx* pCtx, int32_t rowIndex, const SSDataBlock* pSrcBlock, const STupleKey* pKey) { if (pCtx->subsidiaries.rowLen == 0) { int32_t rowLen = 0; for (int32_t j = 0; j < pCtx->subsidiaries.num; ++j) { SqlFunctionCtx* pc = pCtx->subsidiaries.pCtx[j]; rowLen += pc->pExpr->base.resSchema.bytes; } pCtx->subsidiaries.rowLen = rowLen + pCtx->subsidiaries.num * sizeof(bool); pCtx->subsidiaries.buf = taosMemoryMalloc(pCtx->subsidiaries.rowLen); } char* buf = serializeTupleData(pSrcBlock, rowIndex, &pCtx->subsidiaries, pCtx->subsidiaries.buf); return doSaveTupleData(&pCtx->saveHandle, buf, pCtx->subsidiaries.rowLen, pKey); } static int32_t doUpdateTupleData(SSerializeDataHandle* pHandle, const void* pBuf, size_t length, STuplePos* pPos) { if (pHandle->pBuf != NULL) { SFilePage* pPage = getBufPage(pHandle->pBuf, pPos->pageId); memcpy(pPage->data + pPos->offset, pBuf, length); setBufPageDirty(pPage, true); releaseBufPage(pHandle->pBuf, pPage); } else { streamStateFuncPut(pHandle->pState, &pPos->streamTupleKey, pBuf, length); } return TSDB_CODE_SUCCESS; } static int32_t updateTupleData(SqlFunctionCtx* pCtx, int32_t rowIndex, const SSDataBlock* pSrcBlock, STuplePos* pPos) { char* buf = serializeTupleData(pSrcBlock, rowIndex, &pCtx->subsidiaries, pCtx->subsidiaries.buf); doUpdateTupleData(&pCtx->saveHandle, buf, pCtx->subsidiaries.rowLen, pPos); return TSDB_CODE_SUCCESS; } static char* doLoadTupleData(SSerializeDataHandle* pHandle, const STuplePos* pPos) { if (pHandle->pBuf != NULL) { SFilePage* pPage = getBufPage(pHandle->pBuf, pPos->pageId); char* p = pPage->data + pPos->offset; releaseBufPage(pHandle->pBuf, pPage); return p; } else { void* value = NULL; int32_t vLen; streamStateFuncGet(pHandle->pState, &pPos->streamTupleKey, &value, &vLen); return (char*)value; } } static const char* loadTupleData(SqlFunctionCtx* pCtx, const STuplePos* pPos) { return doLoadTupleData(&pCtx->saveHandle, pPos); } int32_t topBotFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(pCtx); STopBotRes* pRes = getTopBotOutputInfo(pCtx); int16_t type = pCtx->pExpr->base.resSchema.type; int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); // todo assign the tag value and the corresponding row data int32_t currentRow = pBlock->info.rows; if (pEntryInfo->numOfRes <= 0) { colDataAppendNULL(pCol, currentRow); setSelectivityValue(pCtx, pBlock, &pRes->nullTuplePos, currentRow); return pEntryInfo->numOfRes; } for (int32_t i = 0; i < pEntryInfo->numOfRes; ++i) { STopBotResItem* pItem = &pRes->pItems[i]; if (type == TSDB_DATA_TYPE_FLOAT) { float v = pItem->v.d; colDataAppend(pCol, currentRow, (const char*)&v, false); } else { colDataAppend(pCol, currentRow, (const char*)&pItem->v.i, false); } #ifdef BUF_PAGE_DEBUG qDebug("page_finalize i:%d,item:%p,pageId:%d, offset:%d\n", i, pItem, pItem->tuplePos.pageId, pItem->tuplePos.offset); #endif setSelectivityValue(pCtx, pBlock, &pRes->pItems[i].tuplePos, currentRow); currentRow += 1; } return pEntryInfo->numOfRes; } void addResult(SqlFunctionCtx* pCtx, STopBotResItem* pSourceItem, int16_t type, bool isTopQuery) { SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(pCtx); STopBotRes* pRes = getTopBotOutputInfo(pCtx); STopBotResItem* pItems = pRes->pItems; assert(pItems != NULL); // not full yet if (pEntryInfo->numOfRes < pRes->maxSize) { STopBotResItem* pItem = &pItems[pEntryInfo->numOfRes]; pItem->v = pSourceItem->v; pItem->uid = pSourceItem->uid; pItem->tuplePos.pageId = -1; replaceTupleData(&pItem->tuplePos, &pSourceItem->tuplePos); pEntryInfo->numOfRes++; taosheapsort((void*)pItems, sizeof(STopBotResItem), pEntryInfo->numOfRes, (const void*)&type, topBotResComparFn, !isTopQuery); } else { // replace the minimum value in the result if ((isTopQuery && ((IS_SIGNED_NUMERIC_TYPE(type) && pSourceItem->v.i > pItems[0].v.i) || (IS_UNSIGNED_NUMERIC_TYPE(type) && pSourceItem->v.u > pItems[0].v.u) || (IS_FLOAT_TYPE(type) && pSourceItem->v.d > pItems[0].v.d))) || (!isTopQuery && ((IS_SIGNED_NUMERIC_TYPE(type) && pSourceItem->v.i < pItems[0].v.i) || (IS_UNSIGNED_NUMERIC_TYPE(type) && pSourceItem->v.u < pItems[0].v.u) || (IS_FLOAT_TYPE(type) && pSourceItem->v.d < pItems[0].v.d)))) { // replace the old data and the coresponding tuple data STopBotResItem* pItem = &pItems[0]; pItem->v = pSourceItem->v; pItem->uid = pSourceItem->uid; // save the data of this tuple by over writing the old data replaceTupleData(&pItem->tuplePos, &pSourceItem->tuplePos); taosheapadjust((void*)pItems, sizeof(STopBotResItem), 0, pEntryInfo->numOfRes - 1, (const void*)&type, topBotResComparFn, NULL, !isTopQuery); } } } int32_t topCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); STopBotRes* pSBuf = getTopBotOutputInfo(pSourceCtx); int16_t type = pSBuf->type; for (int32_t i = 0; i < pSResInfo->numOfRes; i++) { addResult(pDestCtx, pSBuf->pItems + i, type, true); } return TSDB_CODE_SUCCESS; } int32_t bottomCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); STopBotRes* pSBuf = getTopBotOutputInfo(pSourceCtx); int16_t type = pSBuf->type; for (int32_t i = 0; i < pSResInfo->numOfRes; i++) { addResult(pDestCtx, pSBuf->pItems + i, type, false); } return TSDB_CODE_SUCCESS; } int32_t getSpreadInfoSize() { return (int32_t)sizeof(SSpreadInfo); } bool getSpreadFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SSpreadInfo); return true; } bool spreadFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SSpreadInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); SET_DOUBLE_VAL(&pInfo->min, DBL_MAX); SET_DOUBLE_VAL(&pInfo->max, -DBL_MAX); pInfo->hasResult = false; return true; } int32_t spreadFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; int32_t type = pInput->pData[0]->info.type; SSpreadInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); if (pInput->colDataAggIsSet) { numOfElems = pInput->numOfRows - pAgg->numOfNull; if (numOfElems == 0) { goto _spread_over; } double tmin = 0.0, tmax = 0.0; if (IS_SIGNED_NUMERIC_TYPE(type)) { tmin = (double)GET_INT64_VAL(&pAgg->min); tmax = (double)GET_INT64_VAL(&pAgg->max); } else if (IS_FLOAT_TYPE(type)) { tmin = GET_DOUBLE_VAL(&pAgg->min); tmax = GET_DOUBLE_VAL(&pAgg->max); } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { tmin = (double)GET_UINT64_VAL(&pAgg->min); tmax = (double)GET_UINT64_VAL(&pAgg->max); } if (GET_DOUBLE_VAL(&pInfo->min) > tmin) { SET_DOUBLE_VAL(&pInfo->min, tmin); } if (GET_DOUBLE_VAL(&pInfo->max) < tmax) { SET_DOUBLE_VAL(&pInfo->max, tmax); } } else { // computing based on the true data block SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; // check the valid data one by one for (int32_t i = start; i < pInput->numOfRows + start; ++i) { if (colDataIsNull_f(pCol->nullbitmap, i)) { continue; } char* data = colDataGetData(pCol, i); double v = 0; GET_TYPED_DATA(v, double, type, data); if (v < GET_DOUBLE_VAL(&pInfo->min)) { SET_DOUBLE_VAL(&pInfo->min, v); } if (v > GET_DOUBLE_VAL(&pInfo->max)) { SET_DOUBLE_VAL(&pInfo->max, v); } numOfElems += 1; } } _spread_over: // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElems, 1); if (numOfElems > 0) { pInfo->hasResult = true; } return TSDB_CODE_SUCCESS; } static void spreadTransferInfo(SSpreadInfo* pInput, SSpreadInfo* pOutput) { pOutput->hasResult = pInput->hasResult; if (pInput->max > pOutput->max) { pOutput->max = pInput->max; } if (pInput->min < pOutput->min) { pOutput->min = pInput->min; } } int32_t spreadFunctionMerge(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SSpreadInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t start = pInput->startRowIndex; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SSpreadInfo* pInputInfo = (SSpreadInfo*)varDataVal(data); if (pInputInfo->hasResult) { spreadTransferInfo(pInputInfo, pInfo); } } if (pInfo->hasResult) { GET_RES_INFO(pCtx)->numOfRes = 1; } return TSDB_CODE_SUCCESS; } int32_t spreadFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SSpreadInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); if (pInfo->hasResult == true) { SET_DOUBLE_VAL(&pInfo->result, pInfo->max - pInfo->min); } else { GET_RES_INFO(pCtx)->isNullRes = 1; } return functionFinalize(pCtx, pBlock); } int32_t spreadPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SSpreadInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t resultBytes = getSpreadInfoSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } int32_t spreadCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SSpreadInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SSpreadInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); spreadTransferInfo(pSBuf, pDBuf); pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } int32_t getElapsedInfoSize() { return (int32_t)sizeof(SElapsedInfo); } bool getElapsedFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SElapsedInfo); return true; } bool elapsedFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SElapsedInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); pInfo->result = 0; pInfo->min = TSKEY_MAX; pInfo->max = 0; if (pCtx->numOfParams > 1) { pInfo->timeUnit = pCtx->param[1].param.i; } else { pInfo->timeUnit = 1; } return true; } int32_t elapsedFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; // Only the pre-computing information loaded and actual data does not loaded SInputColumnInfoData* pInput = &pCtx->input; SColumnDataAgg* pAgg = pInput->pColumnDataAgg[0]; SElapsedInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); numOfElems = pInput->numOfRows; // since this is the primary timestamp, no need to exclude NULL values if (numOfElems == 0) { goto _elapsed_over; } if (pInput->colDataAggIsSet) { if (pInfo->min == TSKEY_MAX) { pInfo->min = GET_INT64_VAL(&pAgg->min); pInfo->max = GET_INT64_VAL(&pAgg->max); } else { if (pCtx->order == TSDB_ORDER_ASC) { pInfo->max = GET_INT64_VAL(&pAgg->max); } else { pInfo->min = GET_INT64_VAL(&pAgg->min); } } } else { // computing based on the true data block if (0 == pInput->numOfRows) { if (pCtx->order == TSDB_ORDER_DESC) { if (pCtx->end.key != INT64_MIN) { pInfo->min = pCtx->end.key; } } else { if (pCtx->end.key != INT64_MIN) { pInfo->max = pCtx->end.key + 1; } } goto _elapsed_over; } SColumnInfoData* pCol = pInput->pData[0]; int32_t start = pInput->startRowIndex; TSKEY* ptsList = (int64_t*)colDataGetData(pCol, 0); if (pCtx->order == TSDB_ORDER_DESC) { if (pCtx->start.key == INT64_MIN) { pInfo->max = (pInfo->max < ptsList[start]) ? ptsList[start] : pInfo->max; } else { pInfo->max = pCtx->start.key + 1; } if (pCtx->end.key == INT64_MIN) { pInfo->min = (pInfo->min > ptsList[start + pInput->numOfRows - 1]) ? ptsList[start + pInput->numOfRows - 1] : pInfo->min; } else { pInfo->min = pCtx->end.key; } } else { if (pCtx->start.key == INT64_MIN) { pInfo->min = (pInfo->min > ptsList[start]) ? ptsList[start] : pInfo->min; } else { pInfo->min = pCtx->start.key; } if (pCtx->end.key == INT64_MIN) { pInfo->max = (pInfo->max < ptsList[start + pInput->numOfRows - 1]) ? ptsList[start + pInput->numOfRows - 1] : pInfo->max; } else { pInfo->max = pCtx->end.key + 1; } } } _elapsed_over: // data in the check operation are all null, not output SET_VAL(GET_RES_INFO(pCtx), numOfElems, 1); return TSDB_CODE_SUCCESS; } static void elapsedTransferInfo(SElapsedInfo* pInput, SElapsedInfo* pOutput) { pOutput->timeUnit = pInput->timeUnit; if (pOutput->min > pInput->min) { pOutput->min = pInput->min; } if (pOutput->max < pInput->max) { pOutput->max = pInput->max; } } int32_t elapsedFunctionMerge(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SElapsedInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t start = pInput->startRowIndex; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SElapsedInfo* pInputInfo = (SElapsedInfo*)varDataVal(data); elapsedTransferInfo(pInputInfo, pInfo); } SET_VAL(GET_RES_INFO(pCtx), 1, 1); return TSDB_CODE_SUCCESS; } int32_t elapsedFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SElapsedInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); double result = (double)pInfo->max - (double)pInfo->min; result = (result >= 0) ? result : -result; pInfo->result = result / pInfo->timeUnit; return functionFinalize(pCtx, pBlock); } int32_t elapsedPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SElapsedInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t resultBytes = getElapsedInfoSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } int32_t elapsedCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SElapsedInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SElapsedInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); elapsedTransferInfo(pSBuf, pDBuf); pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } int32_t getHistogramInfoSize() { return (int32_t)sizeof(SHistoFuncInfo) + HISTOGRAM_MAX_BINS_NUM * sizeof(SHistoFuncBin); } bool getHistogramFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SHistoFuncInfo) + HISTOGRAM_MAX_BINS_NUM * sizeof(SHistoFuncBin); return true; } static int8_t getHistogramBinType(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 getHistogramBinDesc(SHistoFuncInfo* pInfo, char* binDescStr, int8_t binType, bool normalized) { 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) { 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)) { return false; } if (count->valueint <= 0 || count->valueint > 1000) { // limit count to 1000 return false; } if (isinf(start->valuedouble) || (width != NULL && isinf(width->valuedouble)) || (factor != NULL && isinf(factor->valuedouble)) || (count != NULL && isinf(count->valuedouble))) { 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) { taosMemoryFree(intervals); return false; } for (int i = 0; i < counter + 1; ++i) { intervals[startIndex] = start->valuedouble + i * width->valuedouble; if (isinf(intervals[startIndex])) { taosMemoryFree(intervals); return false; } startIndex++; } } else if (cJSON_IsNumber(factor) && width == NULL && binType == LOG_BIN) { // log bin process if (start->valuedouble == 0) { taosMemoryFree(intervals); return false; } if (factor->valuedouble < 0 || factor->valuedouble == 0 || factor->valuedouble == 1) { 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])) { taosMemoryFree(intervals); return false; } startIndex++; } } else { 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) { return false; } numOfBins = cJSON_GetArraySize(binDesc); intervals = taosMemoryCalloc(numOfBins, sizeof(double)); cJSON* bin = binDesc->child; if (bin == NULL) { taosMemoryFree(intervals); return false; } int i = 0; while (bin) { intervals[i] = bin->valuedouble; if (!cJSON_IsNumber(bin)) { taosMemoryFree(intervals); return false; } if (i != 0 && intervals[i] <= intervals[i - 1]) { taosMemoryFree(intervals); return false; } bin = bin->next; i++; } } else { return false; } pInfo->numOfBins = numOfBins - 1; pInfo->normalized = normalized; for (int32_t i = 0; i < pInfo->numOfBins; ++i) { pInfo->bins[i].lower = intervals[i] < intervals[i + 1] ? intervals[i] : intervals[i + 1]; pInfo->bins[i].upper = intervals[i + 1] > intervals[i] ? intervals[i + 1] : intervals[i]; pInfo->bins[i].count = 0; } taosMemoryFree(intervals); return true; } bool histogramFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SHistoFuncInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); pInfo->numOfBins = 0; pInfo->totalCount = 0; pInfo->normalized = 0; int8_t binType = getHistogramBinType(varDataVal(pCtx->param[1].param.pz)); if (binType == UNKNOWN_BIN) { return false; } char* binDesc = varDataVal(pCtx->param[2].param.pz); int64_t normalized = pCtx->param[3].param.i; if (normalized != 0 && normalized != 1) { return false; } if (!getHistogramBinDesc(pInfo, binDesc, binType, (bool)normalized)) { return false; } return true; } static int32_t