#include "ttime.h" #include "tdatablock.h" #include "executorimpl.h" #include "functionMgt.h" typedef enum SResultTsInterpType { RESULT_ROW_START_INTERP = 1, RESULT_ROW_END_INTERP = 2, } SResultTsInterpType; /* * There are two cases to handle: * * 1. Query range is not set yet (queryRangeSet = 0). we need to set the query range info, including * pQueryAttr->lastKey, pQueryAttr->window.skey, and pQueryAttr->eKey. * 2. Query range is set and query is in progress. There may be another result with the same query ranges to be * merged during merge stage. In this case, we need the pTableQueryInfo->lastResRows to decide if there * is a previous result generated or not. */ static void setIntervalQueryRange(STableQueryInfo* pTableQueryInfo, TSKEY key, STimeWindow* pQRange) { // SResultRowInfo* pResultRowInfo = &pTableQueryInfo->resInfo; // if (pResultRowInfo->curPos != -1) { // return; // } // pTableQueryInfo->win.skey = key; // STimeWindow win = {.skey = key, .ekey = pQRange->ekey}; /** * In handling the both ascending and descending order super table query, we need to find the first qualified * timestamp of this table, and then set the first qualified start timestamp. * In ascending query, the key is the first qualified timestamp. However, in the descending order query, additional * operations involve. */ // STimeWindow w = TSWINDOW_INITIALIZER; // // TSKEY sk = TMIN(win.skey, win.ekey); // TSKEY ek = TMAX(win.skey, win.ekey); // getAlignQueryTimeWindow(pQueryAttr, win.skey, sk, ek, &w); // if (pResultRowInfo->prevSKey == TSKEY_INITIAL_VAL) { // if (!QUERY_IS_ASC_QUERY(pQueryAttr)) { // assert(win.ekey == pQueryAttr->window.ekey); // } // // pResultRowInfo->prevSKey = w.skey; // } // pTableQueryInfo->lastKey = pTableQueryInfo->win.skey; } static TSKEY getStartTsKey(STimeWindow* win, const TSKEY* tsCols, int32_t rows, bool ascQuery) { TSKEY ts = TSKEY_INITIAL_VAL; if (tsCols == NULL) { ts = ascQuery ? win->skey : win->ekey; } else { int32_t offset = ascQuery ? 0 : rows - 1; ts = tsCols[offset]; } return ts; } static void getInitialStartTimeWindow(SInterval* pInterval, int32_t precision, TSKEY ts, STimeWindow* w, bool ascQuery) { if (ascQuery) { getAlignQueryTimeWindow(pInterval, precision, ts, w); } else { // the start position of the first time window in the endpoint that spreads beyond the queried last timestamp getAlignQueryTimeWindow(pInterval, precision, ts, w); int64_t key = w->skey; while (key < ts) { // moving towards end key = taosTimeAdd(key, pInterval->sliding, pInterval->slidingUnit, precision); if (key >= ts) { break; } w->skey = key; } } } // get the correct time window according to the handled timestamp static STimeWindow getActiveTimeWindow(SDiskbasedBuf* pBuf, SResultRowInfo* pResultRowInfo, int64_t ts, SInterval* pInterval, int32_t precision, STimeWindow* win) { STimeWindow w = {0}; if (pResultRowInfo->cur.pageId == -1) { // the first window, from the previous stored value getInitialStartTimeWindow(pInterval, precision, ts, &w, true); w.ekey = taosTimeAdd(w.skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } else { w = getResultRowByPos(pBuf, &pResultRowInfo->cur)->win; } if (w.skey > ts || w.ekey < ts) { if (pInterval->intervalUnit == 'n' || pInterval->intervalUnit == 'y') { w.skey = taosTimeTruncate(ts, pInterval, precision); w.ekey = taosTimeAdd(w.skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } else { int64_t st = w.skey; if (st > ts) { st -= ((st - ts + pInterval->sliding - 1) / pInterval->sliding) * pInterval->sliding; } int64_t et = st + pInterval->interval - 1; if (et < ts) { st += ((ts - et + pInterval->sliding - 1) / pInterval->sliding) * pInterval->sliding; } w.skey = st; w.ekey = taosTimeAdd(w.skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } } return w; } static int32_t setTimeWindowOutputBuf(SResultRowInfo* pResultRowInfo, STimeWindow* win, bool masterscan, SResultRow** pResult, int64_t tableGroupId, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset, SAggSupporter* pAggSup, SExecTaskInfo* pTaskInfo) { assert(win->skey <= win->ekey); SResultRow* pResultRow = doSetResultOutBufByKey(pAggSup->pResultBuf, pResultRowInfo, (char*)&win->skey, TSDB_KEYSIZE, masterscan, tableGroupId, pTaskInfo, true, pAggSup); if (pResultRow == NULL) { *pResult = NULL; return TSDB_CODE_SUCCESS; } // set time window for current result pResultRow->win = (*win); *pResult = pResultRow; setResultRowInitCtx(pResultRow, pCtx, numOfOutput, rowCellInfoOffset); return TSDB_CODE_SUCCESS; } static void updateTimeWindowInfo(SColumnInfoData* pColData, STimeWindow* pWin, bool includeEndpoint) { int64_t* ts = (int64_t*)pColData->pData; int32_t delta = includeEndpoint ? 1 : 0; int64_t duration = pWin->ekey - pWin->skey + delta; ts[2] = duration; // set the duration ts[3] = pWin->skey; // window start key ts[4] = pWin->ekey + delta; // window end key } static void doKeepTuple(SWindowRowsSup* pRowSup, int64_t ts) { pRowSup->win.ekey = ts; pRowSup->prevTs = ts; pRowSup->numOfRows += 1; } static void doKeepNewWindowStartInfo(SWindowRowsSup* pRowSup, const int64_t* tsList, int32_t rowIndex) { pRowSup->startRowIndex = rowIndex; pRowSup->numOfRows = 0; pRowSup->win.skey = tsList[rowIndex]; } static FORCE_INLINE int32_t getForwardStepsInBlock(int32_t numOfRows, __block_search_fn_t searchFn, TSKEY ekey, int16_t pos, int16_t order, int64_t* pData) { int32_t forwardStep = 0; if (order == TSDB_ORDER_ASC) { int32_t end = searchFn((char*)&pData[pos], numOfRows - pos, ekey, order); if (end >= 0) { forwardStep = end; if (pData[end + pos] == ekey) { forwardStep += 1; } } } else { int32_t end = searchFn((char*)pData, pos + 1, ekey, order); if (end >= 0) { forwardStep = pos - end; if (pData[end] == ekey) { forwardStep += 1; } } } assert(forwardStep >= 0); return forwardStep; } static int32_t binarySearchForKey(char* pValue, int num, TSKEY key, int order) { int32_t midPos = -1; int32_t numOfRows; if (num <= 0) { return -1; } assert(order == TSDB_ORDER_ASC || order == TSDB_ORDER_DESC); TSKEY* keyList = (TSKEY*)pValue; int32_t firstPos = 0; int32_t lastPos = num - 1; if (order == TSDB_ORDER_DESC) { // find the first position which is smaller than the key while (1) { if (key >= keyList[lastPos]) return lastPos; if (key == keyList[firstPos]) return firstPos; if (key < keyList[firstPos]) return firstPos - 1; numOfRows = lastPos - firstPos + 1; midPos = (numOfRows >> 1) + firstPos; if (key < keyList[midPos]) { lastPos = midPos - 1; } else if (key > keyList[midPos]) { firstPos = midPos + 1; } else { break; } } } else { // find the first position which is bigger than the key while (1) { if (key <= keyList[firstPos]) return firstPos; if (key == keyList[lastPos]) return lastPos; if (key > keyList[lastPos]) { lastPos = lastPos + 1; if (lastPos >= num) return -1; else return lastPos; } numOfRows = lastPos - firstPos + 1; midPos = (numOfRows >> 1u) + firstPos; if (key < keyList[midPos]) { lastPos = midPos - 1; } else if (key > keyList[midPos]) { firstPos = midPos + 1; } else { break; } } } return midPos; } static int32_t getNumOfRowsInTimeWindow(SDataBlockInfo* pDataBlockInfo, TSKEY* pPrimaryColumn, int32_t startPos, TSKEY ekey, __block_search_fn_t searchFn, STableQueryInfo* item, int32_t order) { assert(startPos >= 0 && startPos < pDataBlockInfo->rows); int32_t num = -1; int32_t step = GET_FORWARD_DIRECTION_FACTOR(order); if (order == TSDB_ORDER_ASC) { if (ekey < pDataBlockInfo->window.ekey && pPrimaryColumn) { num = getForwardStepsInBlock(pDataBlockInfo->rows, searchFn, ekey, startPos, order, pPrimaryColumn); if (item != NULL) { item->lastKey = pPrimaryColumn[startPos + (num - 1)] + step; } } else { num = pDataBlockInfo->rows - startPos; if (item != NULL) { item->lastKey = pDataBlockInfo->window.ekey + step; } } } else { // desc if (ekey > pDataBlockInfo->window.skey && pPrimaryColumn) { num = getForwardStepsInBlock(pDataBlockInfo->rows, searchFn, ekey, startPos, order, pPrimaryColumn); if (item != NULL) { item->lastKey = pPrimaryColumn[startPos - (num - 1)] + step; } } else { num = startPos + 1; if (item != NULL) { item->lastKey = pDataBlockInfo->window.skey + step; } } } assert(num >= 0); return num; } static void getNextTimeWindow(SInterval* pInterval, int32_t precision, int32_t order, STimeWindow* tw) { int32_t factor = GET_FORWARD_DIRECTION_FACTOR(order); if (pInterval->intervalUnit != 'n' && pInterval->intervalUnit != 'y') { tw->skey += pInterval->sliding * factor; tw->ekey = tw->skey + pInterval->interval - 1; return; } int64_t key = tw->skey, interval = pInterval->interval; // convert key to second key = convertTimePrecision(key, precision, TSDB_TIME_PRECISION_MILLI) / 1000; if (pInterval->intervalUnit == 'y') { interval *= 12; } struct tm tm; time_t t = (time_t)key; taosLocalTime(&t, &tm); int mon = (int)(tm.tm_year * 12 + tm.tm_mon + interval * factor); tm.tm_year = mon / 12; tm.tm_mon = mon % 12; tw->skey = convertTimePrecision((int64_t)taosMktime(&tm) * 1000L, TSDB_TIME_PRECISION_MILLI, precision); mon = (int)(mon + interval); tm.tm_year = mon / 12; tm.tm_mon = mon % 12; tw->ekey = convertTimePrecision((int64_t)taosMktime(&tm) * 1000L, TSDB_TIME_PRECISION_MILLI, precision); tw->ekey -= 1; } void doTimeWindowInterpolation(SOperatorInfo* pOperator, SOptrBasicInfo* pInfo, SArray* pDataBlock, TSKEY prevTs, int32_t prevRowIndex, TSKEY curTs, int32_t curRowIndex, TSKEY windowKey, int32_t type) { SExprInfo* pExpr = pOperator->pExpr; SqlFunctionCtx* pCtx = pInfo->pCtx; for (int32_t k = 0; k < pOperator->numOfExprs; ++k) { int32_t functionId = pCtx[k].functionId; if (functionId != FUNCTION_TWA && functionId != FUNCTION_INTERP) { pCtx[k].start.key = INT64_MIN; continue; } SColIndex* pColIndex = NULL /*&pExpr[k].base.colInfo*/; int16_t index = pColIndex->colIndex; SColumnInfoData* pColInfo = taosArrayGet(pDataBlock, index); // assert(pColInfo->info.colId == pColIndex->info.colId && curTs != windowKey); double v1 = 0, v2 = 0, v = 0; if (prevRowIndex == -1) { // GET_TYPED_DATA(v1, double, pColInfo->info.type, (char*)pRuntimeEnv->prevRow[index]); } else { GET_TYPED_DATA(v1, double, pColInfo->info.type, (char*)pColInfo->pData + prevRowIndex * pColInfo->info.bytes); } GET_TYPED_DATA(v2, double, pColInfo->info.type, (char*)pColInfo->pData + curRowIndex * pColInfo->info.bytes); if (functionId == FUNCTION_INTERP) { if (type == RESULT_ROW_START_INTERP) { pCtx[k].start.key = prevTs; pCtx[k].start.val = v1; pCtx[k].end.key = curTs; pCtx[k].end.val = v2; if (pColInfo->info.type == TSDB_DATA_TYPE_BINARY || pColInfo->info.type == TSDB_DATA_TYPE_NCHAR) { if (prevRowIndex == -1) { // pCtx[k].start.ptr = (char*)pRuntimeEnv->prevRow[index]; } else { pCtx[k].start.ptr = (char*)pColInfo->pData + prevRowIndex * pColInfo->info.bytes; } pCtx[k].end.ptr = (char*)pColInfo->pData + curRowIndex * pColInfo->info.bytes; } } } else if (functionId == FUNCTION_TWA) { SPoint point1 = (SPoint){.key = prevTs, .val = &v1}; SPoint point2 = (SPoint){.key = curTs, .val = &v2}; SPoint point = (SPoint){.key = windowKey, .val = &v}; taosGetLinearInterpolationVal(&point, TSDB_DATA_TYPE_DOUBLE, &point1, &point2, TSDB_DATA_TYPE_DOUBLE); if (type == RESULT_ROW_START_INTERP) { pCtx[k].start.key = point.key; pCtx[k].start.val = v; } else { pCtx[k].end.key = point.key; pCtx[k].end.val = v; } } } } static void setNotInterpoWindowKey(SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t type) { if (type == RESULT_ROW_START_INTERP) { for (int32_t k = 0; k < numOfOutput; ++k) { pCtx[k].start.key = INT64_MIN; } } else { for (int32_t k = 0; k < numOfOutput; ++k) { pCtx[k].end.key = INT64_MIN; } } } static bool setTimeWindowInterpolationStartTs(SOperatorInfo* pOperatorInfo, SqlFunctionCtx* pCtx, int32_t pos, int32_t numOfRows, SArray* pDataBlock, const TSKEY* tsCols, STimeWindow* win) { bool ascQuery = true; TSKEY curTs = tsCols[pos]; TSKEY lastTs = 0; //*(TSKEY*)pRuntimeEnv->prevRow[0]; // lastTs == INT64_MIN and pos == 0 means this