/* * 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 "filter.h" #include "functionMgt.h" #include "function.h" #include "querynodes.h" #include "tname.h" #include "os.h" #include "parser.h" #include "tdatablock.h" #include "texception.h" #include "tglobal.h" #include "tmsg.h" #include "tsort.h" #include "ttime.h" #include "executorimpl.h" #include "function.h" #include "query.h" #include "tcompare.h" #include "tcompression.h" #include "thash.h" #include "tsdb.h" #include "ttypes.h" #include "vnode.h" #define IS_MAIN_SCAN(runtime) ((runtime)->scanFlag == MAIN_SCAN) #define IS_REVERSE_SCAN(runtime) ((runtime)->scanFlag == REVERSE_SCAN) #define IS_REPEAT_SCAN(runtime) ((runtime)->scanFlag == REPEAT_SCAN) #define SET_MAIN_SCAN_FLAG(runtime) ((runtime)->scanFlag = MAIN_SCAN) #define SET_REVERSE_SCAN_FLAG(runtime) ((runtime)->scanFlag = REVERSE_SCAN) #define TSWINDOW_IS_EQUAL(t1, t2) (((t1).skey == (t2).skey) && ((t1).ekey == (t2).ekey)) #define SDATA_BLOCK_INITIALIZER \ (SDataBlockInfo) { {0}, 0 } #define GET_FORWARD_DIRECTION_FACTOR(ord) (((ord) == TSDB_ORDER_ASC) ? QUERY_ASC_FORWARD_STEP : QUERY_DESC_FORWARD_STEP) enum { TS_JOIN_TS_EQUAL = 0, TS_JOIN_TS_NOT_EQUALS = 1, TS_JOIN_TAG_NOT_EQUALS = 2, }; typedef enum SResultTsInterpType { RESULT_ROW_START_INTERP = 1, RESULT_ROW_END_INTERP = 2, } SResultTsInterpType; #if 0 static UNUSED_FUNC void *u_malloc (size_t __size) { uint32_t v = taosRand(); if (v % 1000 <= 0) { return NULL; } else { return taosMemoryMalloc(__size); } } static UNUSED_FUNC void* u_calloc(size_t num, size_t __size) { uint32_t v = taosRand(); if (v % 1000 <= 0) { return NULL; } else { return taosMemoryCalloc(num, __size); } } static UNUSED_FUNC void* u_realloc(void* p, size_t __size) { uint32_t v = taosRand(); if (v % 5 <= 1) { return NULL; } else { return taosMemoryRealloc(p, __size); } } #define calloc u_calloc #define malloc u_malloc #define realloc u_realloc #endif #define CLEAR_QUERY_STATUS(q, st) ((q)->status &= (~(st))) #define GET_NUM_OF_TABLEGROUP(q) taosArrayGetSize((q)->tableqinfoGroupInfo.pGroupList) #define QUERY_IS_INTERVAL_QUERY(_q) ((_q)->interval.interval > 0) #define TSKEY_MAX_ADD(a, b) \ do { \ if (a < 0) { \ a = a + b; \ break; \ } \ if (sizeof(a) == sizeof(int32_t)) { \ if ((b) > 0 && ((b) >= INT32_MAX - (a))) { \ a = INT32_MAX; \ } else { \ a = a + b; \ } \ } else { \ if ((b) > 0 && ((b) >= INT64_MAX - (a))) { \ a = INT64_MAX; \ } else { \ a = a + b; \ } \ } \ } while (0) #define TSKEY_MIN_SUB(a, b) \ do { \ if (a >= 0) { \ a = a + b; \ break; \ } \ if (sizeof(a) == sizeof(int32_t)) { \ if ((b) < 0 && ((b) <= INT32_MIN - (a))) { \ a = INT32_MIN; \ } else { \ a = a + b; \ } \ } else { \ if ((b) < 0 && ((b) <= INT64_MIN - (a))) { \ a = INT64_MIN; \ } else { \ a = a + b; \ } \ } \ } while (0) int32_t getMaximumIdleDurationSec() { return tsShellActivityTimer * 2; } static int32_t getExprFunctionId(SExprInfo* pExprInfo) { assert(pExprInfo != NULL && pExprInfo->pExpr != NULL && pExprInfo->pExpr->nodeType == TEXPR_UNARYEXPR_NODE); return 0; } 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)mktime(&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)mktime(&tm) * 1000L, TSDB_TIME_PRECISION_MILLI, precision); tw->ekey -= 1; } static void doSetTagValueToResultBuf(char* output, const char* val, int16_t type, int16_t bytes); void setResultRowOutputBufInitCtx(STaskRuntimeEnv* pRuntimeEnv, SResultRow* pResult, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset); static bool functionNeedToExecute(SqlFunctionCtx* pCtx); static void setBlockStatisInfo(SqlFunctionCtx* pCtx, SSDataBlock* pSDataBlock, SColumn* pColumn); static void destroyTableQueryInfoImpl(STableQueryInfo* pTableQueryInfo); static bool hasMainOutput(STaskAttr* pQueryAttr); static SColumnInfo* extractColumnFilterInfo(SExprInfo* pExpr, int32_t numOfOutput, int32_t* numOfFilterCols); static int32_t setTimestampListJoinInfo(STaskRuntimeEnv* pRuntimeEnv, SVariant* pTag, STableQueryInfo* pTableQueryInfo); static void releaseQueryBuf(size_t numOfTables); static int32_t binarySearchForKey(char* pValue, int num, TSKEY key, int order); // static STsdbQueryCond createTsdbQueryCond(STaskAttr* pQueryAttr, STimeWindow* win); static STableIdInfo createTableIdInfo(STableQueryInfo* pTableQueryInfo); static int32_t getNumOfScanTimes(STaskAttr* pQueryAttr); static void destroyBasicOperatorInfo(void* param, int32_t numOfOutput); static void destroySFillOperatorInfo(void* param, int32_t numOfOutput); static void destroyProjectOperatorInfo(void* param, int32_t numOfOutput); static void destroyTagScanOperatorInfo(void* param, int32_t numOfOutput); static void destroyOrderOperatorInfo(void* param, int32_t numOfOutput); static void destroySWindowOperatorInfo(void* param, int32_t numOfOutput); static void destroyStateWindowOperatorInfo(void* param, int32_t numOfOutput); static void destroyAggOperatorInfo(void* param, int32_t numOfOutput); static void destroyIntervalOperatorInfo(void* param, int32_t numOfOutput); static void destroyExchangeOperatorInfo(void* param, int32_t numOfOutput); static void destroyConditionOperatorInfo(void* param, int32_t numOfOutput); static void destroyOperatorInfo(SOperatorInfo* pOperator); static void destroySysTableScannerOperatorInfo(void* param, int32_t numOfOutput); void doSetOperatorCompleted(SOperatorInfo* pOperator) { pOperator->status = OP_EXEC_DONE; if (pOperator->pTaskInfo != NULL) { setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); } } #define OPTR_IS_OPENED(_optr) (((_optr)->status & OP_OPENED) == OP_OPENED) #define OPTR_SET_OPENED(_optr) ((_optr)->status |= OP_OPENED) int32_t operatorDummyOpenFn(SOperatorInfo* pOperator) { OPTR_SET_OPENED(pOperator); return TSDB_CODE_SUCCESS; } void operatorDummyCloseFn(void* param, int32_t numOfCols) {} static int32_t doCopyToSDataBlock(SDiskbasedBuf* pBuf, SGroupResInfo* pGroupResInfo, int32_t orderType, SSDataBlock* pBlock, int32_t rowCapacity, int32_t* rowCellOffset); static void initCtxOutputBuffer(SqlFunctionCtx* pCtx, int32_t size); static void getAlignQueryTimeWindow(SInterval* pInterval, int32_t precision, int64_t key, int64_t keyFirst, int64_t keyLast, STimeWindow* win); static void setResultBufSize(STaskAttr* pQueryAttr, SResultInfo* pResultInfo); static void setCtxTagForJoin(STaskRuntimeEnv* pRuntimeEnv, SqlFunctionCtx* pCtx, SExprInfo* pExprInfo, void* pTable); static void doSetTableGroupOutputBuf(SAggOperatorInfo* pAggInfo, int32_t numOfOutput, int32_t tableGroupId, SExecTaskInfo* pTaskInfo); SArray* getOrderCheckColumns(STaskAttr* pQuery); typedef struct SRowCompSupporter { STaskRuntimeEnv* pRuntimeEnv; int16_t dataOffset; __compar_fn_t comFunc; } SRowCompSupporter; static int compareRowData(const void* a, const void* b, const void* userData) { const SResultRow* pRow1 = (const SResultRow*)a; const SResultRow* pRow2 = (const SResultRow*)b; SRowCompSupporter* supporter = (SRowCompSupporter*)userData; STaskRuntimeEnv* pRuntimeEnv = supporter->pRuntimeEnv; SFilePage* page1 = getBufPage(pRuntimeEnv->pResultBuf, pRow1->pageId); SFilePage* page2 = getBufPage(pRuntimeEnv->pResultBuf, pRow2->pageId); int16_t offset = supporter->dataOffset; char* in1 = getPosInResultPage(pRuntimeEnv->pQueryAttr, page1, pRow1->offset, offset); char* in2 = getPosInResultPage(pRuntimeEnv->pQueryAttr, page2, pRow2->offset, offset); return (in1 != NULL && in2 != NULL) ? supporter->comFunc(in1, in2) : 0; } // setup the output buffer for each operator SSDataBlock* createOutputBuf_rv1(SDataBlockDescNode* pNode) { int32_t numOfCols = LIST_LENGTH(pNode->pSlots); SSDataBlock* pBlock = taosMemoryCalloc(1, sizeof(SSDataBlock)); pBlock->info.numOfCols = numOfCols; pBlock->pDataBlock = taosArrayInit(numOfCols, sizeof(SColumnInfoData)); pBlock->info.blockId = pNode->dataBlockId; pBlock->info.rowSize = pNode->totalRowSize; // todo ?? for (int32_t i = 0; i < numOfCols; ++i) { SColumnInfoData idata = {{0}}; SSlotDescNode* pDescNode = nodesListGetNode(pNode->pSlots, i); if (!pDescNode->output) { continue; } idata.info.type = pDescNode->dataType.type; idata.info.bytes = pDescNode->dataType.bytes; idata.info.scale = pDescNode->dataType.scale; idata.info.slotId = pDescNode->slotId; idata.info.precision = pDescNode->dataType.precision; taosArrayPush(pBlock->pDataBlock, &idata); } return pBlock; } static bool isSelectivityWithTagsQuery(SqlFunctionCtx* pCtx, int32_t numOfOutput) { return true; // bool hasTags = false; // int32_t numOfSelectivity = 0; // // for (int32_t i = 0; i < numOfOutput; ++i) { // int32_t functId = pCtx[i].functionId; // if (functId == FUNCTION_TAG_DUMMY || functId == FUNCTION_TS_DUMMY) { // hasTags = true; // continue; // } // // if ((aAggs[functId].status & FUNCSTATE_SELECTIVITY) != 0) { // numOfSelectivity++; // } // } // // return (numOfSelectivity > 0 && hasTags); } static bool hasNull(SColumn* pColumn, SColumnDataAgg* pStatis) { if (TSDB_COL_IS_TAG(pColumn->flag) || TSDB_COL_IS_UD_COL(pColumn->flag) || pColumn->colId == PRIMARYKEY_TIMESTAMP_COL_ID) { return false; } if (pStatis != NULL && pStatis->numOfNull == 0) { return false; } return true; } static void prepareResultListBuffer(SResultRowInfo* pResultRowInfo, jmp_buf env) { int64_t newCapacity = 0; // more than the capacity, reallocate the resources if (pResultRowInfo->size < pResultRowInfo->capacity) { return; } if (pResultRowInfo->capacity > 10000) { newCapacity = (int64_t)(pResultRowInfo->capacity * 1.25); } else { newCapacity = (int64_t)(pResultRowInfo->capacity * 1.5); } if (newCapacity == pResultRowInfo->capacity) { newCapacity += 4; } pResultRowInfo->pPosition = taosMemoryRealloc(pResultRowInfo->pPosition, newCapacity * sizeof(SResultRowPosition)); int32_t inc = (int32_t)newCapacity - pResultRowInfo->capacity; memset(&pResultRowInfo->pPosition[pResultRowInfo->capacity], 0, sizeof(SResultRowPosition)); pResultRowInfo->capacity = (int32_t)newCapacity; } static bool chkResultRowFromKey(STaskRuntimeEnv* pRuntimeEnv, SResultRowInfo* pResultRowInfo, char* pData, int16_t bytes, bool masterscan, uint64_t uid) { bool existed = false; SET_RES_WINDOW_KEY(pRuntimeEnv->keyBuf, pData, bytes, uid); SResultRow** p1 = (SResultRow**)taosHashGet(pRuntimeEnv->pResultRowHashTable, pRuntimeEnv->keyBuf, GET_RES_WINDOW_KEY_LEN(bytes)); // in case of repeat scan/reverse scan, no new time window added. if (QUERY_IS_INTERVAL_QUERY(pRuntimeEnv->pQueryAttr)) { if (!masterscan) { // the *p1 may be NULL in case of sliding+offset exists. return p1 != NULL; } if (p1 != NULL) { if (pResultRowInfo->size == 0) { existed = false; } else if (pResultRowInfo->size == 1) { // existed = (pResultRowInfo->pResult[0] == (*p1)); } else { // check if current pResultRowInfo contains the existed pResultRow SET_RES_EXT_WINDOW_KEY(pRuntimeEnv->keyBuf, pData, bytes, uid, pResultRowInfo); int64_t* index = taosHashGet(pRuntimeEnv->pResultRowListSet, pRuntimeEnv->keyBuf, GET_RES_EXT_WINDOW_KEY_LEN(bytes)); if (index != NULL) { existed = true; } else { existed = false; } } } return existed; } return p1 != NULL; } #if 0 static SResultRow* doSetResultOutBufByKey(STaskRuntimeEnv* pRuntimeEnv, SResultRowInfo* pResultRowInfo, int64_t tid, char* pData, int16_t bytes, bool masterscan, uint64_t tableGroupId) { bool existed = false; SET_RES_WINDOW_KEY(pRuntimeEnv->keyBuf, pData, bytes, tableGroupId); SResultRow** p1 = (SResultRow**)taosHashGet(pRuntimeEnv->pResultRowHashTable, pRuntimeEnv->keyBuf, GET_RES_WINDOW_KEY_LEN(bytes)); // in case of repeat scan/reverse scan, no new time window added. if (QUERY_IS_INTERVAL_QUERY(pRuntimeEnv->pQueryAttr)) { if (!masterscan) { // the *p1 may be NULL in case of sliding+offset exists. return (p1 != NULL) ? *p1 : NULL; } if (p1 != NULL) { if (pResultRowInfo->size == 0) { existed = false; // assert(pResultRowInfo->curPos == -1); } else if (pResultRowInfo->size == 1) { // existed = (pResultRowInfo->pResult[0] == (*p1)); // pResultRowInfo->curPos = 0; } else { // check if current pResultRowInfo contains the existed pResultRow SET_RES_EXT_WINDOW_KEY(pRuntimeEnv->keyBuf, pData, bytes, tid, pResultRowInfo); int64_t* index = taosHashGet(pRuntimeEnv->pResultRowListSet, pRuntimeEnv->keyBuf, GET_RES_EXT_WINDOW_KEY_LEN(bytes)); if (index != NULL) { // pResultRowInfo->curPos = (int32_t)*index; existed = true; } else { existed = false; } } } } else { // In case of group by column query, the required SResultRow object must be existed in the pResultRowInfo object. if (p1 != NULL) { return *p1; } } if (!existed) { // prepareResultListBuffer(pResultRowInfo, pRuntimeEnv); SResultRow* pResult = NULL; if (p1 == NULL) { pResult = getNewResultRow(pRuntimeEnv->pool); int32_t ret = initResultRow(pResult); if (ret != TSDB_CODE_SUCCESS) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } // add a new result set for a new group taosHashPut(pRuntimeEnv->pResultRowHashTable, pRuntimeEnv->keyBuf, GET_RES_WINDOW_KEY_LEN(bytes), &pResult, POINTER_BYTES); SResultRowCell cell = {.groupId = tableGroupId, .pRow = pResult}; taosArrayPush(pRuntimeEnv->pResultRowArrayList, &cell); } else { pResult = *p1; } pResultRowInfo->curPos = pResultRowInfo->size; pResultRowInfo->pResult[pResultRowInfo->size++] = pResult; int64_t index = pResultRowInfo->curPos; SET_RES_EXT_WINDOW_KEY(pRuntimeEnv->keyBuf, pData, bytes, tid, pResultRowInfo); taosHashPut(pRuntimeEnv->pResultRowListSet, pRuntimeEnv->keyBuf, GET_RES_EXT_WINDOW_KEY_LEN(bytes), &index, POINTER_BYTES); } // too many time window in query if (pResultRowInfo->size > MAX_INTERVAL_TIME_WINDOW) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_TOO_MANY_TIMEWINDOW); } return pResultRowInfo->pResult[pResultRowInfo->curPos]; } #endif SResultRow* getNewResultRow_rv(SDiskbasedBuf* pResultBuf, int64_t tableGroupId, int32_t interBufSize) { SFilePage* pData = NULL; // in the first scan, new space needed for results int32_t pageId = -1; SIDList list = getDataBufPagesIdList(pResultBuf, tableGroupId); if (taosArrayGetSize(list) == 0) { pData = getNewBufPage(pResultBuf, tableGroupId, &pageId); pData->num = sizeof(SFilePage); } else { SPageInfo* pi = getLastPageInfo(list); pData = getBufPage(pResultBuf, getPageId(pi)); pageId = getPageId(pi); if (pData->num + interBufSize + sizeof(SResultRow) > getBufPageSize(pResultBuf)) { // release current page first, and prepare the next one releaseBufPageInfo(pResultBuf, pi); pData = getNewBufPage(pResultBuf, tableGroupId, &pageId); if (pData != NULL) { pData->num = sizeof(SFilePage); } } } if (pData == NULL) { return NULL; } // set the number of rows in current disk page SResultRow* pResultRow = (SResultRow*)((char*)pData + pData->num); pResultRow->pageId = pageId; pResultRow->offset = (int32_t)pData->num; pData->num += interBufSize + sizeof(SResultRow); return pResultRow; } static SResultRow* doSetResultOutBufByKey_rv(SDiskbasedBuf* pResultBuf, SResultRowInfo* pResultRowInfo, int64_t tid, char* pData, int16_t bytes, bool masterscan, uint64_t tableGroupId, SExecTaskInfo* pTaskInfo, bool isIntervalQuery, SAggSupporter* pSup) { bool existInCurrentResusltRowInfo = false; SET_RES_WINDOW_KEY(pSup->keyBuf, pData, bytes, tableGroupId); SResultRowPosition* p1 = (SResultRowPosition*)taosHashGet(pSup->pResultRowHashTable, pSup->keyBuf, GET_RES_WINDOW_KEY_LEN(bytes)); // in case of repeat scan/reverse scan, no new time window added. if (isIntervalQuery) { if (!masterscan) { // the *p1 may be NULL in case of sliding+offset exists. if (p1 != NULL) { return getResultRowByPos(pResultBuf, p1); } else { return NULL; } } if (p1 != NULL) { if (pResultRowInfo->size == 0) { existInCurrentResusltRowInfo = false; // this time window created by other timestamp that does not belongs to current table. assert(pResultRowInfo->curPos == -1); } else if (pResultRowInfo->size == 1) { ASSERT(0); // existInCurrentResusltRowInfo = (pResultRowInfo->pResult[0] == (*p1)); } else { // check if current pResultRowInfo contains the existInCurrentResusltRowInfo pResultRow SET_RES_EXT_WINDOW_KEY(pSup->keyBuf, pData, bytes, tid, pResultRowInfo); int64_t* index = taosHashGet(pSup->pResultRowListSet, pSup->keyBuf, GET_RES_EXT_WINDOW_KEY_LEN(bytes)); if (index != NULL) { // TODO check the scan order for current opened time window // pResultRowInfo->curPos = (int32_t)*index; existInCurrentResusltRowInfo = true; } else { existInCurrentResusltRowInfo = false; } } } } else { // In case of group by column query, the required SResultRow object must be existInCurrentResusltRowInfo in the pResultRowInfo object. if (p1 != NULL) { return getResultRowByPos(pResultBuf, p1); } } SResultRow* pResult = NULL; if (!existInCurrentResusltRowInfo) { // 1. close current opened time window if (pResultRowInfo->curPos != -1) { // todo extract function SResultRowPosition* pos = &pResultRowInfo->pPosition[pResultRowInfo->curPos]; SFilePage* pPage = getBufPage(pResultBuf, pos->pageId); SResultRow* pRow = (SResultRow*)((char*)pPage + pos->offset); closeResultRow(pRow); releaseBufPage(pResultBuf, pPage); } prepareResultListBuffer(pResultRowInfo, pTaskInfo->env); if (p1 == NULL) { pResult = getNewResultRow_rv(pResultBuf, tableGroupId, pSup->resultRowSize); initResultRow(pResult); // add a new result set for a new group SResultRowPosition pos = {.pageId = pResult->pageId, .offset = pResult->offset}; taosHashPut(pSup->pResultRowHashTable, pSup->keyBuf, GET_RES_WINDOW_KEY_LEN(bytes), &pos, POINTER_BYTES); SResultRowCell cell = {.groupId = tableGroupId, .pos = pos}; taosArrayPush(pSup->pResultRowArrayList, &cell); } else { pResult = getResultRowByPos(pResultBuf, p1); } // 2. set the new time window to be the new active time window pResultRowInfo->curPos = pResultRowInfo->size; pResultRowInfo->pPosition[pResultRowInfo->size++] = (SResultRowPosition){.pageId = pResult->pageId, .offset = pResult->offset}; int64_t index = pResultRowInfo->curPos; SET_RES_EXT_WINDOW_KEY(pSup->keyBuf, pData, bytes, tid, pResultRowInfo); taosHashPut(pSup->pResultRowListSet, pSup->keyBuf, GET_RES_EXT_WINDOW_KEY_LEN(bytes), &index, POINTER_BYTES); } // too many time window in query if (pResultRowInfo->size > MAX_INTERVAL_TIME_WINDOW) { longjmp(pTaskInfo->env, TSDB_CODE_QRY_TOO_MANY_TIMEWINDOW); } return