histogramFunctionImpl(SqlFunctionCtx* pCtx, bool isPartial) { SHistoFuncInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; int32_t type = pInput->pData[0]->info.type; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; int32_t numOfElems = 0; for (int32_t i = start; i < numOfRows + start; ++i) { if (pCol->hasNull && colDataIsNull_f(pCol->nullbitmap, i)) { continue; } numOfElems++; char* data = colDataGetData(pCol, i); double v; GET_TYPED_DATA(v, double, type, data); for (int32_t k = 0; k < pInfo->numOfBins; ++k) { if (v > pInfo->bins[k].lower && v <= pInfo->bins[k].upper) { pInfo->bins[k].count++; pInfo->totalCount++; break; } } } if (!isPartial) { GET_RES_INFO(pCtx)->numOfRes = pInfo->numOfBins; } else { GET_RES_INFO(pCtx)->numOfRes = 1; } return TSDB_CODE_SUCCESS; } int32_t histogramFunction(SqlFunctionCtx* pCtx) { return histogramFunctionImpl(pCtx, false); } int32_t histogramFunctionPartial(SqlFunctionCtx* pCtx) { return histogramFunctionImpl(pCtx, true); } static void histogramTransferInfo(SHistoFuncInfo* pInput, SHistoFuncInfo* pOutput) { pOutput->normalized = pInput->normalized; pOutput->numOfBins = pInput->numOfBins; pOutput->totalCount += pInput->totalCount; for (int32_t k = 0; k < pOutput->numOfBins; ++k) { pOutput->bins[k].lower = pInput->bins[k].lower; pOutput->bins[k].upper = pInput->bins[k].upper; pOutput->bins[k].count += pInput->bins[k].count; } } int32_t histogramFunctionMerge(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SHistoFuncInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t start = pInput->startRowIndex; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SHistoFuncInfo* pInputInfo = (SHistoFuncInfo*)varDataVal(data); histogramTransferInfo(pInputInfo, pInfo); } SET_VAL(GET_RES_INFO(pCtx), pInfo->numOfBins, pInfo->numOfBins); return TSDB_CODE_SUCCESS; } int32_t histogramFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SHistoFuncInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); int32_t currentRow = pBlock->info.rows; if (pInfo->normalized) { for (int32_t k = 0; k < pResInfo->numOfRes; ++k) { if (pInfo->totalCount != 0) { pInfo->bins[k].percentage = pInfo->bins[k].count / (double)pInfo->totalCount; } else { pInfo->bins[k].percentage = 0; } } } for (int32_t i = 0; i < pResInfo->numOfRes; ++i) { int32_t len; char buf[512] = {0}; if (!pInfo->normalized) { len = sprintf(varDataVal(buf), "{\"lower_bin\":%g, \"upper_bin\":%g, \"count\":%" PRId64 "}", pInfo->bins[i].lower, pInfo->bins[i].upper, pInfo->bins[i].count); } else { len = sprintf(varDataVal(buf), "{\"lower_bin\":%g, \"upper_bin\":%g, \"count\":%lf}", pInfo->bins[i].lower, pInfo->bins[i].upper, pInfo->bins[i].percentage); } varDataSetLen(buf, len); colDataAppend(pCol, currentRow, buf, false); currentRow++; } return pResInfo->numOfRes; } int32_t histogramPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SHistoFuncInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t resultBytes = getHistogramInfoSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } int32_t histogramCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SHistoFuncInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SHistoFuncInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); histogramTransferInfo(pSBuf, pDBuf); pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } int32_t getHLLInfoSize() { return (int32_t)sizeof(SHLLInfo); } bool getHLLFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SHLLInfo); return true; } static uint8_t hllCountNum(void* data, int32_t bytes, int32_t* buk) { uint64_t hash = MurmurHash3_64(data, bytes); int32_t index = hash & HLL_BUCKET_MASK; hash >>= HLL_BUCKET_BITS; hash |= ((uint64_t)1 << HLL_DATA_BITS); uint64_t bit = 1; uint8_t count = 1; while ((hash & bit) == 0) { count++; bit <<= 1; } *buk = index; return count; } static void hllBucketHisto(uint8_t* buckets, int32_t* bucketHisto) { uint64_t* word = (uint64_t*)buckets; uint8_t* bytes; for (int32_t j = 0; j < HLL_BUCKETS >> 3; j++) { if (*word == 0) { bucketHisto[0] += 8; } else { bytes = (uint8_t*)word; bucketHisto[bytes[0]]++; bucketHisto[bytes[1]]++; bucketHisto[bytes[2]]++; bucketHisto[bytes[3]]++; bucketHisto[bytes[4]]++; bucketHisto[bytes[5]]++; bucketHisto[bytes[6]]++; bucketHisto[bytes[7]]++; } word++; } } static double hllTau(double x) { if (x == 0. || x == 1.) return 0.; double zPrime; double y = 1.0; double z = 1 - x; do { x = sqrt(x); zPrime = z; y *= 0.5; z -= pow(1 - x, 2) * y; } while (zPrime != z); return z / 3; } static double hllSigma(double x) { if (x == 1.0) return INFINITY; double zPrime; double y = 1; double z = x; do { x *= x; zPrime = z; z += x * y; y += y; } while (zPrime != z); return z; } // estimate the cardinality, the algorithm refer this paper: "New cardinality estimation algorithms for HyperLogLog // sketches" static uint64_t hllCountCnt(uint8_t* buckets) { double m = HLL_BUCKETS; int32_t buckethisto[64] = {0}; hllBucketHisto(buckets, buckethisto); double z = m * hllTau((m - buckethisto[HLL_DATA_BITS + 1]) / (double)m); for (int j = HLL_DATA_BITS; j >= 1; --j) { z += buckethisto[j]; z *= 0.5; } z += m * hllSigma(buckethisto[0] / (double)m); double E = (double)llroundl(HLL_ALPHA_INF * m * m / z); return (uint64_t)E; } int32_t hllFunction(SqlFunctionCtx* pCtx) { SHLLInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; int32_t type = pCol->info.type; int32_t bytes = pCol->info.bytes; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; int32_t numOfElems = 0; for (int32_t i = start; i < numOfRows + start; ++i) { if (pCol->hasNull && colDataIsNull_s(pCol, i)) { continue; } numOfElems++; char* data = colDataGetData(pCol, i); if (IS_VAR_DATA_TYPE(type)) { bytes = varDataLen(data); data = varDataVal(data); } int32_t index = 0; uint8_t count = hllCountNum(data, bytes, &index); uint8_t oldcount = pInfo->buckets[index]; if (count > oldcount) { pInfo->buckets[index] = count; } } pInfo->totalCount += numOfElems; if (pInfo->totalCount == 0 && !tsCountAlwaysReturnValue) { SET_VAL(GET_RES_INFO(pCtx), 0, 1); } else { SET_VAL(GET_RES_INFO(pCtx), 1, 1); } return TSDB_CODE_SUCCESS; } static void hllTransferInfo(SHLLInfo* pInput, SHLLInfo* pOutput) { for (int32_t k = 0; k < HLL_BUCKETS; ++k) { if (pOutput->buckets[k] < pInput->buckets[k]) { pOutput->buckets[k] = pInput->buckets[k]; } } pOutput->totalCount += pInput->totalCount; } int32_t hllFunctionMerge(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pCol = pInput->pData[0]; ASSERT(pCol->info.type == TSDB_DATA_TYPE_BINARY); SHLLInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t start = pInput->startRowIndex; for (int32_t i = start; i < start + pInput->numOfRows; ++i) { char* data = colDataGetData(pCol, i); SHLLInfo* pInputInfo = (SHLLInfo*)varDataVal(data); hllTransferInfo(pInputInfo, pInfo); } if (pInfo->totalCount == 0 && !tsCountAlwaysReturnValue) { SET_VAL(GET_RES_INFO(pCtx), 0, 1); } else { SET_VAL(GET_RES_INFO(pCtx), 1, 1); } return TSDB_CODE_SUCCESS; } int32_t hllFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pInfo = GET_RES_INFO(pCtx); SHLLInfo* pHllInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); pHllInfo->result = hllCountCnt(pHllInfo->buckets); if (tsCountAlwaysReturnValue && pHllInfo->result == 0) { pInfo->numOfRes = 1; } return functionFinalize(pCtx, pBlock); } int32_t hllPartialFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SHLLInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); int32_t resultBytes = getHLLInfoSize(); char* res = taosMemoryCalloc(resultBytes + VARSTR_HEADER_SIZE, sizeof(char)); memcpy(varDataVal(res), pInfo, resultBytes); varDataSetLen(res, resultBytes); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); colDataAppend(pCol, pBlock->info.rows, res, false); taosMemoryFree(res); return pResInfo->numOfRes; } int32_t