is the first time window, interpolation is not needed. // start exactly from this point, no need to do interpolation TSKEY key = ascQuery ? win->skey : win->ekey; if (key == curTs) { setNotInterpoWindowKey(pCtx, pOperatorInfo->numOfExprs, RESULT_ROW_START_INTERP); return true; } if (lastTs == INT64_MIN && ((pos == 0 && ascQuery) || (pos == (numOfRows - 1) && !ascQuery))) { setNotInterpoWindowKey(pCtx, pOperatorInfo->numOfExprs, RESULT_ROW_START_INTERP); return true; } int32_t step = 1; // GET_FORWARD_DIRECTION_FACTOR(pQueryAttr->order.order); TSKEY prevTs = ((pos == 0 && ascQuery) || (pos == (numOfRows - 1) && !ascQuery)) ? lastTs : tsCols[pos - step]; doTimeWindowInterpolation(pOperatorInfo, pOperatorInfo->info, pDataBlock, prevTs, pos - step, curTs, pos, key, RESULT_ROW_START_INTERP); return true; } static bool setTimeWindowInterpolationEndTs(SOperatorInfo* pOperatorInfo, SqlFunctionCtx* pCtx, int32_t endRowIndex, SArray* pDataBlock, const TSKEY* tsCols, TSKEY blockEkey, STimeWindow* win) { int32_t order = TSDB_ORDER_ASC; int32_t numOfOutput = pOperatorInfo->numOfExprs; TSKEY actualEndKey = tsCols[endRowIndex]; TSKEY key = order ? win->ekey : win->skey; // not ended in current data block, do not invoke interpolation if ((key > blockEkey /*&& QUERY_IS_ASC_QUERY(pQueryAttr)*/) || (key < blockEkey /*&& !QUERY_IS_ASC_QUERY(pQueryAttr)*/)) { setNotInterpoWindowKey(pCtx, numOfOutput, RESULT_ROW_END_INTERP); return false; } // there is actual end point of current time window, no interpolation need if (key == actualEndKey) { setNotInterpoWindowKey(pCtx, numOfOutput, RESULT_ROW_END_INTERP); return true; } int32_t step = GET_FORWARD_DIRECTION_FACTOR(order); int32_t nextRowIndex = endRowIndex + step; assert(nextRowIndex >= 0); TSKEY nextKey = tsCols[nextRowIndex]; doTimeWindowInterpolation(pOperatorInfo, pOperatorInfo->info, pDataBlock, actualEndKey, endRowIndex, nextKey, nextRowIndex, key, RESULT_ROW_END_INTERP); return true; } static int32_t getNextQualifiedWindow(SInterval* pInterval, STimeWindow* pNext, SDataBlockInfo* pDataBlockInfo, TSKEY* primaryKeys, int32_t prevPosition, SIntervalAggOperatorInfo* pInfo) { int32_t order = pInfo->order; bool ascQuery = (order == TSDB_ORDER_ASC); int32_t precision = pInterval->precision; getNextTimeWindow(pInterval, precision, order, pNext); // next time window is not in current block if ((pNext->skey > pDataBlockInfo->window.ekey && order == TSDB_ORDER_ASC) || (pNext->ekey < pDataBlockInfo->window.skey && order == TSDB_ORDER_DESC)) { return -1; } TSKEY startKey = ascQuery ? pNext->skey : pNext->ekey; int32_t startPos = 0; // tumbling time window query, a special case of sliding time window query if (pInterval->sliding == pInterval->interval && prevPosition != -1) { int32_t factor = GET_FORWARD_DIRECTION_FACTOR(order); startPos = prevPosition + factor; } else { if (startKey <= pDataBlockInfo->window.skey && ascQuery) { startPos = 0; } else if (startKey >= pDataBlockInfo->window.ekey && !ascQuery) { startPos = pDataBlockInfo->rows - 1; } else { startPos = binarySearchForKey((char*)primaryKeys, pDataBlockInfo->rows, startKey, order); } } /* interp query with fill should not skip time window */ // if (pQueryAttr->pointInterpQuery && pQueryAttr->fillType != TSDB_FILL_NONE) { // return startPos; // } /* * This time window does not cover any data, try next time window, * this case may happen when the time window is too small */ if (primaryKeys == NULL) { if (ascQuery) { assert(pDataBlockInfo->window.skey <= pNext->ekey); } else { assert(pDataBlockInfo->window.ekey >= pNext->skey); } } else { if (ascQuery && primaryKeys[startPos] > pNext->ekey) { TSKEY next = primaryKeys[startPos]; if (pInterval->intervalUnit == 'n' || pInterval->intervalUnit == 'y') { pNext->skey = taosTimeTruncate(next, pInterval, precision); pNext->ekey = taosTimeAdd(pNext->skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } else { pNext->ekey += ((next - pNext->ekey + pInterval->sliding - 1) / pInterval->sliding) * pInterval->sliding; pNext->skey = pNext->ekey - pInterval->interval + 1; } } else if ((!ascQuery) && primaryKeys[startPos] < pNext->skey) { TSKEY next = primaryKeys[startPos]; if (pInterval->intervalUnit == 'n' || pInterval->intervalUnit == 'y') { pNext->skey = taosTimeTruncate(next, pInterval, precision); pNext->ekey = taosTimeAdd(pNext->skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } else { pNext->skey -= ((pNext->skey - next + pInterval->sliding - 1) / pInterval->sliding) * pInterval->sliding; pNext->ekey = pNext->skey + pInterval->interval - 1; } } } return startPos; } static bool resultRowInterpolated(SResultRow* pResult, SResultTsInterpType type) { assert(pResult != NULL && (type == RESULT_ROW_START_INTERP || type == RESULT_ROW_END_INTERP)); if (type == RESULT_ROW_START_INTERP) { return pResult->startInterp == true; } else { return pResult->endInterp == true; } } static void setResultRowInterpo(SResultRow* pResult, SResultTsInterpType type) { assert(pResult != NULL && (type == RESULT_ROW_START_INTERP || type == RESULT_ROW_END_INTERP)); if (type == RESULT_ROW_START_INTERP) { pResult->startInterp = true; } else { pResult->endInterp = true; } } static void doWindowBorderInterpolation(SOperatorInfo* pOperatorInfo, SSDataBlock* pBlock, SqlFunctionCtx* pCtx, SResultRow* pResult, STimeWindow* win, int32_t startPos, int32_t forwardStep, int32_t order, bool timeWindowInterpo) { if (!timeWindowInterpo) { return; } assert(pBlock != NULL); int32_t step = GET_FORWARD_DIRECTION_FACTOR(order); if (pBlock->pDataBlock == NULL) { // tscError("pBlock->pDataBlock == NULL"); return; } SColumnInfoData* pColInfo = taosArrayGet(pBlock->pDataBlock, 0); TSKEY* tsCols = (TSKEY*)(pColInfo->pData); bool done = resultRowInterpolated(pResult, RESULT_ROW_START_INTERP); if (!done) { // it is not interpolated, now start to generated the interpolated value int32_t startRowIndex = startPos; bool interp = setTimeWindowInterpolationStartTs(pOperatorInfo, pCtx, startRowIndex, pBlock->info.rows, pBlock->pDataBlock, tsCols, win); if (interp) { setResultRowInterpo(pResult, RESULT_ROW_START_INTERP); } } else { setNotInterpoWindowKey(pCtx, pOperatorInfo->numOfExprs, RESULT_ROW_START_INTERP); } // point interpolation does not require the end key time window interpolation. // if (pointInterpQuery) { // return; // } // interpolation query does not generate the time window end interpolation done = resultRowInterpolated(pResult, RESULT_ROW_END_INTERP); if (!done) { int32_t endRowIndex = startPos + (forwardStep - 1) * step; TSKEY endKey = (order == TSDB_ORDER_ASC) ? pBlock->info.window.ekey : pBlock->info.window.skey; bool interp = setTimeWindowInterpolationEndTs(pOperatorInfo, pCtx, endRowIndex, pBlock->pDataBlock, tsCols, endKey, win); if (interp) { setResultRowInterpo(pResult, RESULT_ROW_END_INTERP); } } else { setNotInterpoWindowKey(pCtx, pOperatorInfo->numOfExprs, RESULT_ROW_END_INTERP); } } static void saveDataBlockLastRow(char** pRow, SArray* pDataBlock, int32_t rowIndex, int32_t numOfCols) { if (pDataBlock == NULL) { return; } for (int32_t k = 0; k < numOfCols; ++k) { SColumnInfoData* pColInfo = taosArrayGet(pDataBlock, k); memcpy(pRow[k], ((char*)pColInfo->pData) + (pColInfo->info.bytes * rowIndex), pColInfo->info.bytes); } } static SArray* hashIntervalAgg(SOperatorInfo* pOperatorInfo, SResultRowInfo* pResultRowInfo, SSDataBlock* pSDataBlock, int32_t tableGroupId) { SIntervalAggOperatorInfo* pInfo = (SIntervalAggOperatorInfo*)pOperatorInfo->info; SExecTaskInfo* pTaskInfo = pOperatorInfo->pTaskInfo; int32_t numOfOutput = pOperatorInfo->numOfExprs; SArray* pUpdated = NULL; if (pInfo->execModel == OPTR_EXEC_MODEL_STREAM) { pUpdated = taosArrayInit(4, POINTER_BYTES); } int32_t step = 1; bool ascScan = true; // int32_t prevIndex = pResultRowInfo->curPos; TSKEY* tsCols = NULL; if (pSDataBlock->pDataBlock != NULL) { SColumnInfoData* pColDataInfo = taosArrayGet(pSDataBlock->pDataBlock, pInfo->primaryTsIndex); tsCols = (int64_t*)pColDataInfo->pData; } int32_t startPos = ascScan ? 0 : (pSDataBlock->info.rows - 1); TSKEY ts = getStartTsKey(&pSDataBlock->info.window, tsCols, pSDataBlock->info.rows, ascScan); STimeWindow win = getActiveTimeWindow(pInfo->aggSup.pResultBuf, pResultRowInfo, ts, &pInfo->interval, pInfo->interval.precision, &pInfo->win); bool masterScan = true; SResultRow* pResult = NULL; int32_t ret = setTimeWindowOutputBuf(pResultRowInfo, &win, masterScan, &pResult, tableGroupId, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS || pResult == NULL) { longjmp(pTaskInfo->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } if (pInfo->execModel == OPTR_EXEC_MODEL_STREAM) { SResKeyPos* pos = taosMemoryMalloc(sizeof(SResKeyPos) + sizeof(uint64_t)); pos->groupId = tableGroupId; pos->pos = (SResultRowPosition){.pageId = pResult->pageId, .offset = pResult->offset}; *(int64_t*)pos->key = pResult->win.skey; taosArrayPush(pUpdated, &pos); } int32_t forwardStep = 0; TSKEY ekey = win.ekey; forwardStep = getNumOfRowsInTimeWindow(&pSDataBlock->info, tsCols, startPos, ekey, binarySearchForKey, NULL, TSDB_ORDER_ASC); // prev time window not interpolation yet. // int32_t curIndex = pResultRowInfo->curPos; #if 0 if (prevIndex != -1 && prevIndex < curIndex && pInfo->timeWindowInterpo) { for (int32_t j = prevIndex; j < curIndex; ++j) { // previous time window may be all closed already. SResultRow* pRes = getResultRow(pResultRowInfo, j); if (pRes->closed) { assert(resultRowInterpolated(pRes, RESULT_ROW_START_INTERP) && resultRowInterpolated(pRes, RESULT_ROW_END_INTERP)); continue; } STimeWindow w = pRes->win; ret = setTimeWindowOutputBuf(pResultRowInfo, pSDataBlock->info.uid, &w, masterScan, &pResult, tableGroupId, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS) { longjmp(pTaskInfo->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } assert(!resultRowInterpolated(pResult, RESULT_ROW_END_INTERP)); doTimeWindowInterpolation(pOperatorInfo, &pInfo->binfo, pSDataBlock->pDataBlock, *(TSKEY*)pInfo->pRow[0], -1, tsCols[startPos], startPos, w.ekey, RESULT_ROW_END_INTERP); setResultRowInterpo(pResult, RESULT_ROW_END_INTERP); setNotInterpoWindowKey(pInfo->binfo.pCtx, pOperatorInfo->numOfExprs, RESULT_ROW_START_INTERP); doApplyFunctions(pInfo->binfo.pCtx, &w, &pInfo->timeWindowData, startPos, 0, tsCols, pSDataBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); } // restore current time window ret = setTimeWindowOutputBuf(pResultRowInfo, pSDataBlock->info.uid, &win, masterScan, &pResult, tableGroupId, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS) { longjmp(pTaskInfo->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } } #endif // window start key interpolation doWindowBorderInterpolation(pOperatorInfo, pSDataBlock, pInfo->binfo.pCtx, pResult, &win, startPos, forwardStep, pInfo->order, false); updateTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &win, true); doApplyFunctions(pInfo->binfo.pCtx, &win, &pInfo->twAggSup.timeWindowData, startPos, forwardStep, tsCols, pSDataBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); STimeWindow nextWin = win; while (1) { int32_t prevEndPos = (forwardStep - 1) * step + startPos; startPos = getNextQualifiedWindow(&pInfo->interval, &nextWin, &pSDataBlock->info, tsCols, prevEndPos, pInfo); if (startPos < 0) { break; } // null data, failed to allocate more memory buffer int32_t code = setTimeWindowOutputBuf(pResultRowInfo, &nextWin, masterScan, &pResult, tableGroupId, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (code != TSDB_CODE_SUCCESS || pResult == NULL) { longjmp(pTaskInfo->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } if (pInfo->execModel == OPTR_EXEC_MODEL_STREAM) { SResKeyPos* pos = taosMemoryMalloc(sizeof(SResKeyPos) + sizeof(uint64_t)); pos->groupId = tableGroupId; pos->pos = (SResultRowPosition){.pageId = pResult->pageId, .offset = pResult->offset}; *(int64_t*)pos->key = pResult->win.skey; taosArrayPush(pUpdated, &pos); } ekey = nextWin.ekey; // reviseWindowEkey(pQueryAttr, &nextWin); forwardStep = getNumOfRowsInTimeWindow(&pSDataBlock->info, tsCols, startPos, ekey, binarySearchForKey, NULL, TSDB_ORDER_ASC); // window start(end) key interpolation doWindowBorderInterpolation(pOperatorInfo, pSDataBlock, pInfo->binfo.pCtx, pResult, &nextWin, startPos, forwardStep, pInfo->order, false); updateTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &nextWin, true); doApplyFunctions(pInfo->binfo.pCtx, &nextWin, &pInfo->twAggSup.timeWindowData, startPos, forwardStep, tsCols, pSDataBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); } if (pInfo->timeWindowInterpo) { int32_t rowIndex = ascScan ? (pSDataBlock->info.rows - 1) : 0; saveDataBlockLastRow(pInfo->pRow, pSDataBlock->pDataBlock, rowIndex, pSDataBlock->info.numOfCols); } return pUpdated; // updateResultRowInfoActiveIndex(pResultRowInfo, &pInfo->win, pRuntimeEnv->current->lastKey, true, false); } static int32_t doOpenIntervalAgg(SOperatorInfo* pOperator) { if (OPTR_IS_OPENED(pOperator)) { return TSDB_CODE_SUCCESS; } SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SIntervalAggOperatorInfo* pInfo = pOperator->info; int32_t order = TSDB_ORDER_ASC; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->fpSet.getNextFn(downstream); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // setTagValue(pOperator, pRuntimeEnv->current->pTable, pInfo->pCtx, pOperator->numOfExprs); // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->binfo.pCtx, pBlock, order, true); STableQueryInfo* pTableQueryInfo = pInfo->pCurrent; setIntervalQueryRange(pTableQueryInfo, pBlock->info.window.skey, &pTaskInfo->window); hashIntervalAgg(pOperator, &pInfo->binfo.resultRowInfo, pBlock, pBlock->info.groupId); #if 0 // test for encode/decode result info if(pOperator->encodeResultRow){ char *result = NULL; int32_t length = 0; SAggSupporter *pSup = &pInfo->aggSup; pOperator->encodeResultRow(pOperator, pSup, &pInfo->binfo, &result, &length); taosHashClear(pSup->pResultRowHashTable); pInfo->binfo.resultRowInfo.size = 0; pOperator->decodeResultRow(pOperator, pSup, &pInfo->binfo, result, length); if(result){ taosMemoryFree(result); } } #endif } closeAllResultRows(&pInfo->binfo.resultRowInfo); finalizeMultiTupleQueryResult(pInfo->binfo.pCtx, pOperator->numOfExprs, pInfo->aggSup.pResultBuf, &pInfo->binfo.resultRowInfo, pInfo->binfo.rowCellInfoOffset); initGroupedResultInfo(&pInfo->groupResInfo, pInfo->aggSup.pResultRowHashTable, true); OPTR_SET_OPENED(pOperator); return TSDB_CODE_SUCCESS; } static void doStateWindowAggImpl(SOperatorInfo* pOperator, SStateWindowOperatorInfo* pInfo, SSDataBlock* pBlock) { SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SColumnInfoData* pStateColInfoData = taosArrayGet(pBlock->pDataBlock, pInfo->colIndex); int64_t gid = pBlock->info.groupId; bool masterScan = true; int32_t numOfOutput = pOperator->numOfExprs; int16_t bytes = pStateColInfoData->info.bytes; SColumnInfoData* pColInfoData = taosArrayGet(pBlock->pDataBlock, pInfo->tsSlotId); TSKEY* tsList = (TSKEY*)pColInfoData->pData; SWindowRowsSup* pRowSup = &pInfo->winSup; pRowSup->numOfRows = 0; for (int32_t j = 0; j < pBlock->info.rows; ++j) { if (colDataIsNull(pStateColInfoData, pBlock->info.rows, j, pBlock->pBlockAgg[pInfo->colIndex])) { continue; } char* val = colDataGetData(pStateColInfoData, j); if (!pInfo->hasKey) { memcpy(pInfo->stateKey.pData, val, bytes); pInfo->hasKey = true; doKeepNewWindowStartInfo(pRowSup, tsList, j); doKeepTuple(pRowSup, tsList[j]); } else if (memcmp(pInfo->stateKey.pData, val, bytes) == 0) { doKeepTuple(pRowSup, tsList[j]); if (j == 0 && pRowSup->startRowIndex != 0) { pRowSup->startRowIndex = 0; } } else { // a new state window started SResultRow* pResult = NULL; // keep the time window for the closed time window. STimeWindow window = pRowSup->win; pRowSup->win.ekey = pRowSup->win.skey; int32_t ret = setTimeWindowOutputBuf(&pInfo->binfo.resultRowInfo, &window, masterScan, &pResult, gid, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS) { // null data, too many state code longjmp(pTaskInfo->env, TSDB_CODE_QRY_APP_ERROR); } updateTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &window, false); doApplyFunctions(pInfo->binfo.pCtx, &window, &pInfo->twAggSup.timeWindowData, pRowSup->startRowIndex, pRowSup->numOfRows, NULL, pBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); // here we start a new session window doKeepNewWindowStartInfo(pRowSup, tsList, j); doKeepTuple(pRowSup, tsList[j]); } } SResultRow* pResult = NULL; pRowSup->win.ekey = tsList[pBlock->info.rows - 1]; int32_t ret = setTimeWindowOutputBuf(&pInfo->binfo.resultRowInfo, &pRowSup->win, masterScan, &pResult, gid, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS) { // null data, too many state code longjmp(pTaskInfo->env, TSDB_CODE_QRY_APP_ERROR); } updateTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &pRowSup->win, false); doApplyFunctions(pInfo->binfo.pCtx, &pRowSup->win, &pInfo->twAggSup.timeWindowData, pRowSup->startRowIndex, pRowSup->numOfRows, NULL, pBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); } static SSDataBlock* doStateWindowAgg(SOperatorInfo* pOperator) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SStateWindowOperatorInfo* pInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SOptrBasicInfo* pBInfo = &pInfo->binfo; if (pOperator->status == OP_RES_TO_RETURN) { doBuildResultDatablock(pBInfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); return NULL; } return pBInfo->pRes; } int32_t order = TSDB_ORDER_ASC; STimeWindow win = pTaskInfo->window; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->fpSet.getNextFn(downstream); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } setInputDataBlock(pOperator, pBInfo->pCtx, pBlock, order, true); doStateWindowAggImpl(pOperator, pInfo, pBlock); } pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pBInfo->resultRowInfo); finalizeMultiTupleQueryResult(pBInfo->pCtx, pOperator->numOfExprs, pInfo->aggSup.pResultBuf, &pBInfo->resultRowInfo, pBInfo->rowCellInfoOffset); initGroupedResultInfo(&pInfo->groupResInfo, pInfo->aggSup.pResultRowHashTable, true); blockDataEnsureCapacity(pBInfo->pRes, pOperator->resultInfo.capacity); doBuildResultDatablock(pBInfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pBInfo->pRes->info.rows == 0 ? NULL : pBInfo->pRes; } static SSDataBlock* doBuildIntervalResult(SOperatorInfo* pOperator) { SIntervalAggOperatorInfo* pInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; if (pOperator->status == OP_EXEC_DONE) { return NULL; } SSDataBlock* pBlock = pInfo->binfo.pRes; if (pInfo->execModel == OPTR_EXEC_MODEL_STREAM) { return pOperator->fpSet.getStreamResFn(pOperator); } else { pTaskInfo->code = pOperator->fpSet._openFn(pOperator); if (pTaskInfo->code != TSDB_CODE_SUCCESS) { return NULL; } blockDataEnsureCapacity(pBlock, pOperator->resultInfo.capacity); doBuildResultDatablock(&pInfo->binfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); if (pBlock->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pBlock->info.rows == 0 ? NULL : pBlock; } } // todo merged with the build group result. static void finalizeUpdatedResult(int32_t numOfOutput, SDiskbasedBuf* pBuf, SArray* pUpdateList, int32_t* rowCellInfoOffset) { size_t num = taosArrayGetSize(pUpdateList); for (int32_t i = 0; i < num; ++i) { SResKeyPos* pPos = taosArrayGetP(pUpdateList, i); SFilePage* bufPage = getBufPage(pBuf, pPos->pos.pageId); SResultRow* pRow = (SResultRow*)((char*)bufPage + pPos->pos.offset); for (int32_t j = 0; j < numOfOutput; ++j) { SResultRowEntryInfo* pEntry = getResultCell(pRow, j, rowCellInfoOffset); if (pRow->numOfRows < pEntry->numOfRes) { pRow->numOfRows = pEntry->numOfRes; } } releaseBufPage(pBuf, bufPage); } } static void setInverFunction(SqlFunctionCtx* pCtx, int32_t num, EStreamType type) { for ( int i = 0; i < num; i++) { if (type == STREAM_INVERT) { fmSetInvertFunc(pCtx[i].functionId, &(pCtx[i].fpSet)); } else if (type == STREAM_NORMAL){ fmSetNormalFunc(pCtx[i].functionId, &(pCtx[i].fpSet)); } } } static SSDataBlock* doStreamIntervalAgg(SOperatorInfo* pOperator) { SIntervalAggOperatorInfo* pInfo = pOperator->info; int32_t order = TSDB_ORDER_ASC; if (pOperator->status == OP_EXEC_DONE) { return NULL; } if (pOperator->status == OP_RES_TO_RETURN) { doBuildResultDatablock(&pInfo->binfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); if (pInfo->binfo.pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } return pInfo->binfo.pRes->info.rows == 0 ? NULL : pInfo->binfo.pRes; } // STimeWindow win = {0}; SOperatorInfo* downstream = pOperator->pDownstream[0]; SArray* pUpdated = NULL; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->fpSet.getNextFn(downstream); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // The timewindows that overlaps the timestamps of the input pBlock need to be recalculated and return to the // caller. Note that all the time window are not close till now. // setTagValue(pOperator, pRuntimeEnv->current->pTable, pInfo->pCtx, pOperator->numOfExprs); // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->binfo.pCtx, pBlock, order, true); if (pInfo->invertible) { setInverFunction(pInfo->binfo.pCtx, pOperator->numOfExprs, pBlock->info.type); } pUpdated = hashIntervalAgg(pOperator, &pInfo->binfo.resultRowInfo, pBlock, 0); } finalizeUpdatedResult(pOperator->numOfExprs, pInfo->aggSup.pResultBuf, pUpdated, pInfo->binfo.rowCellInfoOffset); initMultiResInfoFromArrayList(&pInfo->groupResInfo, pUpdated); blockDataEnsureCapacity(pInfo->binfo.pRes, pOperator->resultInfo.capacity); doBuildResultDatablock(&pInfo->binfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); ASSERT(pInfo->binfo.pRes->info.rows > 0); pOperator->status = OP_RES_TO_RETURN; return pInfo->binfo.pRes->info.rows == 0 ? NULL : pInfo->binfo.pRes; } static void destroyStateWindowOperatorInfo(void* param, int32_t numOfOutput) { SStateWindowOperatorInfo* pInfo = (SStateWindowOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); taosMemoryFreeClear(pInfo->stateKey.pData); } void destroyIntervalOperatorInfo(void* param, int32_t numOfOutput) { SIntervalAggOperatorInfo* pInfo = (SIntervalAggOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); cleanupAggSup(&pInfo->aggSup); } bool allInvertible(SqlFunctionCtx* pFCtx, int32_t numOfCols) { for (int32_t i = 0; i < numOfCols; i++) { if (!fmIsInvertible(pFCtx[i].functionId)) { return false; } } return true; } SOperatorInfo* createIntervalOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResBlock, SInterval* pInterval, int32_t primaryTsSlotId, STimeWindowAggSupp* pTwAggSupp, const STableGroupInfo* pTableGroupInfo, SExecTaskInfo* pTaskInfo) { SIntervalAggOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SIntervalAggOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->order = TSDB_ORDER_ASC; pInfo->interval = *pInterval; // pInfo->execModel = OPTR_EXEC_MODEL_STREAM; pInfo->execModel = pTaskInfo->execModel; pInfo->win = pTaskInfo->window; pInfo->twAggSup = *pTwAggSupp; pInfo->primaryTsIndex = primaryTsSlotId; size_t keyBufSize = sizeof(int64_t) + sizeof(int64_t) + POINTER_BYTES; initResultSizeInfo(pOperator, 4096); int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, pResBlock, keyBufSize, pTaskInfo->id.str); initExecTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &pInfo->win); pInfo->invertible = allInvertible(pInfo->binfo.pCtx, numOfCols); // pInfo->pTableQueryInfo = initTableQueryInfo(pTableGroupInfo); if (code != TSDB_CODE_SUCCESS /* || pInfo->pTableQueryInfo == NULL*/) { goto _error; } initResultRowInfo(&pInfo->binfo.resultRowInfo, (int32_t)1); pOperator->name = "TimeIntervalAggOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_INTERVAL; pOperator->blocking = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExprInfo; pOperator->pTaskInfo = pTaskInfo; pOperator->numOfExprs = numOfCols; pOperator->info = pInfo; pOperator->fpSet = createOperatorFpSet(doOpenIntervalAgg, doBuildIntervalResult, doStreamIntervalAgg, NULL, destroyIntervalOperatorInfo, aggEncodeResultRow, aggDecodeResultRow, NULL); code = appendDownstream(pOperator, &downstream, 1); if (code != TSDB_CODE_SUCCESS) { goto _error; } return pOperator; _error: destroyIntervalOperatorInfo(pInfo, numOfCols); taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); pTaskInfo->code = code; return NULL; } SOperatorInfo* createStreamIntervalOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResBlock, SInterval* pInterval, int32_t primaryTsSlotId, STimeWindowAggSupp* pTwAggSupp, const STableGroupInfo* pTableGroupInfo, SExecTaskInfo* pTaskInfo) { SIntervalAggOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SIntervalAggOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->order = TSDB_ORDER_ASC; pInfo->interval = *pInterval; pInfo->execModel = OPTR_EXEC_MODEL_STREAM; pInfo->win = pTaskInfo->window; pInfo->twAggSup = *pTwAggSupp; pInfo->primaryTsIndex = primaryTsSlotId; int32_t numOfRows = 4096; size_t keyBufSize = sizeof(int64_t) + sizeof(int64_t) + POINTER_BYTES; initResultSizeInfo(pOperator, numOfRows); int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, pResBlock, keyBufSize, pTaskInfo->id.str); initExecTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &pInfo->win); // pInfo->pTableQueryInfo = initTableQueryInfo(pTableGroupInfo); if (code != TSDB_CODE_SUCCESS /* || pInfo->pTableQueryInfo == NULL*/) { goto _error; } initResultRowInfo(&pInfo->binfo.resultRowInfo, (int32_t)1); pOperator->name = "StreamTimeIntervalAggOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_INTERVAL; pOperator->blocking = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExprInfo; pOperator->pTaskInfo = pTaskInfo; pOperator->numOfExprs = numOfCols; pOperator->info = pInfo; pOperator->fpSet = createOperatorFpSet(doOpenIntervalAgg, doStreamIntervalAgg, doStreamIntervalAgg, NULL, destroyIntervalOperatorInfo, aggEncodeResultRow, aggDecodeResultRow, NULL); code = appendDownstream(pOperator, &downstream, 1); if (code != TSDB_CODE_SUCCESS) { goto _error; } return pOperator; _error: destroyIntervalOperatorInfo(pInfo, numOfCols); taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); pTaskInfo->code = code; return NULL; } // todo handle multiple tables cases. static void doSessionWindowAggImpl(SOperatorInfo* pOperator, SSessionAggOperatorInfo* pInfo, SSDataBlock* pBlock) { SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SColumnInfoData* pColInfoData = taosArrayGet(pBlock->pDataBlock, pInfo->tsSlotId); bool masterScan = true; int32_t numOfOutput = pOperator->numOfExprs; int64_t gid = pBlock->info.groupId; int64_t gap = pInfo->gap; if (!pInfo->reptScan) { pInfo->reptScan = true; pInfo->winSup.prevTs = INT64_MIN; } SWindowRowsSup* pRowSup = &pInfo->winSup; pRowSup->numOfRows = 0; // In case of ascending or descending order scan data, only one time window needs to be kepted for each table. TSKEY* tsList = (TSKEY*)pColInfoData->pData; for (int32_t j = 0; j < pBlock->info.rows; ++j) { if (pInfo->winSup.prevTs == INT64_MIN) { doKeepNewWindowStartInfo(pRowSup, tsList, j); doKeepTuple(pRowSup, tsList[j]); } else if (tsList[j] - pRowSup->prevTs <= gap && (tsList[j] - pRowSup->prevTs) >= 0) { // The gap is less than the threshold, so it belongs to current session window that has been opened already. doKeepTuple(pRowSup, tsList[j]); if (j == 0 && pRowSup->startRowIndex != 0) { pRowSup->startRowIndex = 0; } } else { // start a new session window SResultRow* pResult = NULL; // keep the time window for the closed time window. STimeWindow window = pRowSup->win; pRowSup->win.ekey = pRowSup->win.skey; int32_t ret = setTimeWindowOutputBuf(&pInfo->binfo.resultRowInfo, &window, masterScan, &pResult, gid, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS) { // null data, too many state code longjmp(pTaskInfo->env, TSDB_CODE_QRY_APP_ERROR); } // pInfo->numOfRows data belong to the current session window updateTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &window, false); doApplyFunctions(pInfo->binfo.pCtx, &window, &pInfo->twAggSup.timeWindowData, pRowSup->startRowIndex, pRowSup->numOfRows, NULL, pBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); // here we start a new session window doKeepNewWindowStartInfo(pRowSup, tsList, j); doKeepTuple(pRowSup, tsList[j]); } } SResultRow* pResult = NULL; pRowSup->win.ekey = tsList[pBlock->info.rows - 1]; int32_t ret = setTimeWindowOutputBuf(&pInfo->binfo.resultRowInfo, &pRowSup->win, masterScan, &pResult, gid, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset, &pInfo->aggSup, pTaskInfo); if (ret != TSDB_CODE_SUCCESS) { // null data, too many state code longjmp(pTaskInfo->env, TSDB_CODE_QRY_APP_ERROR); } updateTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &pRowSup->win, false); doApplyFunctions(pInfo->binfo.pCtx, &pRowSup->win, &pInfo->twAggSup.timeWindowData, pRowSup->startRowIndex, pRowSup->numOfRows, NULL, pBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); } static SSDataBlock* doSessionWindowAgg(SOperatorInfo* pOperator) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SSessionAggOperatorInfo* pInfo = pOperator->info; SOptrBasicInfo* pBInfo = &pInfo->binfo; if (pOperator->status == OP_RES_TO_RETURN) { doBuildResultDatablock(pBInfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); return NULL; } return pBInfo->pRes; } int32_t order = TSDB_ORDER_ASC; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->fpSet.getNextFn(downstream); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pBInfo->pCtx, pBlock, order, true); doSessionWindowAggImpl(pOperator, pInfo, pBlock); } // restore the value pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pBInfo->resultRowInfo); finalizeMultiTupleQueryResult(pBInfo->pCtx, pOperator->numOfExprs, pInfo->aggSup.pResultBuf, &pBInfo->resultRowInfo, pBInfo->rowCellInfoOffset); initGroupedResultInfo(&pInfo->groupResInfo, pInfo->aggSup.pResultRowHashTable, true); blockDataEnsureCapacity(pBInfo->pRes, pOperator->resultInfo.capacity); doBuildResultDatablock(pBInfo, &pInfo->groupResInfo, pOperator->pExpr, pInfo->aggSup.pResultBuf); if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pBInfo->pRes->info.rows == 0 ? NULL : pBInfo->pRes; } static SSDataBlock* doAllIntervalAgg(SOperatorInfo* pOperator) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } STimeSliceOperatorInfo* pSliceInfo = pOperator->info; if (pOperator->status == OP_RES_TO_RETURN) { // doBuildResultDatablock(&pRuntimeEnv->groupResInfo, pRuntimeEnv, pIntervalInfo->pRes); if (pSliceInfo->binfo.pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pSliceInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pSliceInfo->binfo.pRes; } int32_t order = TSDB_ORDER_ASC; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->fpSet.getNextFn(downstream); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // setTagValue(pOperator, pRuntimeEnv->current->pTable, pIntervalInfo->pCtx, pOperator->numOfExprs); // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pSliceInfo->binfo.pCtx, pBlock, order, true); // hashAllIntervalAgg(pOperator, &pSliceInfo->binfo.resultRowInfo, pBlock, 0); } // restore the value pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pSliceInfo->binfo.resultRowInfo); setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); // finalizeQueryResult(pSliceInfo->binfo.pCtx, pOperator->numOfExprs); // initGroupedResultInfo(&pSliceInfo->groupResInfo, &pSliceInfo->binfo.resultRowInfo); // doBuildResultDatablock(&pRuntimeEnv->groupResInfo, pRuntimeEnv, pSliceInfo->pRes); if (pSliceInfo->binfo.pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pSliceInfo->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } return pSliceInfo->binfo.pRes->info.rows == 0 ? NULL : pSliceInfo->binfo.pRes; } SOperatorInfo* createTimeSliceOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResultBlock, SExecTaskInfo* pTaskInfo) { STimeSliceOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(STimeSliceOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pOperator == NULL || pInfo == NULL) { goto _error; } initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); pOperator->name = "TimeSliceOperator"; // pOperator->operatorType = OP_AllTimeWindow; pOperator->blocking = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExprInfo; pOperator->numOfExprs = numOfCols; pOperator->info = pInfo; pOperator->pTaskInfo = pTaskInfo; pOperator->fpSet = createOperatorFpSet(operatorDummyOpenFn, doAllIntervalAgg, NULL, NULL, destroyBasicOperatorInfo, NULL, NULL, NULL); int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; _error: taosMemoryFree(pInfo); taosMemoryFree(pOperator); pTaskInfo->code = TSDB_CODE_OUT_OF_MEMORY; return NULL; } SOperatorInfo* createStatewindowOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfCols, SSDataBlock* pResBlock, STimeWindowAggSupp* pTwAggSup, int32_t tsSlotId, SExecTaskInfo* pTaskInfo) { SStateWindowOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SStateWindowOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->colIndex = -1; size_t keyBufSize = sizeof(int64_t) + sizeof(int64_t) + POINTER_BYTES; initResultSizeInfo(pOperator, 4096); initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExpr, numOfCols, pResBlock, keyBufSize, pTaskInfo->id.str); initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); pInfo->twAggSup = *pTwAggSup; initExecTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &pTaskInfo->window); pInfo->tsSlotId = tsSlotId; pOperator->name = "StateWindowOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_STATE_WINDOW; pOperator->blocking = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExpr; pOperator->numOfExprs = numOfCols; pOperator->pTaskInfo = pTaskInfo; pOperator->info = pInfo; pOperator->fpSet = createOperatorFpSet(operatorDummyOpenFn, doStateWindowAgg, NULL, NULL, destroyStateWindowOperatorInfo, aggEncodeResultRow, aggDecodeResultRow, NULL); int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; _error: pTaskInfo->code = TSDB_CODE_SUCCESS; return NULL; } void destroySWindowOperatorInfo(void* param, int32_t numOfOutput) { SSessionAggOperatorInfo* pInfo = (SSessionAggOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); } SOperatorInfo* createSessionAggOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResBlock, int64_t gap, int32_t tsSlotId, STimeWindowAggSupp* pTwAggSupp, SExecTaskInfo* pTaskInfo) { SSessionAggOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SSessionAggOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } size_t keyBufSize = sizeof(int64_t) + sizeof(int64_t) + POINTER_BYTES; initResultSizeInfo(pOperator, 4096); int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, pResBlock, keyBufSize, pTaskInfo->id.str); if (code != TSDB_CODE_SUCCESS) { goto _error; } pInfo->twAggSup = *pTwAggSupp; initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); initExecTimeWindowInfo(&pInfo->twAggSup.timeWindowData, &pTaskInfo->window); pInfo->tsSlotId = tsSlotId; pInfo->gap = gap; pInfo->binfo.pRes = pResBlock; pInfo->winSup.prevTs = INT64_MIN; pInfo->reptScan = false; pOperator->name = "SessionWindowAggOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_SESSION_WINDOW; pOperator->blocking = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExprInfo; pOperator->numOfExprs = numOfCols; pOperator->info = pInfo; pOperator->fpSet = createOperatorFpSet(operatorDummyOpenFn, doSessionWindowAgg, NULL, NULL, destroySWindowOperatorInfo, aggEncodeResultRow, aggDecodeResultRow, NULL); pOperator->pTaskInfo = pTaskInfo; code = appendDownstream(pOperator, &downstream, 1); return pOperator; _error: if (pInfo != NULL) { destroySWindowOperatorInfo(pInfo, numOfCols); } taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); pTaskInfo->code = code; return NULL; }