pResult; } static void getInitialStartTimeWindow(SInterval* pInterval, int32_t precision, TSKEY ts, STimeWindow* w, TSKEY ekey, bool ascQuery) { if (ascQuery) { getAlignQueryTimeWindow(pInterval, precision, ts, ts, ekey, w); } else { // the start position of the first time window in the endpoint that spreads beyond the queried last timestamp getAlignQueryTimeWindow(pInterval, precision, ts, ekey, 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->curPos == -1) { // the first window, from the previous stored value getInitialStartTimeWindow(pInterval, precision, ts, &w, win->ekey, true); w.ekey = taosTimeAdd(w.skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } else { w = getResultRow(pBuf, pResultRowInfo, pResultRowInfo->curPos)->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; } // get the correct time window according to the handled timestamp static STimeWindow getCurrentActiveTimeWindow(SResultRowInfo* pResultRowInfo, int64_t ts, STaskAttr* pQueryAttr) { STimeWindow w = {0}; #if 0 if (pResultRowInfo->curPos == -1) { // the first window, from the previous stored value // getInitialStartTimeWindow(pQueryAttr, ts, &w); if (pQueryAttr->interval.intervalUnit == 'n' || pQueryAttr->interval.intervalUnit == 'y') { w.ekey = taosTimeAdd(w.skey, pQueryAttr->interval.interval, pQueryAttr->interval.intervalUnit, pQueryAttr->precision) - 1; } else { w.ekey = w.skey + pQueryAttr->interval.interval - 1; } } else { w = pRow->win; } /* * query border check, skey should not be bounded by the query time range, since the value skey will * be used as the time window index value. So we only change ekey of time window accordingly. */ if (w.ekey > pQueryAttr->window.ekey && QUERY_IS_ASC_QUERY(pQueryAttr)) { w.ekey = pQueryAttr->window.ekey; } #endif return w; } // a new buffer page for each table. Needs to opt this design static int32_t addNewWindowResultBuf(SResultRow* pWindowRes, SDiskbasedBuf* pResultBuf, int32_t tid, uint32_t size) { if (pWindowRes->pageId != -1) { return 0; } SFilePage* pData = NULL; // in the first scan, new space needed for results int32_t pageId = -1; SIDList list = getDataBufPagesIdList(pResultBuf, tid); if (taosArrayGetSize(list) == 0) { pData = getNewBufPage(pResultBuf, tid, &pageId); pData->num = sizeof(SFilePage); } else { SPageInfo* pi = getLastPageInfo(list); pData = getBufPage(pResultBuf, getPageId(pi)); pageId = getPageId(pi); if (pData->num + size > getBufPageSize(pResultBuf)) { // release current page first, and prepare the next one releaseBufPageInfo(pResultBuf, pi); pData = getNewBufPage(pResultBuf, tid, &pageId); if (pData != NULL) { pData->num = sizeof(SFilePage); } } } if (pData == NULL) { return -1; } // set the number of rows in current disk page if (pWindowRes->pageId == -1) { // not allocated yet, allocate new buffer pWindowRes->pageId = pageId; pWindowRes->offset = (int32_t)pData->num; pData->num += size; assert(pWindowRes->pageId >= 0); } return 0; } static bool chkWindowOutputBufByKey(STaskRuntimeEnv* pRuntimeEnv, SResultRowInfo* pResultRowInfo, STimeWindow* win, bool masterscan, SResultRow** pResult, int64_t groupId, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset) { assert(win->skey <= win->ekey); return chkResultRowFromKey(pRuntimeEnv, pResultRowInfo, (char*)&win->skey, TSDB_KEYSIZE, masterscan, groupId); } static int32_t setResultOutputBufByKey(STaskRuntimeEnv* pRuntimeEnv, SResultRowInfo* pResultRowInfo, int64_t tid, STimeWindow* win, bool masterscan, SResultRow** pResult, int64_t tableGroupId, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset) { assert(win->skey <= win->ekey); SDiskbasedBuf* pResultBuf = pRuntimeEnv->pResultBuf; SResultRow* pResultRow = NULL;//doSetResultOutBufByKey(pRuntimeEnv, pResultRowInfo, tid, (char*)&win->skey, TSDB_KEYSIZE, // masterscan, tableGroupId); if (pResultRow == NULL) { *pResult = NULL; return TSDB_CODE_SUCCESS; } // not assign result buffer yet, add new result buffer if (pResultRow->pageId == -1) { int32_t ret = addNewWindowResultBuf(pResultRow, pResultBuf, (int32_t)tableGroupId, pRuntimeEnv->pQueryAttr->intermediateResultRowSize); if (ret != TSDB_CODE_SUCCESS) { return -1; } } // set time window for current result pResultRow->win = (*win); *pResult = pResultRow; setResultRowOutputBufInitCtx(pRuntimeEnv, pResultRow, pCtx, numOfOutput, rowCellInfoOffset); return TSDB_CODE_SUCCESS; } static void setResultRowOutputBufInitCtx_rv(SResultRow* pResult, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset); static int32_t setResultOutputBufByKey_rv(SResultRowInfo* pResultRowInfo, int64_t id, 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_rv(pAggSup->pResultBuf, pResultRowInfo, id, (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; setResultRowOutputBufInitCtx_rv(pResultRow, pCtx, numOfOutput, rowCellInfoOffset); return TSDB_CODE_SUCCESS; } 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 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 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 void doUpdateResultRowIndex(SResultRowInfo* pResultRowInfo, TSKEY lastKey, bool ascQuery, bool timeWindowInterpo) { int64_t skey = TSKEY_INITIAL_VAL; #if 0 int32_t i = 0; for (i = pResultRowInfo->size - 1; i >= 0; --i) { SResultRow* pResult = pResultRowInfo->pResult[i]; if (pResult->closed) { break; } // new closed result rows if (timeWindowInterpo) { if (pResult->endInterp && ((pResult->win.skey <= lastKey && ascQuery) || (pResult->win.skey >= lastKey && !ascQuery))) { if (i > 0) { // the first time window, the startInterp is false. assert(pResult->startInterp); } closeResultRow(pResultRowInfo, i); } else { skey = pResult->win.skey; } } else { if ((pResult->win.ekey <= lastKey && ascQuery) || (pResult->win.skey >= lastKey && !ascQuery)) { closeResultRow(pResultRowInfo, i); } else { skey = pResult->win.skey; } } } // all result rows are closed, set the last one to be the skey if (skey == TSKEY_INITIAL_VAL) { if (pResultRowInfo->size == 0) { // assert(pResultRowInfo->current == NULL); assert(pResultRowInfo->curPos == -1); pResultRowInfo->curPos = -1; } else { pResultRowInfo->curPos = pResultRowInfo->size - 1; } } else { for (i = pResultRowInfo->size - 1; i >= 0; --i) { SResultRow* pResult = pResultRowInfo->pResult[i]; if (pResult->closed) { break; } } if (i == pResultRowInfo->size - 1) { pResultRowInfo->curPos = i; } else { pResultRowInfo->curPos = i + 1; // current not closed result object } } #endif } static void updateResultRowInfoActiveIndex(SResultRowInfo* pResultRowInfo, const STimeWindow* pWin, TSKEY lastKey, bool ascQuery, bool interp) { if ((lastKey > pWin->ekey && ascQuery) || (lastKey < pWin->ekey && (!ascQuery))) { closeAllResultRows(pResultRowInfo); pResultRowInfo->curPos = pResultRowInfo->size - 1; } else { int32_t step = ascQuery ? 1 : -1; doUpdateResultRowIndex(pResultRowInfo, lastKey - step, ascQuery, interp); } } 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; } // query_range_start, query_range_end, window_duration, window_start, window_end static void initExecTimeWindowInfo(SColumnInfoData* pColData, STimeWindow* pQueryWindow) { pColData->info.type = TSDB_DATA_TYPE_TIMESTAMP; pColData->info.bytes = sizeof(int64_t); colInfoDataEnsureCapacity(pColData, 5); colDataAppendInt64(pColData, 0, &pQueryWindow->skey); colDataAppendInt64(pColData, 1, &pQueryWindow->ekey); int64_t interval = 0; colDataAppendInt64(pColData, 2, &interval); // this value may be variable in case of 'n' and 'y'. colDataAppendInt64(pColData, 3, &pQueryWindow->skey); colDataAppendInt64(pColData, 4, &pQueryWindow->ekey); } 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 } void doApplyFunctions(SqlFunctionCtx* pCtx, STimeWindow* pWin, SColumnInfoData* pTimeWindowData, int32_t offset, int32_t forwardStep, TSKEY* tsCol, int32_t numOfTotal, int32_t numOfOutput, int32_t order) { for (int32_t k = 0; k < numOfOutput; ++k) { pCtx[k].startTs = pWin->skey; // keep it temporarily bool hasAgg = pCtx[k].input.colDataAggIsSet; int32_t numOfRows = pCtx[k].input.numOfRows; int32_t startOffset = pCtx[k].input.startRowIndex; int32_t pos = (order == TSDB_ORDER_ASC) ? offset : offset - (forwardStep - 1); pCtx[k].input.startRowIndex = pos; pCtx[k].input.numOfRows = forwardStep; if (tsCol != NULL) { pCtx[k].ptsList = tsCol; } // not a whole block involved in query processing, statistics data can not be used // NOTE: the original value of isSet have been changed here if (pCtx[k].isAggSet && forwardStep < numOfTotal) { pCtx[k].isAggSet = false; } if (fmIsWindowPseudoColumnFunc(pCtx[k].functionId)) { SResultRowEntryInfo* pEntryInfo = GET_RES_INFO(&pCtx[k]); char* p = GET_ROWCELL_INTERBUF(pEntryInfo); SColumnInfoData idata = {0}; idata.info.type = TSDB_DATA_TYPE_BIGINT; idata.info.bytes = tDataTypes[TSDB_DATA_TYPE_BIGINT].bytes; idata.pData = p; SScalarParam out = {.columnData = &idata}; SScalarParam tw = {.numOfRows = 5, .columnData = pTimeWindowData}; pCtx[k].sfp.process(&tw, 1, &out); pEntryInfo->numOfRes = 1; continue; } if (functionNeedToExecute(&pCtx[k])) { pCtx[k].fpSet.process(&pCtx[k]); } // restore it pCtx[k].input.colDataAggIsSet = hasAgg; pCtx[k].input.startRowIndex = startOffset; pCtx[k].input.numOfRows = numOfRows; } } static int32_t getNextQualifiedWindow(SInterval* pInterval, STimeWindow* pNext, SDataBlockInfo* pDataBlockInfo, TSKEY* primaryKeys, int32_t prevPosition, STableIntervalOperatorInfo* 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 FORCE_INLINE TSKEY reviseWindowEkey(STaskAttr* pQueryAttr, STimeWindow* pWindow) { TSKEY ekey = -1; if (QUERY_IS_ASC_QUERY(pQueryAttr)) { ekey = pWindow->ekey; if (ekey > pQueryAttr->window.ekey) { ekey = pQueryAttr->window.ekey; } } else { ekey = pWindow->skey; if (ekey < pQueryAttr->window.ekey) { ekey = pQueryAttr->window.ekey; } } return ekey; } 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 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 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 doSetInputDataBlock(SOperatorInfo* pOperator, SqlFunctionCtx* pCtx, SSDataBlock* pBlock, int32_t order); static void doSetInputDataBlockInfo(SOperatorInfo* pOperator, SqlFunctionCtx* pCtx, SSDataBlock* pBlock, int32_t order) { for (int32_t i = 0; i < pOperator->numOfOutput; ++i) { pCtx[i].order = order; pCtx[i].size = pBlock->info.rows; pCtx[i].currentStage = (uint8_t)pOperator->pRuntimeEnv->scanFlag; setBlockStatisInfo(&pCtx[i], pBlock, NULL /*&pOperator->pExpr[i].base.colInfo*/); } } void setInputDataBlock(SOperatorInfo* pOperator, SqlFunctionCtx* pCtx, SSDataBlock* pBlock, int32_t order) { if (pBlock->pDataBlock != NULL) { doSetInputDataBlock(pOperator, pCtx, pBlock, order); } else { doSetInputDataBlockInfo(pOperator, pCtx, pBlock, order); } } static void doSetInputDataBlock(SOperatorInfo* pOperator, SqlFunctionCtx* pCtx, SSDataBlock* pBlock, int32_t order) { for (int32_t i = 0; i < pOperator->numOfOutput; ++i) { pCtx[i].order = order; pCtx[i].size = pBlock->info.rows; pCtx[i].currentStage = MAIN_SCAN; SExprInfo expr = pOperator->pExpr[i]; for (int32_t j = 0; j < expr.base.numOfParams; ++j) { SFunctParam *pFuncParam = &expr.base.pParam[j]; if (pFuncParam->type == FUNC_PARAM_TYPE_COLUMN) { int32_t slotId = pFuncParam->pCol->slotId; pCtx[i].input.pData[j] = taosArrayGet(pBlock->pDataBlock, slotId); pCtx[i].input.totalRows = pBlock->info.rows; pCtx[i].input.numOfRows = pBlock->info.rows; pCtx[i].input.startRowIndex = 0; ASSERT(pCtx[i].input.pData[j] != NULL); } } // setBlockStatisInfo(&pCtx[i], pBlock, pOperator->pExpr[i].base.pColumns); // uint32_t flag = pOperator->pExpr[i].base.pParam[0].pCol->flag; // if (TSDB_COL_IS_NORMAL_COL(flag) /*|| (pCtx[i].functionId == FUNCTION_BLKINFO) || // (TSDB_COL_IS_TAG(flag) && pOperator->pRuntimeEnv->scanFlag == MERGE_STAGE)*/) { // SColumn* pCol = pOperator->pExpr[i].base.pParam[0].pCol; // if (pCtx[i].columnIndex == -1) { // for(int32_t j = 0; j < pBlock->info.numOfCols; ++j) { // SColumnInfoData* pColData = taosArrayGet(pBlock->pDataBlock, j); // if (pColData->info.colId == pCol->colId) { // pCtx[i].columnIndex = j; // break; // } // } // } // in case of the block distribution query, the inputBytes is not a constant value. //pCtx[i].input.pData[0] = taosArrayGet(pBlock->pDataBlock, slotId); //pCtx[i].input.totalRows = pBlock->info.rows; //pCtx[i].input.numOfRows = pBlock->info.rows; //pCtx[i].input.startRowIndex = 0; // uint32_t status = aAggs[pCtx[i].functionId].status; // if ((status & (FUNCSTATE_SELECTIVITY | FUNCSTATE_NEED_TS)) != 0) { // SColumnInfoData* tsInfo = taosArrayGet(pBlock->pDataBlock, 0); // In case of the top/bottom query again the nest query result, which has no timestamp column // don't set the ptsList attribute. // if (tsInfo->info.type == TSDB_DATA_TYPE_TIMESTAMP) { // pCtx[i].ptsList = (int64_t*) tsInfo->pData; // } else { // pCtx[i].ptsList = NULL; // } // } // } else if (TSDB_COL_IS_UD_COL(pCol->flag) && (pOperator->pRuntimeEnv->scanFlag == MERGE_STAGE)) { // SColIndex* pColIndex = &pOperator->pExpr[i].base.colInfo; // SColumnInfoData* p = taosArrayGet(pBlock->pDataBlock, pColIndex->colIndex); // // pCtx[i].pInput = p->pData; // assert(p->info.colId == pColIndex->info.colId && pCtx[i].inputType == p->info.type); // for(int32_t j = 0; j < pBlock->info.rows; ++j) { // char* dst = p->pData + j * p->info.bytes; // taosVariantDump(&pOperator->pExpr[i].base.param[1], dst, p->info.type, true); // } // } } } static void doAggregateImpl(SOperatorInfo* pOperator, TSKEY startTs, SqlFunctionCtx* pCtx) { for (int32_t k = 0; k < pOperator->numOfOutput; ++k) { if (functionNeedToExecute(&pCtx[k])) { pCtx[k].startTs = startTs; // this can be set during create the struct pCtx[k].fpSet.process(&pCtx[k]); } } } static void setPseudoOutputColInfo(SSDataBlock* pResult, SqlFunctionCtx* pCtx, SArray* pPseudoList) { size_t num = (pPseudoList != NULL)? taosArrayGetSize(pPseudoList):0; for (int32_t i = 0; i < num; ++i) { pCtx[i].pOutput = taosArrayGet(pResult->pDataBlock, i); } } static void projectApplyFunctions(SExprInfo* pExpr, SSDataBlock* pResult, SSDataBlock* pSrcBlock, SqlFunctionCtx* pCtx, int32_t numOfOutput, SArray* pPseudoList) { setPseudoOutputColInfo(pResult, pCtx, pPseudoList); for (int32_t k = 0; k < numOfOutput; ++k) { if (pExpr[k].pExpr->nodeType == QUERY_NODE_COLUMN) { // it is a project query SColumnInfoData* pColInfoData = taosArrayGet(pResult->pDataBlock, k); colDataAssign(pColInfoData, pCtx[k].input.pData[0], pCtx[k].input.numOfRows); pResult->info.rows = pCtx[0].input.numOfRows; } else if (pExpr[k].pExpr->nodeType == QUERY_NODE_OPERATOR) { SArray* pBlockList = taosArrayInit(4, POINTER_BYTES); taosArrayPush(pBlockList, &pSrcBlock); SScalarParam dest = {0}; dest.columnData = taosArrayGet(pResult->pDataBlock, k); scalarCalculate(pExpr[k].pExpr->_optrRoot.pRootNode, pBlockList, &dest); pResult->info.rows = dest.numOfRows; taosArrayDestroy(pBlockList); } else if (pExpr[k].pExpr->nodeType == QUERY_NODE_FUNCTION) { ASSERT(!fmIsAggFunc(pCtx[k].functionId)); if (fmIsPseudoColumnFunc(pCtx[k].functionId)) { // do nothing } else if (fmIsNonstandardSQLFunc(pCtx[k].functionId)) { // todo set the correct timestamp column pCtx[k].input.pPTS = taosArrayGet(pSrcBlock->pDataBlock, 1); SResultRowEntryInfo *pResInfo = GET_RES_INFO(&pCtx[k]); pCtx[k].fpSet.init(&pCtx[k], pResInfo); pCtx[k].pOutput = taosArrayGet(pResult->pDataBlock, k); pCtx[k].offset = pResult->info.rows; // set the start offset if (taosArrayGetSize(pPseudoList) > 0) { int32_t* outputColIndex = taosArrayGet(pPseudoList, 0); pCtx[k].pTsOutput = (SColumnInfoData*)pCtx[*outputColIndex].pOutput; } int32_t numOfRows = pCtx[k].fpSet.process(&pCtx[k]); pResult->info.rows += numOfRows; } else { SArray* pBlockList = taosArrayInit(4, POINTER_BYTES); taosArrayPush(pBlockList, &pSrcBlock); SScalarParam dest = {0}; dest.columnData = taosArrayGet(pResult->pDataBlock, k); scalarCalculate((SNode*)pExpr[k].pExpr->_function.pFunctNode, pBlockList, &dest); pResult->info.rows = dest.numOfRows; taosArrayDestroy(pBlockList); } } else if (pExpr[k].pExpr->nodeType == QUERY_NODE_VALUE) { SColumnInfoData* pColInfoData = taosArrayGet(pResult->pDataBlock, k); for (int32_t i = 0; i < pSrcBlock->info.rows; ++i) { colDataAppend(pColInfoData, i, taosVariantGet(&pExpr[k].base.pParam[0].param, pExpr[k].base.pParam[0].type), TSDB_DATA_TYPE_NULL == pExpr[k].base.pParam[0].param.nType); } pResult->info.rows = pSrcBlock->info.rows; } else { ASSERT(0); } } } void doTimeWindowInterpolation(SOperatorInfo* pOperator, SOptrBasicInfo* pInfo, SArray* pDataBlock, TSKEY prevTs, int32_t prevRowIndex, TSKEY curTs, int32_t curRowIndex, TSKEY windowKey, int32_t type) { STaskRuntimeEnv* pRuntimeEnv = pOperator->pRuntimeEnv; SExprInfo* pExpr = pOperator->pExpr; SqlFunctionCtx* pCtx = pInfo->pCtx; for (int32_t k = 0; k < pOperator->numOfOutput; ++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 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->numOfOutput, RESULT_ROW_START_INTERP); return true; } if (lastTs == INT64_MIN && ((pos == 0 && ascQuery) || (pos == (numOfRows - 1) && !ascQuery))) { setNotInterpoWindowKey(pCtx, pOperatorInfo->numOfOutput, 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->numOfOutput; 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 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->numOfOutput, 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->numOfOutput, RESULT_ROW_END_INTERP); } } static SArray* hashIntervalAgg(SOperatorInfo* pOperatorInfo, SResultRowInfo* pResultRowInfo, SSDataBlock* pSDataBlock, int32_t tableGroupId) { STableIntervalOperatorInfo* pInfo = (STableIntervalOperatorInfo*)pOperatorInfo->info; SExecTaskInfo* pTaskInfo = pOperatorInfo->pTaskInfo; int32_t numOfOutput = pOperatorInfo->numOfOutput; SArray* pUpdated = NULL; if (pInfo->execModel == OPTR_EXEC_MODEL_STREAM) { pUpdated = taosArrayInit(4, sizeof(SResultRowPosition)); } 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; // assert(tsCols[0] == pSDataBlock->info.window.skey && tsCols[pSDataBlock->info.rows - 1] == // pSDataBlock->info.window.ekey); } 