hllCombine(SqlFunctionCtx* pDestCtx, SqlFunctionCtx* pSourceCtx) { SResultRowEntryInfo* pDResInfo = GET_RES_INFO(pDestCtx); SHLLInfo* pDBuf = GET_ROWCELL_INTERBUF(pDResInfo); SResultRowEntryInfo* pSResInfo = GET_RES_INFO(pSourceCtx); SHLLInfo* pSBuf = GET_ROWCELL_INTERBUF(pSResInfo); hllTransferInfo(pSBuf, pDBuf); pDResInfo->numOfRes = TMAX(pDResInfo->numOfRes, pSResInfo->numOfRes); pDResInfo->isNullRes &= pSResInfo->isNullRes; return TSDB_CODE_SUCCESS; } bool getStateFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SStateInfo); return true; } static int8_t getStateOpType(char* opStr) { int8_t opType; if (strncasecmp(opStr, "LT", 2) == 0) { opType = STATE_OPER_LT; } else if (strncasecmp(opStr, "GT", 2) == 0) { opType = STATE_OPER_GT; } else if (strncasecmp(opStr, "LE", 2) == 0) { opType = STATE_OPER_LE; } else if (strncasecmp(opStr, "GE", 2) == 0) { opType = STATE_OPER_GE; } else if (strncasecmp(opStr, "NE", 2) == 0) { opType = STATE_OPER_NE; } else if (strncasecmp(opStr, "EQ", 2) == 0) { opType = STATE_OPER_EQ; } else { opType = STATE_OPER_INVALID; } return opType; } static bool checkStateOp(int8_t op, SColumnInfoData* pCol, int32_t index, SVariant param) { char* data = colDataGetData(pCol, index); switch (pCol->info.type) { case TSDB_DATA_TYPE_TINYINT: { int8_t v = *(int8_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_UTINYINT: { uint8_t v = *(uint8_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t v = *(int16_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_USMALLINT: { uint16_t v = *(uint16_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_INT: { int32_t v = *(int32_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_UINT: { uint32_t v = *(uint32_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_BIGINT: { int64_t v = *(int64_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_UBIGINT: { uint64_t v = *(uint64_t*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_FLOAT: { float v = *(float*)data; STATE_COMP(op, v, param); break; } case TSDB_DATA_TYPE_DOUBLE: { double v = *(double*)data; STATE_COMP(op, v, param); break; } default: { ASSERT(0); } } return false; } int32_t stateCountFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SStateInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t numOfElems = 0; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; int8_t op = getStateOpType(varDataVal(pCtx->param[1].param.pz)); if (STATE_OPER_INVALID == op) { return 0; } for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { numOfElems++; if (colDataIsNull_f(pInputCol->nullbitmap, i)) { colDataAppendNULL(pOutput, i); // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pCtx->offset + numOfElems - 1); } continue; } bool ret = checkStateOp(op, pInputCol, i, pCtx->param[2].param); int64_t output = -1; if (ret) { output = ++pInfo->count; } else { pInfo->count = 0; } colDataAppend(pOutput, pCtx->offset + numOfElems - 1, (char*)&output, false); // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pCtx->offset + numOfElems - 1); } } return numOfElems; } int32_t stateDurationFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SStateInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; TSKEY* tsList = (int64_t*)pInput->pPTS->pData; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t numOfElems = 0; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; // TODO: process timeUnit for different db precisions int32_t timeUnit = 1; if (pCtx->numOfParams == 5) { // TODO: param number incorrect timeUnit = pCtx->param[3].param.i; } int8_t op = getStateOpType(varDataVal(pCtx->param[1].param.pz)); if (STATE_OPER_INVALID == op) { return 0; } for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { numOfElems++; if (colDataIsNull_f(pInputCol->nullbitmap, i)) { colDataAppendNULL(pOutput, i); // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pCtx->offset + numOfElems - 1); } continue; } bool ret = checkStateOp(op, pInputCol, i, pCtx->param[2].param); int64_t output = -1; if (ret) { if (pInfo->durationStart == 0) { output = 0; pInfo->durationStart = tsList[i]; } else { output = (tsList[i] - pInfo->durationStart) / timeUnit; } } else { pInfo->durationStart = 0; } colDataAppend(pOutput, pCtx->offset + numOfElems - 1, (char*)&output, false); // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pCtx->offset + numOfElems - 1); } } return numOfElems; } bool getCsumFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SSumRes); return true; } int32_t csumFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SSumRes* pSumRes = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; int32_t numOfElems = 0; int32_t type = pInputCol->info.type; int32_t startOffset = pCtx->offset; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { int32_t pos = startOffset + numOfElems; if (colDataIsNull_f(pInputCol->nullbitmap, i)) { // colDataAppendNULL(pOutput, i); continue; } char* data = colDataGetData(pInputCol, i); if (IS_SIGNED_NUMERIC_TYPE(type)) { int64_t v; GET_TYPED_DATA(v, int64_t, type, data); pSumRes->isum += v; colDataAppend(pOutput, pos, (char*)&pSumRes->isum, false); } else if (IS_UNSIGNED_NUMERIC_TYPE(type)) { uint64_t v; GET_TYPED_DATA(v, uint64_t, type, data); pSumRes->usum += v; colDataAppend(pOutput, pos, (char*)&pSumRes->usum, false); } else if (IS_FLOAT_TYPE(type)) { double v; GET_TYPED_DATA(v, double, type, data); pSumRes->dsum += v; // check for overflow if (isinf(pSumRes->dsum) || isnan(pSumRes->dsum)) { colDataAppendNULL(pOutput, pos); } else { colDataAppend(pOutput, pos, (char*)&pSumRes->dsum, false); } } // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pos); } numOfElems++; } return numOfElems; } bool getMavgFuncEnv(SFunctionNode* UNUSED_PARAM(pFunc), SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SMavgInfo) + MAVG_MAX_POINTS_NUM * sizeof(double); return true; } bool mavgFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } SMavgInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); pInfo->pos = 0; pInfo->sum = 0; pInfo->numOfPoints = pCtx->param[1].param.i; if (pInfo->numOfPoints < 1 || pInfo->numOfPoints > MAVG_MAX_POINTS_NUM) { return false; } pInfo->pointsMeet = false; return true; } int32_t mavgFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SMavgInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; SColumnInfoData* pTsOutput = pCtx->pTsOutput; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; int32_t numOfElems = 0; int32_t type = pInputCol->info.type; int32_t startOffset = pCtx->offset; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { int32_t pos = startOffset + numOfElems; if (colDataIsNull_f(pInputCol->nullbitmap, i)) { // colDataAppendNULL(pOutput, i); continue; } char* data = colDataGetData(pInputCol, i); double v; GET_TYPED_DATA(v, double, type, data); if (!pInfo->pointsMeet && (pInfo->pos < pInfo->numOfPoints - 1)) { pInfo->points[pInfo->pos] = v; pInfo->sum += v; } else { if (!pInfo->pointsMeet && (pInfo->pos == pInfo->numOfPoints - 1)) { pInfo->sum += v; pInfo->pointsMeet = true; } else { pInfo->sum = pInfo->sum + v - pInfo->points[pInfo->pos]; } pInfo->points[pInfo->pos] = v; double result = pInfo->sum / pInfo->numOfPoints; // check for overflow if (isinf(result) || isnan(result)) { colDataAppendNULL(pOutput, pos); } else { colDataAppend(pOutput, pos, (char*)&result, false); } // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pos); } numOfElems++; } pInfo->pos++; if (pInfo->pos == pInfo->numOfPoints) { pInfo->pos = 0; } } return numOfElems; } static SSampleInfo* getSampleOutputInfo(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SSampleInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); pInfo->data = (char*)pInfo + sizeof(SSampleInfo); pInfo->tuplePos = (STuplePos*)((char*)pInfo + sizeof(SSampleInfo) + pInfo->samples * pInfo->colBytes); return pInfo; } bool getSampleFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { SColumnNode* pCol = (SColumnNode*)nodesListGetNode(pFunc->pParameterList, 0); SValueNode* pVal = (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1); int32_t numOfSamples = pVal->datum.i; pEnv->calcMemSize = sizeof(SSampleInfo) + numOfSamples * (pCol->node.resType.bytes + sizeof(STuplePos)); return true; } bool sampleFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } taosSeedRand(taosSafeRand()); SSampleInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); pInfo->samples = pCtx->param[1].param.i; pInfo->totalPoints = 0; pInfo->numSampled = 0; pInfo->colType = pCtx->resDataInfo.type; pInfo->colBytes = pCtx->resDataInfo.bytes; pInfo->nullTuplePos.pageId = -1; pInfo->nullTupleSaved = false; pInfo->data = (char*)pInfo + sizeof(SSampleInfo); pInfo->tuplePos = (STuplePos*)((char*)pInfo + sizeof(SSampleInfo) + pInfo->samples * pInfo->colBytes); return true; } static void sampleAssignResult(SSampleInfo* pInfo, char* data, int32_t index) { assignVal(pInfo->data + index * pInfo->colBytes, data, pInfo->colBytes, pInfo->colType); } static void doReservoirSample(SqlFunctionCtx* pCtx, SSampleInfo* pInfo, char* data, int32_t index) { pInfo->totalPoints++; if (pInfo->numSampled < pInfo->samples) { sampleAssignResult(pInfo, data, pInfo->numSampled); if (pCtx->subsidiaries.num > 0) { pInfo->tuplePos[pInfo->numSampled] = saveTupleData(pCtx, index, pCtx->pSrcBlock, NULL); } pInfo->numSampled++; } else { int32_t j = taosRand() % (pInfo->totalPoints); if (j < pInfo->samples) { sampleAssignResult(pInfo, data, j); if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, index, pCtx->pSrcBlock, &pInfo->tuplePos[j]); } } } } int32_t sampleFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SSampleInfo* pInfo = getSampleOutputInfo(pCtx); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_s(pInputCol, i)) { continue; } char* data = colDataGetData(pInputCol, i); doReservoirSample(pCtx, pInfo, data, i); } if (pInfo->numSampled == 0 && pCtx->subsidiaries.num > 0 && !pInfo->nullTupleSaved) { pInfo->nullTuplePos = saveTupleData(pCtx, pInput->startRowIndex, pCtx->pSrcBlock, NULL); pInfo->nullTupleSaved = true; } SET_VAL(pResInfo, pInfo->numSampled, pInfo->numSampled); return TSDB_CODE_SUCCESS; } int32_t sampleFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(pCtx); SSampleInfo* pInfo = getSampleOutputInfo(pCtx); pEntryInfo->complete = true; int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); int32_t currentRow = pBlock->info.rows; if (pInfo->numSampled == 0) { colDataAppendNULL(pCol, currentRow); setSelectivityValue(pCtx, pBlock, &pInfo->nullTuplePos, currentRow); return pInfo->numSampled; } for (int32_t i = 0; i < pInfo->numSampled; ++i) { colDataAppend(pCol, currentRow + i, pInfo->data + i * pInfo->colBytes, false); setSelectivityValue(pCtx, pBlock, &pInfo->tuplePos[i], currentRow + i); } return pInfo->numSampled; } bool getTailFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { #if 0 SColumnNode* pCol = (SColumnNode*)nodesListGetNode(pFunc->pParameterList, 0); SValueNode* pVal = (SValueNode*)nodesListGetNode(pFunc->pParameterList, 1); int32_t numOfPoints = pVal->datum.i; pEnv->calcMemSize = sizeof(STailInfo) + numOfPoints * (POINTER_BYTES + sizeof(STailItem) + pCol->node.resType.bytes); #endif return true; } bool tailFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { #if 0 if (!functionSetup(pCtx, pResultInfo)) { return false; } STailInfo* pInfo = GET_ROWCELL_INTERBUF(pResultInfo); pInfo->numAdded = 0; pInfo->numOfPoints = pCtx->param[1].param.i; if (pCtx->numOfParams == 4) { pInfo->offset = pCtx->param[2].param.i; } else { pInfo->offset = 0; } pInfo->colType = pCtx->resDataInfo.type; pInfo->colBytes = pCtx->resDataInfo.bytes; if ((pInfo->numOfPoints < 1 || pInfo->numOfPoints > TAIL_MAX_POINTS_NUM) || (pInfo->numOfPoints < 0 || pInfo->numOfPoints > TAIL_MAX_OFFSET)) { return false; } pInfo->pItems = (STailItem**)((char*)pInfo + sizeof(STailInfo)); char* pItem = (char*)pInfo->pItems + pInfo->numOfPoints * POINTER_BYTES; size_t unitSize = sizeof(STailItem) + pInfo->colBytes; for (int32_t i = 0; i < pInfo->numOfPoints; ++i) { pInfo->pItems[i] = (STailItem*)(pItem + i * unitSize); pInfo->pItems[i]->isNull = false; } #endif return true; } static void tailAssignResult(STailItem* pItem, char* data, int32_t colBytes, TSKEY ts, bool isNull) { #if 0 pItem->timestamp = ts; if (isNull) { pItem->isNull = true; } else { pItem->isNull = false; memcpy(pItem->data, data, colBytes); } #endif } #if 0 static int32_t tailCompFn(const void* p1, const void* p2, const void* param) { STailItem* d1 = *(STailItem**)p1; STailItem* d2 = *(STailItem**)p2; return compareInt64Val(&d1->timestamp, &d2->timestamp); } static void doTailAdd(STailInfo* pInfo, char* data, TSKEY ts, bool isNull) { STailItem** pList = pInfo->pItems; if (pInfo->numAdded < pInfo->numOfPoints) { tailAssignResult(pList[pInfo->numAdded], data, pInfo->colBytes, ts, isNull); taosheapsort((void*)pList, sizeof(STailItem**), pInfo->numAdded + 1, NULL, tailCompFn, 0); pInfo->numAdded++; } else if (pList[0]->timestamp < ts) { tailAssignResult(pList[0], data, pInfo->colBytes, ts, isNull); taosheapadjust((void*)pList, sizeof(STailItem**), 0, pInfo->numOfPoints - 1, NULL, tailCompFn, NULL, 0); } } #endif int32_t tailFunction(SqlFunctionCtx* pCtx) { #if 0 SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); STailInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; TSKEY* tsList = (int64_t*)pInput->pPTS->pData; SColumnInfoData* pInputCol = pInput->pData[0]; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; int32_t startOffset = pCtx->offset; if (pInfo->offset >= pInput->numOfRows) { return 0; } else { pInfo->numOfPoints = TMIN(pInfo->numOfPoints, pInput->numOfRows - pInfo->offset); } for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex - pInfo->offset; i += 1) { char* data = colDataGetData(pInputCol, i); doTailAdd(pInfo, data, tsList[i], colDataIsNull_s(pInputCol, i)); } taosqsort(pInfo->pItems, pInfo->numOfPoints, POINTER_BYTES, NULL, tailCompFn); for (int32_t i = 0; i < pInfo->numOfPoints; ++i) { int32_t pos = startOffset + i; STailItem* pItem = pInfo->pItems[i]; if (pItem->isNull) { colDataAppendNULL(pOutput, pos); } else { colDataAppend(pOutput, pos, pItem->data, false); } } return pInfo->numOfPoints; #endif return 0; } int32_t tailFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { #if 0 SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(pCtx); STailInfo* pInfo = GET_ROWCELL_INTERBUF(pEntryInfo); pEntryInfo->complete = true; int32_t type = pCtx->input.pData[0]->info.type; int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); // todo assign the tag value and the corresponding row data int32_t currentRow = pBlock->info.rows; for (int32_t i = 0; i < pEntryInfo->numOfRes; ++i) { STailItem* pItem = pInfo->pItems[i]; colDataAppend(pCol, currentRow, pItem->data, false); currentRow += 1; } return pEntryInfo->numOfRes; #endif return 0; } bool getUniqueFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { #if 0 pEnv->calcMemSize = sizeof(SUniqueInfo) + UNIQUE_MAX_RESULT_SIZE; #endif return true; } bool uniqueFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResInfo) { #if 0 if (!functionSetup(pCtx, pResInfo)) { return false; } SUniqueInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); pInfo->numOfPoints = 0; pInfo->colType = pCtx->resDataInfo.type; pInfo->colBytes = pCtx->resDataInfo.bytes; if (pInfo->pHash != NULL) { taosHashClear(pInfo->pHash); } else { pInfo->pHash = taosHashInit(64, taosGetDefaultHashFunction(TSDB_DATA_TYPE_BINARY), true, HASH_NO_LOCK); } #endif return true; } #if 0 static void doUniqueAdd(SUniqueInfo* pInfo, char* data, TSKEY ts, bool isNull) { // handle null elements if (isNull == true) { int32_t size = sizeof(SUniqueItem) + pInfo->colBytes; SUniqueItem* pItem = (SUniqueItem*)(pInfo->pItems + pInfo->numOfPoints * size); if (pInfo->hasNull == false && pItem->isNull == false) { pItem->timestamp = ts; pItem->isNull = true; pInfo->numOfPoints++; pInfo->hasNull = true; } else if (pItem->timestamp > ts && pItem->isNull == true) { pItem->timestamp = ts; } return; } int32_t hashKeyBytes = IS_VAR_DATA_TYPE(pInfo->colType) ? varDataTLen(data) : pInfo->colBytes; SUniqueItem* pHashItem = taosHashGet(pInfo->pHash, data, hashKeyBytes); if (pHashItem == NULL) { int32_t size = sizeof(SUniqueItem) + pInfo->colBytes; SUniqueItem* pItem = (SUniqueItem*)(pInfo->pItems + pInfo->numOfPoints * size); pItem->timestamp = ts; memcpy(pItem->data, data, pInfo->colBytes); taosHashPut(pInfo->pHash, data, hashKeyBytes, (char*)pItem, sizeof(SUniqueItem*)); pInfo->numOfPoints++; } else if (pHashItem->timestamp > ts) { pHashItem->timestamp = ts; } } #endif int32_t uniqueFunction(SqlFunctionCtx* pCtx) { #if 0 SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SUniqueInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; TSKEY* tsList = (int64_t*)pInput->pPTS->pData; SColumnInfoData* pInputCol = pInput->pData[0]; SColumnInfoData* pTsOutput = pCtx->pTsOutput; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; int32_t startOffset = pCtx->offset; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; ++i) { char* data = colDataGetData(pInputCol, i); doUniqueAdd(pInfo, data, tsList[i], colDataIsNull_s(pInputCol, i)); if (sizeof(SUniqueInfo) + pInfo->numOfPoints * (sizeof(SUniqueItem) + pInfo->colBytes) >= UNIQUE_MAX_RESULT_SIZE) { taosHashCleanup(pInfo->pHash); return 0; } } for (int32_t i = 0; i < pInfo->numOfPoints; ++i) { SUniqueItem* pItem = (SUniqueItem*)(pInfo->pItems + i * (sizeof(SUniqueItem) + pInfo->colBytes)); if (pItem->isNull == true) { colDataAppendNULL(pOutput, i); } else { colDataAppend(pOutput, i, pItem->data, false); } if (pTsOutput != NULL) { colDataAppendInt64(pTsOutput, i, &pItem->timestamp); } } return pInfo->numOfPoints; #endif return 0; } bool getModeFuncEnv(SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SModeInfo) + MODE_MAX_RESULT_SIZE; return true; } bool modeFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResInfo) { if (!functionSetup(pCtx, pResInfo)) { return false; } SModeInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); pInfo->numOfPoints = 0; pInfo->colType = pCtx->resDataInfo.type; pInfo->colBytes = pCtx->resDataInfo.bytes; if (pInfo->pHash != NULL) { taosHashClear(pInfo->pHash); } else { pInfo->pHash = taosHashInit(64, taosGetDefaultHashFunction(TSDB_DATA_TYPE_BINARY), true, HASH_NO_LOCK); } pInfo->nullTupleSaved = false; pInfo->nullTuplePos.pageId = -1; return true; } static void doModeAdd(SModeInfo* pInfo, int32_t rowIndex, SqlFunctionCtx* pCtx, char* data) { int32_t hashKeyBytes = IS_STR_DATA_TYPE(pInfo->colType) ? varDataTLen(data) : pInfo->colBytes; SModeItem** pHashItem = taosHashGet(pInfo->pHash, data, hashKeyBytes); if (pHashItem == NULL) { int32_t size = sizeof(SModeItem) + pInfo->colBytes; SModeItem* pItem = (SModeItem*)(pInfo->pItems + pInfo->numOfPoints * size); memcpy(pItem->data, data, hashKeyBytes); pItem->count += 1; if (pCtx->subsidiaries.num > 0) { pItem->tuplePos = saveTupleData(pCtx, rowIndex, pCtx->pSrcBlock, NULL); } taosHashPut(pInfo->pHash, data, hashKeyBytes, &pItem, sizeof(SModeItem*)); pInfo->numOfPoints++; } else { (*pHashItem)->count += 1; if (pCtx->subsidiaries.num > 0) { updateTupleData(pCtx, rowIndex, pCtx->pSrcBlock, &((*pHashItem)->tuplePos)); } } } int32_t modeFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SModeInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; int32_t numOfElems = 0; int32_t startOffset = pCtx->offset; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; ++i) { char* data = colDataGetData(pInputCol, i); if (colDataIsNull_s(pInputCol, i)) { continue; } numOfElems++; doModeAdd(pInfo, i, pCtx, data); if (sizeof(SModeInfo) + pInfo->numOfPoints * (sizeof(SModeItem) + pInfo->colBytes) >= MODE_MAX_RESULT_SIZE) { taosHashCleanup(pInfo->pHash); return TSDB_CODE_OUT_OF_MEMORY; } } if (numOfElems == 0 && pCtx->subsidiaries.num > 0 && !pInfo->nullTupleSaved) { pInfo->nullTuplePos = saveTupleData(pCtx, pInput->startRowIndex, pCtx->pSrcBlock, NULL); pInfo->nullTupleSaved = true; } SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; } int32_t modeFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SModeInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); int32_t currentRow = pBlock->info.rows; int32_t resIndex = -1; int32_t maxCount = 0; for (int32_t i = 0; i < pInfo->numOfPoints; ++i) { SModeItem* pItem = (SModeItem*)(pInfo->pItems + i * (sizeof(SModeItem) + pInfo->colBytes)); if (pItem->count >= maxCount) { maxCount = pItem->count; resIndex = i; } } if (maxCount != 0) { SModeItem* pResItem = (SModeItem*)(pInfo->pItems + resIndex * (sizeof(SModeItem) + pInfo->colBytes)); colDataAppend(pCol, currentRow, pResItem->data, false); setSelectivityValue(pCtx, pBlock, &pResItem->tuplePos, currentRow); } else { colDataAppendNULL(pCol, currentRow); setSelectivityValue(pCtx, pBlock, &pInfo->nullTuplePos, currentRow); } taosHashCleanup(pInfo->pHash); return pResInfo->numOfRes; } bool getTwaFuncEnv(struct SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(STwaInfo); return true; } bool twaFunctionSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } STwaInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); pInfo->isNull = false; pInfo->p.key = INT64_MIN; pInfo->win = TSWINDOW_INITIALIZER; return true; } static double twa_get_area(SPoint1 s, SPoint1 e) { if ((s.val >= 0 && e.val >= 0) || (s.val <= 0 && e.val <= 0)) { return (s.val + e.val) * (e.key - s.key) / 2; } double x = (s.key * e.val - e.key * s.val) / (e.val - s.val); double val = (s.val * (x - s.key) + e.val * (e.key - x)) / 2; return val; } int32_t twaFunction(SqlFunctionCtx* pCtx) { SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; TSKEY* tsList = (int64_t*)pInput->pPTS->pData; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); STwaInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SPoint1* last = &pInfo->p; int32_t numOfElems = 0; if (IS_NULL_TYPE(pInputCol->info.type)) { pInfo->isNull = true; goto _twa_over; } int32_t i = pInput->startRowIndex; if (pCtx->start.key != INT64_MIN) { // ASSERT((pCtx->start.key < tsList[i] && pCtx->order == TSDB_ORDER_ASC) || // (pCtx->start.key > tsList[i] && pCtx->order == TSDB_ORDER_DESC)); ASSERT(last->key == INT64_MIN); for (; i < pInput->numOfRows + pInput->startRowIndex; ++i) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } last->key = tsList[i]; GET_TYPED_DATA(last->val, double, pInputCol->info.type, colDataGetData(pInputCol, i)); pInfo->dOutput += twa_get_area(pCtx->start, *last); pInfo->win.skey = pCtx->start.key; numOfElems++; i += 1; break; } } else if (pInfo->p.key == INT64_MIN) { for (; i < pInput->numOfRows + pInput->startRowIndex; ++i) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } last->key = tsList[i]; GET_TYPED_DATA(last->val, double, pInputCol->info.type, colDataGetData(pInputCol, i)); pInfo->win.skey = last->key; numOfElems++; i += 1; break; } } SPoint1 st = {0}; // calculate the value of switch (pInputCol->info.type) { case TSDB_DATA_TYPE_TINYINT: { int8_t* val = (int8_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_SMALLINT: { int16_t* val = (int16_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_INT: { int32_t* val = (int32_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_BIGINT: { int64_t* val = (int64_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_FLOAT: { float* val = (float*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_DOUBLE: { double* val = (double*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_UTINYINT: { uint8_t* val = (uint8_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_USMALLINT: { uint16_t* val = (uint16_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_UINT: { uint32_t* val = (uint32_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } case TSDB_DATA_TYPE_UBIGINT: { uint64_t* val = (uint64_t*)colDataGetData(pInputCol, 0); for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; INIT_INTP_POINT(st, tsList[i], val[i]); if (pInfo->p.key == st.key) { return TSDB_CODE_FUNC_DUP_TIMESTAMP; } pInfo->dOutput += twa_get_area(pInfo->p, st); pInfo->p = st; } break; } default: ASSERT(0); } // the last interpolated time window value if (pCtx->end.key != INT64_MIN) { pInfo->dOutput += twa_get_area(pInfo->p, pCtx->end); pInfo->p = pCtx->end; numOfElems += 1; } pInfo->win.ekey = pInfo->p.key; _twa_over: if (numOfElems == 0) { pInfo->isNull = true; } SET_VAL(pResInfo, 1, 1); return TSDB_CODE_SUCCESS; } /* * To copy the input to interResBuf to avoid the input buffer space be over writen * by next input data. The TWA function only applies to each table, so no merge procedure * is required, we simply copy to the resut ot interResBuffer. */ // void twa_function_copy(SQLFunctionCtx *pCtx) { // assert(pCtx->inputType == TSDB_DATA_TYPE_BINARY); // SResultRowEntryInfo *pResInfo = GET_RES_INFO(pCtx); // // memcpy(GET_ROWCELL_INTERBUF(pResInfo), pCtx->pInput, (size_t)pCtx->inputBytes); // pResInfo->hasResult = ((STwaInfo *)pCtx->pInput)->hasResult; // } int32_t twaFinalize(struct SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); STwaInfo* pInfo = (STwaInfo*)GET_ROWCELL_INTERBUF(pResInfo); if (pInfo->isNull == true) { pResInfo->numOfRes = 0; } else { if (pInfo->win.ekey == pInfo->win.skey) { pInfo->dOutput = pInfo->p.val; } else { pInfo->dOutput = pInfo->dOutput / (pInfo->win.ekey - pInfo->win.skey); } pResInfo->numOfRes = 1; } return functionFinalize(pCtx, pBlock); } bool blockDistSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResultInfo) { if (!functionSetup(pCtx, pResultInfo)) { return false; } STableBlockDistInfo* pInfo = GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); pInfo->minRows = INT32_MAX; return true; } int32_t blockDistFunction(SqlFunctionCtx* pCtx) { const int32_t BLOCK_DIST_RESULT_ROWS = 24; SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); STableBlockDistInfo* pDistInfo = GET_ROWCELL_INTERBUF(pResInfo); STableBlockDistInfo p1 = {0}; tDeserializeBlockDistInfo(varDataVal(pInputCol->pData), varDataLen(pInputCol->pData), &p1); pDistInfo->numOfBlocks += p1.numOfBlocks; pDistInfo->numOfTables += p1.numOfTables; pDistInfo->numOfInmemRows += p1.numOfInmemRows; pDistInfo->totalSize += p1.totalSize; pDistInfo->totalRows += p1.totalRows; pDistInfo->numOfFiles += p1.numOfFiles; pDistInfo->defMinRows = p1.defMinRows; pDistInfo->defMaxRows = p1.defMaxRows; pDistInfo->rowSize = p1.rowSize; pDistInfo->numOfSmallBlocks = p1.numOfSmallBlocks; if (pDistInfo->minRows > p1.minRows) { pDistInfo->minRows = p1.minRows; } if (pDistInfo->maxRows < p1.maxRows) { pDistInfo->maxRows = p1.maxRows; } for (int32_t i = 0; i < tListLen(pDistInfo->blockRowsHisto); ++i) { pDistInfo->blockRowsHisto[i] += p1.blockRowsHisto[i]; } pResInfo->numOfRes = BLOCK_DIST_RESULT_ROWS; // default output rows return TSDB_CODE_SUCCESS; } int32_t tSerializeBlockDistInfo(void* buf, int32_t bufLen, const STableBlockDistInfo* pInfo) { SEncoder encoder = {0}; tEncoderInit(&encoder, buf, bufLen); if (tStartEncode(&encoder) < 0) return -1; if (tEncodeU32(&encoder, pInfo->rowSize) < 0) return -1; if (tEncodeU16(&encoder, pInfo->numOfFiles) < 0) return -1; if (tEncodeU32(&encoder, pInfo->numOfBlocks) < 0) return -1; if (tEncodeU32(&encoder, pInfo->numOfTables) < 0) return -1; if (tEncodeU64(&encoder, pInfo->totalSize) < 0) return -1; if (tEncodeU64(&encoder, pInfo->totalRows) < 0) return -1; if (tEncodeI32(&encoder, pInfo->maxRows) < 0) return -1; if (tEncodeI32(&encoder, pInfo->minRows) < 0) return -1; if (tEncodeI32(&encoder, pInfo->defMaxRows) < 0) return -1; if (tEncodeI32(&encoder, pInfo->defMinRows) < 0) return -1; if (tEncodeU32(&encoder, pInfo->numOfInmemRows) < 0) return -1; if (tEncodeU32(&encoder, pInfo->numOfSmallBlocks) < 0) return -1; for (int32_t i = 0; i < tListLen(pInfo->blockRowsHisto); ++i) { if (tEncodeI32(&encoder, pInfo->blockRowsHisto[i]) < 0) return -1; } tEndEncode(&encoder); int32_t tlen = encoder.pos; tEncoderClear(&encoder); return tlen; } int32_t tDeserializeBlockDistInfo(void* buf, int32_t bufLen, STableBlockDistInfo* pInfo) { SDecoder decoder = {0}; tDecoderInit(&decoder, buf, bufLen); if (tStartDecode(&decoder) < 0) return -1; if (tDecodeU32(&decoder, &pInfo->rowSize) < 0) return -1; if (tDecodeU16(&decoder, &pInfo->numOfFiles) < 0) return -1; if (tDecodeU32(&decoder, &pInfo->numOfBlocks) < 0) return -1; if (tDecodeU32(&decoder, &pInfo->numOfTables) < 0) return -1; if (tDecodeU64(&decoder, &pInfo->totalSize) < 0) return -1; if (tDecodeU64(&decoder, &pInfo->totalRows) < 0) return -1; if (tDecodeI32(&decoder, &pInfo->maxRows) < 0) return -1; if (tDecodeI32(&decoder, &pInfo->minRows) < 0) return -1; if (tDecodeI32(&decoder, &pInfo->defMaxRows) < 0) return -1; if (tDecodeI32(&decoder, &pInfo->defMinRows) < 0) return -1; if (tDecodeU32(&decoder, &pInfo->numOfInmemRows) < 0) return -1; if (tDecodeU32(&decoder, &pInfo->numOfSmallBlocks) < 0) return -1; for (int32_t i = 0; i < tListLen(pInfo->blockRowsHisto); ++i) { if (tDecodeI32(&decoder, &pInfo->blockRowsHisto[i]) < 0) return -1; } tDecoderClear(&decoder); return 0; } int32_t blockDistFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); STableBlockDistInfo* pData = GET_ROWCELL_INTERBUF(pResInfo); SColumnInfoData* pColInfo = taosArrayGet(pBlock->pDataBlock, 0); if (pData->totalRows == 0) { pData->minRows = 0; } int32_t row = 0; char st[256] = {0}; double totalRawSize = pData->totalRows * pData->rowSize; int32_t len = sprintf(st + VARSTR_HEADER_SIZE, "Total_Blocks=[%d] Total_Size=[%.2f Kb] Average_size=[%.2f Kb] Compression_Ratio=[%.2f %c]", pData->numOfBlocks, pData->totalSize / 1024.0, ((double)pData->totalSize) / pData->numOfBlocks, pData->totalSize * 100 / totalRawSize, '%'); varDataSetLen(st, len); colDataAppend(pColInfo, row++, st, false); int64_t avgRows = 0; if (pData->numOfBlocks > 0) { avgRows = pData->totalRows / pData->numOfBlocks; } len = sprintf(st + VARSTR_HEADER_SIZE, "Total_Rows=[%" PRId64 "] Inmem_Rows=[%d] MinRows=[%d] MaxRows=[%d] Average_Rows=[%" PRId64 "]", pData->totalRows, pData->numOfInmemRows, pData->minRows, pData->maxRows, avgRows); varDataSetLen(st, len); colDataAppend(pColInfo, row++, st, false); len = sprintf(st + VARSTR_HEADER_SIZE, "Total_Tables=[%d] Total_Files=[%d] Total_Vgroups=[%d]", pData->numOfTables, pData->numOfFiles, 0); varDataSetLen(st, len); colDataAppend(pColInfo, row++, st, false); len = sprintf(st + VARSTR_HEADER_SIZE, "--------------------------------------------------------------------------------"); varDataSetLen(st, len); colDataAppend(pColInfo, row++, st, false); int32_t maxVal = 0; int32_t minVal = INT32_MAX; for (int32_t i = 0; i < tListLen(pData->blockRowsHisto); ++i) { if (maxVal < pData->blockRowsHisto[i]) { maxVal = pData->blockRowsHisto[i]; } if (minVal > pData->blockRowsHisto[i]) { minVal = pData->blockRowsHisto[i]; } } // maximum number of step is 80 double factor = pData->numOfBlocks / 80.0; int32_t numOfBuckets = sizeof(pData->blockRowsHisto) / sizeof(pData->blockRowsHisto[0]); int32_t bucketRange = (pData->defMaxRows - pData->defMinRows) / numOfBuckets; for (int32_t i = 0; i < tListLen(pData->blockRowsHisto); ++i) { len = sprintf(st + VARSTR_HEADER_SIZE, "%04d |", pData->defMinRows + bucketRange * i); int32_t num = 0; if (pData->blockRowsHisto[i] > 0) { num = (pData->blockRowsHisto[i]) / factor; } for (int32_t j = 0; j < num; ++j) { int32_t x = sprintf(st + VARSTR_HEADER_SIZE + len, "%c", '|'); len += x; } if (num > 0) { double v = pData->blockRowsHisto[i] * 100.0 / pData->numOfBlocks; len += sprintf(st + VARSTR_HEADER_SIZE + len, " %d (%.2f%c)", pData->blockRowsHisto[i], v, '%'); } varDataSetLen(st, len); colDataAppend(pColInfo, row++, st, false); } return TSDB_CODE_SUCCESS; } bool getDerivativeFuncEnv(struct SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SDerivInfo); return true; } bool derivativeFuncSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResInfo) { if (!functionSetup(pCtx, pResInfo)) { return false; // not initialized since it has been initialized } SDerivInfo* pDerivInfo = GET_ROWCELL_INTERBUF(pResInfo); pDerivInfo->ignoreNegative = pCtx->param[2].param.i; pDerivInfo->prevTs = -1; pDerivInfo->tsWindow = pCtx->param[1].param.i; pDerivInfo->valueSet = false; return true; } int32_t derivativeFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SDerivInfo* pDerivInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t numOfElems = 0; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; SColumnInfoData* pTsOutput = pCtx->pTsOutput; int32_t i = pInput->startRowIndex; TSKEY* tsList = (int64_t*)pInput->pPTS->pData; double v = 0; if (pCtx->order == TSDB_ORDER_ASC) { for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } char* d = (char*)pInputCol->pData + pInputCol->info.bytes * i; GET_TYPED_DATA(v, double, pInputCol->info.type, d); int32_t pos = pCtx->offset + numOfElems; if (!pDerivInfo->valueSet) { // initial value is not set yet pDerivInfo->valueSet = true; } else { double r = ((v - pDerivInfo->prevValue) * pDerivInfo->tsWindow) / (tsList[i] - pDerivInfo->prevTs); if (pDerivInfo->ignoreNegative && r < 0) { } else { if (isinf(r) || isnan(r)) { colDataAppendNULL(pOutput, pos); } else { colDataAppend(pOutput, pos, (const char*)&r, false); } if (pTsOutput != NULL) { colDataAppendInt64(pTsOutput, pos, &tsList[i]); } // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pos); } numOfElems++; } } pDerivInfo->prevValue = v; pDerivInfo->prevTs = tsList[i]; } } else { for (; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } char* d = (char*)pInputCol->pData + pInputCol->info.bytes * i; GET_TYPED_DATA(v, double, pInputCol->info.type, d); int32_t pos = pCtx->offset + numOfElems; if (!pDerivInfo->valueSet) { // initial value is not set yet pDerivInfo->valueSet = true; } else { double r = ((pDerivInfo->prevValue - v) * pDerivInfo->tsWindow) / (pDerivInfo->prevTs - tsList[i]); if (pDerivInfo->ignoreNegative && r < 0) { } else { if (isinf(r) || isnan(r)) { colDataAppendNULL(pOutput, pos); } else { colDataAppend(pOutput, pos, (const char*)&r, false); } if (pTsOutput != NULL) { colDataAppendInt64(pTsOutput, pos, &pDerivInfo->prevTs); } // handle selectivity if (pCtx->subsidiaries.num > 0) { appendSelectivityValue(pCtx, i, pos); } numOfElems++; } } pDerivInfo->prevValue = v; pDerivInfo->prevTs = tsList[i]; } } return numOfElems; } bool getIrateFuncEnv(struct SFunctionNode* pFunc, SFuncExecEnv* pEnv) { pEnv->calcMemSize = sizeof(SRateInfo); return true; } bool irateFuncSetup(SqlFunctionCtx* pCtx, SResultRowEntryInfo* pResInfo) { if (!functionSetup(pCtx, pResInfo)) { return false; // not initialized since it has been initialized } SRateInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); pInfo->firstKey = INT64_MIN; pInfo->lastKey = INT64_MIN; pInfo->firstValue = (double)INT64_MIN; pInfo->lastValue = (double)INT64_MIN; pInfo->hasResult = 0; return true; } int32_t irateFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SRateInfo* pRateInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; SColumnInfoData* pOutput = (SColumnInfoData*)pCtx->pOutput; TSKEY* tsList = (int64_t*)pInput->pPTS->pData; int32_t numOfElems = 0; int32_t type = pInputCol->info.type; for (int32_t i = pInput->startRowIndex; i < pInput->numOfRows + pInput->startRowIndex; i += 1) { if (colDataIsNull_f(pInputCol->nullbitmap, i)) { continue; } numOfElems++; char* data = colDataGetData(pInputCol, i); double v = 0; GET_TYPED_DATA(v, double, type, data); if (INT64_MIN == pRateInfo->lastKey) { pRateInfo->lastValue = v; pRateInfo->lastKey = tsList[i]; continue; } if (tsList[i] > pRateInfo->lastKey) { if ((INT64_MIN == pRateInfo->firstKey) || pRateInfo->lastKey > pRateInfo->firstKey) { pRateInfo->firstValue = pRateInfo->lastValue; pRateInfo->firstKey = pRateInfo->lastKey; } pRateInfo->lastValue = v; pRateInfo->lastKey = tsList[i]; continue; } if ((INT64_MIN == pRateInfo->firstKey) || tsList[i] > pRateInfo->firstKey) { pRateInfo->firstValue = v; pRateInfo->firstKey = tsList[i]; } } SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; } static double doCalcRate(const SRateInfo* pRateInfo, double tickPerSec) { if ((INT64_MIN == pRateInfo->lastKey) || (INT64_MIN == pRateInfo->firstKey) || (pRateInfo->firstKey >= pRateInfo->lastKey)) { return 0.0; } double diff = 0; // If the previous value of the last is greater than the last value, only keep the last point instead of the delta // value between two values. diff = pRateInfo->lastValue; if (diff >= pRateInfo->firstValue) { diff -= pRateInfo->firstValue; } int64_t duration = pRateInfo->lastKey - pRateInfo->firstKey; if (duration == 0) { return 0; } return (duration > 0) ? ((double)diff) / (duration / tickPerSec) : 0.0; } int32_t irateFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); pResInfo->isNullRes = (pResInfo->numOfRes == 0) ? 1 : 0; SRateInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); double result = doCalcRate(pInfo, (double)TSDB_TICK_PER_SECOND(pCtx->param[1].param.i)); colDataAppend(pCol, pBlock->info.rows, (const char*)&result, pResInfo->isNullRes); return pResInfo->numOfRes; } int32_t groupKeyFunction(SqlFunctionCtx* pCtx) { SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SGroupKeyInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t startIndex = pInput->startRowIndex; // escape rest of data blocks to avoid first entry to be overwritten. if (pInfo->hasResult) { goto _group_key_over; } if (colDataIsNull_s(pInputCol, startIndex)) { pInfo->isNull = true; pInfo->hasResult = true; goto _group_key_over; } char* data = colDataGetData(pInputCol, startIndex); if (IS_VAR_DATA_TYPE(pInputCol->info.type)) { memcpy(pInfo->data, data, (pInputCol->info.type == TSDB_DATA_TYPE_JSON) ? getJsonValueLen(data) : varDataTLen(data)); } else { memcpy(pInfo->data, data, pInputCol->info.bytes); } pInfo->hasResult = true; _group_key_over: SET_VAL(pResInfo, 1, 1); return TSDB_CODE_SUCCESS; } int32_t groupKeyFinalize(SqlFunctionCtx* pCtx, SSDataBlock* pBlock) { int32_t slotId = pCtx->pExpr->base.resSchema.slotId; SColumnInfoData* pCol = taosArrayGet(pBlock->pDataBlock, slotId); SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SGroupKeyInfo* pInfo = GET_ROWCELL_INTERBUF(pResInfo); if (pInfo->hasResult) { int32_t currentRow = pBlock->info.rows; for (; currentRow < pBlock->info.rows + pResInfo->numOfRes; ++currentRow) { colDataAppend(pCol, currentRow, pInfo->data, pInfo->isNull ? true : false); } } else { pResInfo->numOfRes = 0; } return pResInfo->numOfRes; } int32_t cachedLastRowFunction(SqlFunctionCtx* pCtx) { int32_t numOfElems = 0; SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); SFirstLastRes* pInfo = GET_ROWCELL_INTERBUF(pResInfo); SInputColumnInfoData* pInput = &pCtx->input; SColumnInfoData* pInputCol = pInput->pData[0]; int32_t bytes = pInputCol->info.bytes; pInfo->bytes = bytes; // last_row function does not ignore the null value for (int32_t i = pInput->numOfRows + pInput->startRowIndex - 1; i >= pInput->startRowIndex; --i) { numOfElems++; char* data = colDataGetData(pInputCol, i); TSKEY cts = getRowPTs(pInput->pPTS, i); if (pResInfo->numOfRes == 0 || pInfo->ts < cts) { doSaveLastrow(pCtx, data, i, cts, pInfo); pResInfo->numOfRes = 1; } } SET_VAL(pResInfo, numOfElems, 1); return TSDB_CODE_SUCCESS; }