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 = setResultOutputBufByKey_rv(pResultRowInfo, pSDataBlock->info.uid, &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) { SResultRowPosition pos = {.pageId = pResult->pageId, .offset = pResult->offset}; 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 = setResultOutputBufByKey_rv(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->numOfOutput, 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 = setResultOutputBufByKey_rv(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->timeWindowData, &win, true); doApplyFunctions(pInfo->binfo.pCtx, &win, &pInfo->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 = setResultOutputBufByKey_rv(pResultRowInfo, pSDataBlock->info.uid, &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) { SResultRowPosition pos = {.pageId = pResult->pageId, .offset = pResult->offset}; 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->timeWindowData, &nextWin, true); doApplyFunctions(pInfo->binfo.pCtx, &nextWin, &pInfo->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 void hashAllIntervalAgg(SOperatorInfo* pOperatorInfo, SResultRowInfo* pResultRowInfo, SSDataBlock* pSDataBlock, int32_t tableGroupId) { STableIntervalOperatorInfo* pInfo = (STableIntervalOperatorInfo*)pOperatorInfo->info; STaskRuntimeEnv* pRuntimeEnv = pOperatorInfo->pRuntimeEnv; int32_t numOfOutput = pOperatorInfo->numOfOutput; int32_t step = 1;//GET_FORWARD_DIRECTION_FACTOR(pQueryAttr->order.order); bool ascQuery = true; TSKEY* tsCols = NULL; if (pSDataBlock->pDataBlock != NULL) { SColumnInfoData* pColDataInfo = taosArrayGet(pSDataBlock->pDataBlock, 0); tsCols = (int64_t*)pColDataInfo->pData; assert(tsCols[0] == pSDataBlock->info.window.skey && tsCols[pSDataBlock->info.rows - 1] == pSDataBlock->info.window.ekey); } int32_t startPos = ascQuery ? 0 : (pSDataBlock->info.rows - 1); TSKEY ts = getStartTsKey(&pSDataBlock->info.window, tsCols, pSDataBlock->info.rows, ascQuery); STimeWindow win = {0};//getCurrentActiveTimeWindow(pResultRowInfo, ts, pQueryAttr); bool masterScan = IS_MAIN_SCAN(pRuntimeEnv); SResultRow* pResult = NULL; int32_t forwardStep = 0; int32_t ret = 0; STimeWindow preWin = win; while (1) { // null data, failed to allocate more memory buffer ret = setResultOutputBufByKey(pRuntimeEnv, pResultRowInfo, pSDataBlock->info.uid, &win, masterScan, &pResult, tableGroupId, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset); if (ret != TSDB_CODE_SUCCESS) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } TSKEY ekey = 0;//reviseWindowEkey(pQueryAttr, &win); // forwardStep = getNumOfRowsInTimeWindow(pRuntimeEnv, &pSDataBlock->info, tsCols, startPos, ekey, // binarySearchForKey, true); // window start(end) key interpolation // doWindowBorderInterpolation(pOperatorInfo, pSDataBlock, pInfo->binfo.pCtx, pResult, &win, startPos, // forwardStep); doApplyFunctions(pRuntimeEnv, pInfo->binfo.pCtx, ascQuery ? &win : &preWin, startPos, // forwardStep, tsCols, pSDataBlock->info.rows, numOfOutput); preWin = win; int32_t prevEndPos = (forwardStep - 1) * step + startPos; // startPos = getNextQualifiedWindow(pQueryAttr, &win, &pSDataBlock->info, tsCols, binarySearchForKey, // prevEndPos); if (startPos < 0) { // if ((ascQuery && win.skey <= pQueryAttr->window.ekey) || ((!ascQuery) && win.ekey >= pQueryAttr->window.ekey)) { // int32_t code = // setResultOutputBufByKey(pRuntimeEnv, pResultRowInfo, pSDataBlock->info.uid, &win, masterScan, &pResult, // tableGroupId, pInfo->binfo.pCtx, numOfOutput, pInfo->binfo.rowCellInfoOffset); // if (code != TSDB_CODE_SUCCESS || pResult == NULL) { // longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_OUT_OF_MEMORY); // } // // startPos = pSDataBlock->info.rows - 1; // window start(end) key interpolation // doWindowBorderInterpolation(pOperatorInfo, pSDataBlock, pInfo->binfo.pCtx, pResult, &win, startPos, // forwardStep); doApplyFunctions(pRuntimeEnv, pInfo->binfo.pCtx, ascQuery ? &win : &preWin, startPos, // forwardStep, tsCols, pSDataBlock->info.rows, numOfOutput); // } break; } setResultRowInterpo(pResult, RESULT_ROW_END_INTERP); } // if (pQueryAttr->timeWindowInterpo) { // int32_t rowIndex = ascQuery ? (pSDataBlock->info.rows - 1) : 0; // saveDataBlockLastRow(pRuntimeEnv, &pSDataBlock->info, pSDataBlock->pDataBlock, rowIndex); // } // updateResultRowInfoActiveIndex(pResultRowInfo, pQueryAttr, pRuntimeEnv->current->lastKey); } static void doKeepTuple(SSessionAggOperatorInfo* pInfo, int64_t ts) { pInfo->curWindow.ekey = ts; pInfo->prevTs = ts; pInfo->numOfRows += 1; } static void doKeepSessionStartInfo(SSessionAggOperatorInfo* pInfo, const int64_t* tsList, int32_t rowIndex) { pInfo->start = rowIndex; pInfo->numOfRows = 0; pInfo->curWindow.skey = tsList[rowIndex]; } // todo handle multiple tables cases. static void doSessionWindowAggImpl(SOperatorInfo* pOperator, SSessionAggOperatorInfo* pInfo, SSDataBlock* pBlock) { SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SColumnInfoData* pColInfoData = taosArrayGet(pBlock->pDataBlock, 0); bool masterScan = true; int32_t numOfOutput = pOperator->numOfOutput; int64_t gid = pBlock->info.groupId; int64_t gap = pInfo->gap; pInfo->numOfRows = 0; if (!pInfo->reptScan) { pInfo->reptScan = true; pInfo->prevTs = INT64_MIN; } // 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->prevTs == INT64_MIN) { doKeepSessionStartInfo(pInfo, tsList, j); doKeepTuple(pInfo, tsList[j]); } else if (tsList[j] - pInfo->prevTs <= gap && (tsList[j] - pInfo->prevTs) >= 0) { // The gap is less than the threshold, so it belongs to current session window that has been opened already. doKeepTuple(pInfo, tsList[j]); if (j == 0 && pInfo->start != 0) { pInfo->start = 0; } } else { // start a new session window SResultRow* pResult = NULL; // keep the time window for the closed time window. STimeWindow window = pInfo->curWindow; pInfo->curWindow.ekey = pInfo->curWindow.skey; int32_t ret = setResultOutputBufByKey_rv(&pInfo->binfo.resultRowInfo, pBlock->info.uid, &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->timeWindowData, &window, false); doApplyFunctions(pInfo->binfo.pCtx, &window, &pInfo->timeWindowData, pInfo->start, pInfo->numOfRows, NULL, pBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); // here we start a new session window doKeepSessionStartInfo(pInfo, tsList, j); doKeepTuple(pInfo, tsList[j]); } } SResultRow* pResult = NULL; pInfo->curWindow.ekey = tsList[pBlock->info.rows - 1]; int32_t ret = setResultOutputBufByKey_rv(&pInfo->binfo.resultRowInfo, pBlock->info.uid, &pInfo->curWindow, 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->timeWindowData, &pInfo->curWindow, false); doApplyFunctions(pInfo->binfo.pCtx, &pInfo->curWindow, &pInfo->timeWindowData, pInfo->start, pInfo->numOfRows, NULL, pBlock->info.rows, numOfOutput, TSDB_ORDER_ASC); } static void setResultRowKey(SResultRow* pResultRow, char* pData, int16_t type) { if (IS_VAR_DATA_TYPE(type)) { if (pResultRow->key == NULL) { pResultRow->key = taosMemoryMalloc(varDataTLen(pData)); varDataCopy(pResultRow->key, pData); } else { assert(memcmp(pResultRow->key, pData, varDataTLen(pData)) == 0); } } else { int64_t v = -1; GET_TYPED_DATA(v, int64_t, type, pData); pResultRow->win.skey = v; pResultRow->win.ekey = v; } } int32_t setGroupResultOutputBuf_rv(SOptrBasicInfo* binfo, int32_t numOfCols, char* pData, int16_t type, int16_t bytes, int32_t groupId, SDiskbasedBuf* pBuf, SExecTaskInfo* pTaskInfo, SAggSupporter* pAggSup) { SResultRowInfo* pResultRowInfo = &binfo->resultRowInfo; SqlFunctionCtx* pCtx = binfo->pCtx; SResultRow* pResultRow = doSetResultOutBufByKey_rv(pBuf, pResultRowInfo, groupId, (char*)pData, bytes, true, groupId, pTaskInfo, false, pAggSup); assert(pResultRow != NULL); setResultRowKey(pResultRow, pData, type); setResultRowOutputBufInitCtx_rv(pResultRow, pCtx, numOfCols, binfo->rowCellInfoOffset); return TSDB_CODE_SUCCESS; } static bool functionNeedToExecute(SqlFunctionCtx* pCtx) { struct SResultRowEntryInfo* pResInfo = GET_RES_INFO(pCtx); // in case of timestamp column, always generated results. int32_t functionId = pCtx->functionId; if (functionId == -1) { return false; } if (isRowEntryCompleted(pResInfo)) { return false; } if (functionId == FUNCTION_FIRST_DST || functionId == FUNCTION_FIRST) { // return QUERY_IS_ASC_QUERY(pQueryAttr); } // denote the order type if ((functionId == FUNCTION_LAST_DST || functionId == FUNCTION_LAST)) { // return pCtx->param[0].i == pQueryAttr->order.order; } // in the reverse table scan, only the following functions need to be executed // if (IS_REVERSE_SCAN(pRuntimeEnv) || // (pRuntimeEnv->scanFlag == REPEAT_SCAN && functionId != FUNCTION_STDDEV && functionId != FUNCTION_PERCT)) { // return false; // } return true; } void setBlockStatisInfo(SqlFunctionCtx* pCtx, SSDataBlock* pSDataBlock, SColumn* pColumn) { SColumnDataAgg* pAgg = NULL; if (pSDataBlock->pBlockAgg != NULL && TSDB_COL_IS_NORMAL_COL(pColumn->flag)) { pAgg = &pSDataBlock->pBlockAgg[pCtx->columnIndex]; pCtx->agg = *pAgg; pCtx->isAggSet = true; assert(pCtx->agg.numOfNull <= pSDataBlock->info.rows); } else { pCtx->isAggSet = false; } pCtx->hasNull = hasNull(pColumn, pAgg); // set the statistics data for primary time stamp column if (pCtx->functionId == FUNCTION_SPREAD && pColumn->colId == PRIMARYKEY_TIMESTAMP_COL_ID) { pCtx->isAggSet = true; pCtx->agg.min = pSDataBlock->info.window.skey; pCtx->agg.max = pSDataBlock->info.window.ekey; } } // set the output buffer for the selectivity + tag query static int32_t setCtxTagColumnInfo(SqlFunctionCtx* pCtx, int32_t numOfOutput) { if (!isSelectivityWithTagsQuery(pCtx, numOfOutput)) { return TSDB_CODE_SUCCESS; } int32_t num = 0; int16_t tagLen = 0; SqlFunctionCtx* p = NULL; SqlFunctionCtx** pTagCtx = taosMemoryCalloc(numOfOutput, POINTER_BYTES); if (pTagCtx == NULL) { return TSDB_CODE_QRY_OUT_OF_MEMORY; } for (int32_t i = 0; i < numOfOutput; ++i) { int32_t functionId = pCtx[i].functionId; if (functionId == FUNCTION_TAG_DUMMY || functionId == FUNCTION_TS_DUMMY) { tagLen += pCtx[i].resDataInfo.bytes; pTagCtx[num++] = &pCtx[i]; } else if (1 /*(aAggs[functionId].status & FUNCSTATE_SELECTIVITY) != 0*/) { p = &pCtx[i]; } else if (functionId == FUNCTION_TS || functionId == FUNCTION_TAG) { // tag function may be the group by tag column // ts may be the required primary timestamp column continue; } else { // the column may be the normal column, group by normal_column, the functionId is FUNCTION_PRJ } } if (p != NULL) { p->subsidiaryRes.pCtx = pTagCtx; p->subsidiaryRes.numOfCols = num; p->subsidiaryRes.bufLen = tagLen; } else { taosMemoryFreeClear(pTagCtx); } return TSDB_CODE_SUCCESS; } static SqlFunctionCtx* createSqlFunctionCtx_rv(SExprInfo* pExprInfo, int32_t numOfOutput, int32_t** rowCellInfoOffset) { SqlFunctionCtx* pFuncCtx = (SqlFunctionCtx*)taosMemoryCalloc(numOfOutput, sizeof(SqlFunctionCtx)); if (pFuncCtx == NULL) { return NULL; } *rowCellInfoOffset = taosMemoryCalloc(numOfOutput, sizeof(int32_t)); if (*rowCellInfoOffset == 0) { taosMemoryFreeClear(pFuncCtx); return NULL; } for (int32_t i = 0; i < numOfOutput; ++i) { SExprInfo* pExpr = &pExprInfo[i]; SExprBasicInfo* pFunct = &pExpr->base; SqlFunctionCtx* pCtx = &pFuncCtx[i]; pCtx->functionId = -1; if (pExpr->pExpr->nodeType == QUERY_NODE_FUNCTION) { SFuncExecEnv env = {0}; pCtx->functionId = pExpr->pExpr->_function.pFunctNode->funcId; if (fmIsAggFunc(pCtx->functionId) || fmIsNonstandardSQLFunc(pCtx->functionId)) { fmGetFuncExecFuncs(pCtx->functionId, &pCtx->fpSet); pCtx->fpSet.getEnv(pExpr->pExpr->_function.pFunctNode, &env); } else { fmGetScalarFuncExecFuncs(pCtx->functionId, &pCtx->sfp); if (pCtx->sfp.getEnv != NULL) { pCtx->sfp.getEnv(pExpr->pExpr->_function.pFunctNode, &env); } } pCtx->resDataInfo.interBufSize = env.calcMemSize; } else if (pExpr->pExpr->nodeType == QUERY_NODE_COLUMN || pExpr->pExpr->nodeType == QUERY_NODE_OPERATOR || pExpr->pExpr->nodeType == QUERY_NODE_VALUE) { pCtx->resDataInfo.interBufSize = pFunct->resSchema.bytes; // for simple column, the intermediate buffer needs to hold one element. } pCtx->input.numOfInputCols = pFunct->numOfParams; pCtx->input.pData = taosMemoryCalloc(pFunct->numOfParams, POINTER_BYTES); pCtx->input.pColumnDataAgg = taosMemoryCalloc(pFunct->numOfParams, POINTER_BYTES); pCtx->pTsOutput = NULL;//taosArrayInit(4, POINTER_BYTES); pCtx->resDataInfo.bytes = pFunct->resSchema.bytes; pCtx->resDataInfo.type = pFunct->resSchema.type; pCtx->order = TSDB_ORDER_ASC; pCtx->start.key = INT64_MIN; pCtx->end.key = INT64_MIN; #if 0 for (int32_t j = 0; j < pCtx->numOfParams; ++j) { // int16_t type = pFunct->param[j].nType; // int16_t bytes = pFunct->param[j].nLen; // if (type == TSDB_DATA_TYPE_BINARY || type == TSDB_DATA_TYPE_NCHAR) { // taosVariantCreateFromBinary(&pCtx->param[j], pFunct->param[j].pz, bytes, type); // } else { // taosVariantCreateFromBinary(&pCtx->param[j], (char *)&pFunct->param[j].i, bytes, type); // } } // set the order information for top/bottom query int32_t functionId = pCtx->functionId; if (functionId == FUNCTION_TOP || functionId == FUNCTION_BOTTOM || functionId == FUNCTION_DIFF) { int32_t f = getExprFunctionId(&pExpr[0]); assert(f == FUNCTION_TS || f == FUNCTION_TS_DUMMY); // pCtx->param[2].i = pQueryAttr->order.order; pCtx->param[2].nType = TSDB_DATA_TYPE_BIGINT; pCtx->param[3].i = functionId; pCtx->param[3].nType = TSDB_DATA_TYPE_BIGINT; // pCtx->param[1].i = pQueryAttr->order.col.info.colId; } else if (functionId == FUNCTION_INTERP) { // pCtx->param[2].i = (int8_t)pQueryAttr->fillType; // if (pQueryAttr->fillVal != NULL) { // if (isNull((const char *)&pQueryAttr->fillVal[i], pCtx->inputType)) { // pCtx->param[1].nType = TSDB_DATA_TYPE_NULL; // } else { // todo refactor, taosVariantCreateFromBinary should handle the NULL value // if (pCtx->inputType != TSDB_DATA_TYPE_BINARY && pCtx->inputType != TSDB_DATA_TYPE_NCHAR) { // taosVariantCreateFromBinary(&pCtx->param[1], (char *)&pQueryAttr->fillVal[i], pCtx->inputBytes, pCtx->inputType); // } // } // } } else if (functionId == FUNCTION_TS_COMP) { // pCtx->param[0].i = pQueryAttr->vgId; //TODO this should be the parameter from client pCtx->param[0].nType = TSDB_DATA_TYPE_BIGINT; } else if (functionId == FUNCTION_TWA) { // pCtx->param[1].i = pQueryAttr->window.skey; pCtx->param[1].nType = TSDB_DATA_TYPE_BIGINT; // pCtx->param[2].i = pQueryAttr->window.ekey; pCtx->param[2].nType = TSDB_DATA_TYPE_BIGINT; } else if (functionId == FUNCTION_ARITHM) { // pCtx->param[1].pz = (char*) getScalarFuncSupport(pRuntimeEnv->scalarSup, i); } #endif } for (int32_t i = 1; i < numOfOutput; ++i) { (*rowCellInfoOffset)[i] = (int32_t)((*rowCellInfoOffset)[i - 1] + sizeof(SResultRowEntryInfo) + pFuncCtx[i - 1].resDataInfo.interBufSize); } setCtxTagColumnInfo(pFuncCtx, numOfOutput); return pFuncCtx; } static void* destroySqlFunctionCtx(SqlFunctionCtx* pCtx, int32_t numOfOutput) { if (pCtx == NULL) { return NULL; } for (int32_t i = 0; i < numOfOutput; ++i) { for (int32_t j = 0; j < pCtx[i].numOfParams; ++j) { taosVariantDestroy(&pCtx[i].param[j]); } taosVariantDestroy(&pCtx[i].tag); taosMemoryFreeClear(pCtx[i].subsidiaryRes.pCtx); } taosMemoryFreeClear(pCtx); return NULL; } static void doFreeQueryHandle(STaskRuntimeEnv* pRuntimeEnv) { STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; // tsdbCleanupReadHandle(pRuntimeEnv->pTsdbReadHandle); pRuntimeEnv->pTsdbReadHandle = NULL; // SMemRef* pMemRef = &pQueryAttr->memRef; // assert(pMemRef->ref == 0 && pMemRef->snapshot.imem == NULL && pMemRef->snapshot.mem == NULL); } static void destroyTsComp(STaskRuntimeEnv* pRuntimeEnv, STaskAttr* pQueryAttr) { if (pQueryAttr->tsCompQuery && pRuntimeEnv->outputBuf && pRuntimeEnv->outputBuf->pDataBlock && taosArrayGetSize(pRuntimeEnv->outputBuf->pDataBlock) > 0) { SColumnInfoData* pColInfoData = taosArrayGet(pRuntimeEnv->outputBuf->pDataBlock, 0); if (pColInfoData) { TdFilePtr pFile = *(TdFilePtr*)pColInfoData->pData; // TODO refactor if (pFile != NULL) { taosCloseFile(&pFile); *(TdFilePtr*)pColInfoData->pData = NULL; } } } } bool isTaskKilled(SExecTaskInfo* pTaskInfo) { // query has been executed more than tsShellActivityTimer, and the retrieve has not arrived // abort current query execution. if (pTaskInfo->owner != 0 && ((taosGetTimestampSec() - pTaskInfo->cost.start / 1000) > 10 * getMaximumIdleDurationSec()) /*(!needBuildResAfterQueryComplete(pTaskInfo))*/) { assert(pTaskInfo->cost.start != 0); // qDebug("QInfo:%" PRIu64 " retrieve not arrive beyond %d ms, abort current query execution, start:%" PRId64 // ", current:%d", pQInfo->qId, 1, pQInfo->startExecTs, taosGetTimestampSec()); // return true; } return false; } void setTaskKilled(SExecTaskInfo* pTaskInfo) { pTaskInfo->code = TSDB_CODE_TSC_QUERY_CANCELLED; } static bool isCachedLastQuery(STaskAttr* pQueryAttr) { for (int32_t i = 0; i < pQueryAttr->numOfOutput; ++i) { int32_t functionId = getExprFunctionId(&pQueryAttr->pExpr1[i]); if (functionId == FUNCTION_LAST || functionId == FUNCTION_LAST_DST) { continue; } return false; } if (pQueryAttr->order.order != TSDB_ORDER_DESC || !TSWINDOW_IS_EQUAL(pQueryAttr->window, TSWINDOW_DESC_INITIALIZER)) { return false; } if (pQueryAttr->groupbyColumn) { return false; } if (pQueryAttr->interval.interval > 0) { return false; } if (pQueryAttr->numOfFilterCols > 0 || pQueryAttr->havingNum > 0) { return false; } return true; } ///////////////////////////////////////////////////////////////////////////////////////////// // todo refactor : return window void getAlignQueryTimeWindow(SInterval* pInterval, int32_t precision, int64_t key, int64_t keyFirst, int64_t keyLast, STimeWindow* win) { ASSERT(key >= keyFirst && key <= keyLast); win->skey = taosTimeTruncate(key, pInterval, precision); /* * if the realSkey > INT64_MAX - pInterval->interval, the query duration between * realSkey and realEkey must be less than one interval.Therefore, no need to adjust the query ranges. */ if (keyFirst > (INT64_MAX - pInterval->interval)) { assert(keyLast - keyFirst < pInterval->interval); win->ekey = INT64_MAX; } else { win->ekey = taosTimeAdd(win->skey, pInterval->interval, pInterval->intervalUnit, precision) - 1; } } static int32_t updateBlockLoadStatus(STaskAttr* pQuery, int32_t status) { bool hasFirstLastFunc = false; bool hasOtherFunc = false; if (status == BLK_DATA_ALL_NEEDED || status == BLK_DATA_DISCARD) { return status; } for (int32_t i = 0; i < pQuery->numOfOutput; ++i) { int32_t functionId = getExprFunctionId(&pQuery->pExpr1[i]); if (functionId == FUNCTION_TS || functionId == FUNCTION_TS_DUMMY || functionId == FUNCTION_TAG || functionId == FUNCTION_TAG_DUMMY) { continue; } if (functionId == FUNCTION_FIRST_DST || functionId == FUNCTION_LAST_DST) { hasFirstLastFunc = true; } else { hasOtherFunc = true; } } if (hasFirstLastFunc && status == BLK_DATA_NO_NEEDED) { if (!hasOtherFunc) { return BLK_DATA_DISCARD; } else { return BLK_DATA_ALL_NEEDED; } } return status; } static void doUpdateLastKey(STaskAttr* pQueryAttr) { STimeWindow* win = &pQueryAttr->window; size_t num = taosArrayGetSize(pQueryAttr->tableGroupInfo.pGroupList); for (int32_t i = 0; i < num; ++i) { SArray* p1 = taosArrayGetP(pQueryAttr->tableGroupInfo.pGroupList, i); size_t len = taosArrayGetSize(p1); for (int32_t j = 0; j < len; ++j) { // STableKeyInfo* pInfo = taosArrayGet(p1, j); // // // update the new lastkey if it is equalled to the value of the old skey // if (pInfo->lastKey == win->ekey) { // pInfo->lastKey = win->skey; // } } } } // static void updateDataCheckOrder(SQInfo *pQInfo, SQueryTableReq* pQueryMsg, bool stableQuery) { // STaskAttr* pQueryAttr = pQInfo->runtimeEnv.pQueryAttr; // // // in case of point-interpolation query, use asc order scan // char msg[] = "QInfo:0x%"PRIx64" scan order changed for %s query, old:%d, new:%d, qrange exchanged, old qrange:%" // PRId64 // "-%" PRId64 ", new qrange:%" PRId64 "-%" PRId64; // // // todo handle the case the the order irrelevant query type mixed up with order critical query type // // descending order query for last_row query // if (isFirstLastRowQuery(pQueryAttr)) { // //qDebug("QInfo:0x%"PRIx64" scan order changed for last_row query, old:%d, new:%d", pQInfo->qId, // pQueryAttr->order.order, TSDB_ORDER_ASC); // // pQueryAttr->order.order = TSDB_ORDER_ASC; // if (pQueryAttr->window.skey > pQueryAttr->window.ekey) { // TSWAP(pQueryAttr->window.skey, pQueryAttr->window.ekey, TSKEY); // } // // pQueryAttr->needReverseScan = false; // return; // } // // if (pQueryAttr->groupbyColumn && pQueryAttr->order.order == TSDB_ORDER_DESC) { // pQueryAttr->order.order = TSDB_ORDER_ASC; // if (pQueryAttr->window.skey > pQueryAttr->window.ekey) { // TSWAP(pQueryAttr->window.skey, pQueryAttr->window.ekey, TSKEY); // } // // pQueryAttr->needReverseScan = false; // doUpdateLastKey(pQueryAttr); // return; // } // // if (pQueryAttr->pointInterpQuery && pQueryAttr->interval.interval == 0) { // if (!QUERY_IS_ASC_QUERY(pQueryAttr)) { // //qDebug(msg, pQInfo->qId, "interp", pQueryAttr->order.order, TSDB_ORDER_ASC, pQueryAttr->window.skey, // pQueryAttr->window.ekey, pQueryAttr->window.ekey, pQueryAttr->window.skey); TSWAP(pQueryAttr->window.skey, // pQueryAttr->window.ekey, TSKEY); // } // // pQueryAttr->order.order = TSDB_ORDER_ASC; // return; // } // // if (pQueryAttr->interval.interval == 0) { // if (onlyFirstQuery(pQueryAttr)) { // if (!QUERY_IS_ASC_QUERY(pQueryAttr)) { // //qDebug(msg, pQInfo->qId, "only-first", pQueryAttr->order.order, TSDB_ORDER_ASC, pQueryAttr->window.skey, //// pQueryAttr->window.ekey, pQueryAttr->window.ekey, pQueryAttr->window.skey); // // TSWAP(pQueryAttr->window.skey, pQueryAttr->window.ekey, TSKEY); // doUpdateLastKey(pQueryAttr); // } // // pQueryAttr->order.order = TSDB_ORDER_ASC; // pQueryAttr->needReverseScan = false; // } else if (onlyLastQuery(pQueryAttr) && notContainSessionOrStateWindow(pQueryAttr)) { // if (QUERY_IS_ASC_QUERY(pQueryAttr)) { // //qDebug(msg, pQInfo->qId, "only-last", pQueryAttr->order.order, TSDB_ORDER_DESC, pQueryAttr->window.skey, //// pQueryAttr->window.ekey, pQueryAttr->window.ekey, pQueryAttr->window.skey); // // TSWAP(pQueryAttr->window.skey, pQueryAttr->window.ekey, TSKEY); // doUpdateLastKey(pQueryAttr); // } // // pQueryAttr->order.order = TSDB_ORDER_DESC; // pQueryAttr->needReverseScan = false; // } // // } else { // interval query // if (stableQuery) { // if (onlyFirstQuery(pQueryAttr)) { // if (!QUERY_IS_ASC_QUERY(pQueryAttr)) { // //qDebug(msg, pQInfo->qId, "only-first stable", pQueryAttr->order.order, TSDB_ORDER_ASC, //// pQueryAttr->window.skey, pQueryAttr->window.ekey, pQueryAttr->window.ekey, /// pQueryAttr->window.skey); // // TSWAP(pQueryAttr->window.skey, pQueryAttr->window.ekey, TSKEY); // doUpdateLastKey(pQueryAttr); // } // // pQueryAttr->order.order = TSDB_ORDER_ASC; // pQueryAttr->needReverseScan = false; // } else if (onlyLastQuery(pQueryAttr)) { // if (QUERY_IS_ASC_QUERY(pQueryAttr)) { // //qDebug(msg, pQInfo->qId, "only-last stable", pQueryAttr->order.order, TSDB_ORDER_DESC, //// pQueryAttr->window.skey, pQueryAttr->window.ekey, pQueryAttr->window.ekey, /// pQueryAttr->window.skey); // // TSWAP(pQueryAttr->window.skey, pQueryAttr->window.ekey, TSKEY); // doUpdateLastKey(pQueryAttr); // } // // pQueryAttr->order.order = TSDB_ORDER_DESC; // pQueryAttr->needReverseScan = false; // } // } // } //} static void getIntermediateBufInfo(STaskRuntimeEnv* pRuntimeEnv, int32_t* ps, int32_t* rowsize) { STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; int32_t MIN_ROWS_PER_PAGE = 4; *rowsize = (int32_t)(pQueryAttr->resultRowSize * getRowNumForMultioutput(pQueryAttr, pQueryAttr->topBotQuery, pQueryAttr->stableQuery)); int32_t overhead = sizeof(SFilePage); // one page contains at least two rows *ps = DEFAULT_INTERN_BUF_PAGE_SIZE; while (((*rowsize) * MIN_ROWS_PER_PAGE) > (*ps) - overhead) { *ps = ((*ps) << 1u); } } #define IS_PREFILTER_TYPE(_t) ((_t) != TSDB_DATA_TYPE_BINARY && (_t) != TSDB_DATA_TYPE_NCHAR) // static FORCE_INLINE bool doFilterByBlockStatistics(STaskRuntimeEnv* pRuntimeEnv, SDataStatis *pDataStatis, // SqlFunctionCtx *pCtx, int32_t numOfRows) { // STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; // // if (pDataStatis == NULL || pQueryAttr->pFilters == NULL) { // return true; // } // // return filterRangeExecute(pQueryAttr->pFilters, pDataStatis, pQueryAttr->numOfCols, numOfRows); // } static bool overlapWithTimeWindow(STaskAttr* pQueryAttr, SDataBlockInfo* pBlockInfo) { STimeWindow w = {0}; TSKEY sk = TMIN(pQueryAttr->window.skey, pQueryAttr->window.ekey); TSKEY ek = TMAX(pQueryAttr->window.skey, pQueryAttr->window.ekey); if (QUERY_IS_ASC_QUERY(pQueryAttr)) { // getAlignQueryTimeWindow(pQueryAttr, pBlockInfo->window.skey, sk, ek, &w); assert(w.ekey >= pBlockInfo->window.skey); if (w.ekey < pBlockInfo->window.ekey) { return true; } while (1) { // getNextTimeWindow(pQueryAttr, &w); if (w.skey > pBlockInfo->window.ekey) { break; } assert(w.ekey > pBlockInfo->window.ekey); if (w.skey <= pBlockInfo->window.ekey && w.skey > pBlockInfo->window.skey) { return true; } } } else { // getAlignQueryTimeWindow(pQueryAttr, pBlockInfo->window.ekey, sk, ek, &w); assert(w.skey <= pBlockInfo->window.ekey); if (w.skey > pBlockInfo->window.skey) { return true; } while (1) { // getNextTimeWindow(pQueryAttr, &w); if (w.ekey < pBlockInfo->window.skey) { break; } assert(w.skey < pBlockInfo->window.skey); if (w.ekey < pBlockInfo->window.ekey && w.ekey >= pBlockInfo->window.skey) { return true; } } } return false; } static int32_t doTSJoinFilter(STaskRuntimeEnv* pRuntimeEnv, TSKEY key, bool ascQuery) { STSElem elem = tsBufGetElem(pRuntimeEnv->pTsBuf); #if defined(_DEBUG_VIEW) printf("elem in comp ts file:%" PRId64 ", key:%" PRId64 ", tag:%" PRIu64 ", query order:%d, ts order:%d, traverse:%d, index:%d\n", elem.ts, key, elem.tag.i, pQueryAttr->order.order, pRuntimeEnv->pTsBuf->tsOrder, pRuntimeEnv->pTsBuf->cur.order, pRuntimeEnv->pTsBuf->cur.tsIndex); #endif if (ascQuery) { if (key < elem.ts) { return TS_JOIN_TS_NOT_EQUALS; } else if (key > elem.ts) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_INCONSISTAN); } } else { if (key > elem.ts) { return TS_JOIN_TS_NOT_EQUALS; } else if (key < elem.ts) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_INCONSISTAN); } } return TS_JOIN_TS_EQUAL; } bool doFilterDataBlock(SSingleColumnFilterInfo* pFilterInfo, int32_t numOfFilterCols, int32_t numOfRows, int8_t* p) { bool all = true; for (int32_t i = 0; i < numOfRows; ++i) { bool qualified = false; for (int32_t k = 0; k < numOfFilterCols; ++k) { char* pElem = (char*)pFilterInfo[k].pData + pFilterInfo[k].info.bytes * i; qualified = false; for (int32_t j = 0; j < pFilterInfo[k].numOfFilters; ++j) { SColumnFilterElem* pFilterElem = NULL; // SColumnFilterElem* pFilterElem = &pFilterInfo[k].pFilters[j]; bool isnull = isNull(pElem, pFilterInfo[k].info.type); if (isnull) { // if (pFilterElem->fp == isNullOperator) { // qualified = true; // break; // } else { // continue; // } } else { // if (pFilterElem->fp == notNullOperator) { // qualified = true; // break; // } else if (pFilterElem->fp == isNullOperator) { // continue; // } } if (pFilterElem->fp(pFilterElem, pElem, pElem, pFilterInfo[k].info.type)) { qualified = true; break; } } if (!qualified) { break; } } p[i] = qualified ? 1 : 0; if (!qualified) { all = false; } } return all; } void doCompactSDataBlock(SSDataBlock* pBlock, int32_t numOfRows, int8_t* p) { int32_t len = 0; int32_t start = 0; for (int32_t j = 0; j < numOfRows; ++j) { if (p[j] == 1) { len++; } else { if (len > 0) { int32_t cstart = j - len; for (int32_t i = 0; i < pBlock->info.numOfCols; ++i) { SColumnInfoData* pColumnInfoData = taosArrayGet(pBlock->pDataBlock, i); int16_t bytes = pColumnInfoData->info.bytes; memmove(((char*)pColumnInfoData->pData) + start * bytes, pColumnInfoData->pData + cstart * bytes, len * bytes); } start += len; len = 0; } } } if (len > 0) { int32_t cstart = numOfRows - len; for (int32_t i = 0; i < pBlock->info.numOfCols; ++i) { SColumnInfoData* pColumnInfoData = taosArrayGet(pBlock->pDataBlock, i); int16_t bytes = pColumnInfoData->info.bytes; memmove(pColumnInfoData->pData + start * bytes, pColumnInfoData->pData + cstart * bytes, len * bytes); } start += len; len = 0; } pBlock->info.rows = start; pBlock->pBlockAgg = NULL; // clean the block statistics info if (start > 0) { SColumnInfoData* pColumnInfoData = taosArrayGet(pBlock->pDataBlock, 0); if (pColumnInfoData->info.type == TSDB_DATA_TYPE_TIMESTAMP && pColumnInfoData->info.colId == PRIMARYKEY_TIMESTAMP_COL_ID) { pBlock->info.window.skey = *(int64_t*)pColumnInfoData->pData; pBlock->info.window.ekey = *(int64_t*)(pColumnInfoData->pData + TSDB_KEYSIZE * (start - 1)); } } } void filterRowsInDataBlock(STaskRuntimeEnv* pRuntimeEnv, SSingleColumnFilterInfo* pFilterInfo, int32_t numOfFilterCols, SSDataBlock* pBlock, bool ascQuery) { int32_t numOfRows = pBlock->info.rows; int8_t* p = taosMemoryCalloc(numOfRows, sizeof(int8_t)); bool all = true; #if 0 if (pRuntimeEnv->pTsBuf != NULL) { SColumnInfoData* pColInfoData = taosArrayGet(pBlock->pDataBlock, 0); TSKEY* k = (TSKEY*) pColInfoData->pData; for (int32_t i = 0; i < numOfRows; ++i) { int32_t offset = ascQuery? i:(numOfRows - i - 1); int32_t ret = doTSJoinFilter(pRuntimeEnv, k[offset], ascQuery); if (ret == TS_JOIN_TAG_NOT_EQUALS) { break; } else if (ret == TS_JOIN_TS_NOT_EQUALS) { all = false; continue; } else { assert(ret == TS_JOIN_TS_EQUAL); p[offset] = true; } if (!tsBufNextPos(pRuntimeEnv->pTsBuf)) { break; } } // save the cursor status pRuntimeEnv->current->cur = tsBufGetCursor(pRuntimeEnv->pTsBuf); } else { all = doFilterDataBlock(pFilterInfo, numOfFilterCols, numOfRows, p); } #endif if (!all) { doCompactSDataBlock(pBlock, numOfRows, p); } taosMemoryFreeClear(p); } void filterColRowsInDataBlock(STaskRuntimeEnv* pRuntimeEnv, SSDataBlock* pBlock, bool ascQuery) { int32_t numOfRows = pBlock->info.rows; int8_t* p = NULL; bool all = true; if (pRuntimeEnv->pTsBuf != NULL) { SColumnInfoData* pColInfoData = taosArrayGet(pBlock->pDataBlock, 0); p = taosMemoryCalloc(numOfRows, sizeof(int8_t)); TSKEY* k = (TSKEY*)pColInfoData->pData; for (int32_t i = 0; i < numOfRows; ++i) { int32_t offset = ascQuery ? i : (numOfRows - i - 1); int32_t ret = doTSJoinFilter(pRuntimeEnv, k[offset], ascQuery); if (ret == TS_JOIN_TAG_NOT_EQUALS) { break; } else if (ret == TS_JOIN_TS_NOT_EQUALS) { all = false; continue; } else { assert(ret == TS_JOIN_TS_EQUAL); p[offset] = true; } if (!tsBufNextPos(pRuntimeEnv->pTsBuf)) { break; } } // save the cursor status // pRuntimeEnv->current->cur = tsBufGetCursor(pRuntimeEnv->pTsBuf); } else { // all = filterExecute(pRuntimeEnv->pQueryAttr->pFilters, numOfRows, &p, pBlock->pBlockAgg, // pRuntimeEnv->pQueryAttr->numOfCols); } if (!all) { if (p) { doCompactSDataBlock(pBlock, numOfRows, p); } else { pBlock->info.rows = 0; pBlock->pBlockAgg = NULL; // clean the block statistics info } } taosMemoryFreeClear(p); } static SColumnInfo* doGetTagColumnInfoById(SColumnInfo* pTagColList, int32_t numOfTags, int16_t colId); static void doSetTagValueInParam(void* pTable, int32_t tagColId, SVariant* tag, int16_t type, int16_t bytes); static uint32_t doFilterByBlockTimeWindow(STableScanInfo* pTableScanInfo, SSDataBlock* pBlock) { SqlFunctionCtx* pCtx = pTableScanInfo->pCtx; uint32_t status = BLK_DATA_NO_NEEDED; int32_t numOfOutput = pTableScanInfo->numOfOutput; for (int32_t i = 0; i < numOfOutput; ++i) { int32_t functionId = pCtx[i].functionId; int32_t colId = pTableScanInfo->pExpr[i].base.pParam[0].pCol->colId; // group by + first/last should not apply the first/last block filter if (functionId < 0) { status |= BLK_DATA_ALL_NEEDED; return status; } else { // status |= aAggs[functionId].dataReqFunc(&pTableScanInfo->pCtx[i], &pBlock->info.window, colId); // if ((status & BLK_DATA_ALL_NEEDED) == BLK_DATA_ALL_NEEDED) { // return status; // } } } return status; } int32_t loadDataBlockOnDemand(SExecTaskInfo* pTaskInfo, STableScanInfo* pTableScanInfo, SSDataBlock* pBlock, uint32_t* status) { *status = BLK_DATA_NO_NEEDED; pBlock->pDataBlock = NULL; pBlock->pBlockAgg = NULL; // int64_t groupId = pRuntimeEnv->current->groupIndex; // bool ascQuery = QUERY_IS_ASC_QUERY(pQueryAttr); STaskCostInfo* pCost = &pTaskInfo->cost; pCost->totalBlocks += 1; pCost->totalRows += pBlock->info.rows; #if 0 if (pRuntimeEnv->pTsBuf != NULL) { (*status) = BLK_DATA_ALL_NEEDED; if (pQueryAttr->stableQuery) { // todo refactor SExprInfo* pExprInfo = &pTableScanInfo->pExpr[0]; int16_t tagId = (int16_t)pExprInfo->base.param[0].i; SColumnInfo* pColInfo = doGetTagColumnInfoById(pQueryAttr->tagColList, pQueryAttr->numOfTags, tagId); // compare tag first SVariant t = {0}; doSetTagValueInParam(pRuntimeEnv->current->pTable, tagId, &t, pColInfo->type, pColInfo->bytes); setTimestampListJoinInfo(pRuntimeEnv, &t, pRuntimeEnv->current); STSElem elem = tsBufGetElem(pRuntimeEnv->pTsBuf); if (!tsBufIsValidElem(&elem) || (tsBufIsValidElem(&elem) && (taosVariantCompare(&t, elem.tag) != 0))) { (*status) = BLK_DATA_DISCARD; return TSDB_CODE_SUCCESS; } } } // Calculate all time windows that are overlapping or contain current data block. // If current data block is contained by all possible time window, do not load current data block. if (/*pQueryAttr->pFilters || */pQueryAttr->groupbyColumn || pQueryAttr->sw.gap > 0 || (QUERY_IS_INTERVAL_QUERY(pQueryAttr) && overlapWithTimeWindow(pTaskInfo, &pBlock->info))) { (*status) = BLK_DATA_ALL_NEEDED; } // check if this data block is required to load if ((*status) != BLK_DATA_ALL_NEEDED) { bool needFilter = true; // the pCtx[i] result is belonged to previous time window since the outputBuf has not been set yet, // the filter result may be incorrect. So in case of interval query, we need to set the correct time output buffer if (QUERY_IS_INTERVAL_QUERY(pQueryAttr)) { SResultRow* pResult = NULL; bool masterScan = IS_MAIN_SCAN(pRuntimeEnv); TSKEY k = ascQuery? pBlock->info.window.skey : pBlock->info.window.ekey; STimeWindow win = getActiveTimeWindow(pTableScanInfo->pResultRowInfo, k, pQueryAttr); if (pQueryAttr->pointInterpQuery) { needFilter = chkWindowOutputBufByKey(pRuntimeEnv, pTableScanInfo->pResultRowInfo, &win, masterScan, &pResult, groupId, pTableScanInfo->pCtx, pTableScanInfo->numOfOutput, pTableScanInfo->rowCellInfoOffset); } else { if (setResultOutputBufByKey(pRuntimeEnv, pTableScanInfo->pResultRowInfo, pBlock->info.uid, &win, masterScan, &pResult, groupId, pTableScanInfo->pCtx, pTableScanInfo->numOfOutput, pTableScanInfo->rowCellInfoOffset) != TSDB_CODE_SUCCESS) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } } } else if (pQueryAttr->stableQuery && (!pQueryAttr->tsCompQuery) && (!pQueryAttr->diffQuery)) { // stable aggregate, not interval aggregate or normal column aggregate doSetTableGroupOutputBuf(pRuntimeEnv, pTableScanInfo->pResultRowInfo, pTableScanInfo->pCtx, pTableScanInfo->rowCellInfoOffset, pTableScanInfo->numOfOutput, pRuntimeEnv->current->groupIndex); } if (needFilter) { (*status) = doFilterByBlockTimeWindow(pTableScanInfo, pBlock); } else { (*status) = BLK_DATA_ALL_NEEDED; } } SDataBlockInfo* pBlockInfo = &pBlock->info; // *status = updateBlockLoadStatus(pRuntimeEnv->pQueryAttr, *status); if ((*status) == BLK_DATA_NO_NEEDED || (*status) == BLK_DATA_DISCARD) { //qDebug("QInfo:0x%"PRIx64" data block discard, brange:%" PRId64 "-%" PRId64 ", rows:%d", pQInfo->qId, pBlockInfo->window.skey, // pBlockInfo->window.ekey, pBlockInfo->rows); pCost->discardBlocks += 1; } else if ((*status) == BLK_DATA_STATIS_NEEDED) { // this function never returns error? pCost->loadBlockStatis += 1; // tsdbRetrieveDataBlockStatisInfo(pTableScanInfo->pTsdbReadHandle, &pBlock->pBlockAgg); if (pBlock->pBlockAgg == NULL) { // data block statistics does not exist, load data block // pBlock->pDataBlock = tsdbRetrieveDataBlock(pTableScanInfo->pTsdbReadHandle, NULL); pCost->totalCheckedRows += pBlock->info.rows; } } else { assert((*status) == BLK_DATA_ALL_NEEDED); // load the data block statistics to perform further filter pCost->loadBlockStatis += 1; // tsdbRetrieveDataBlockStatisInfo(pTableScanInfo->pTsdbReadHandle, &pBlock->pBlockAgg); if (pQueryAttr->topBotQuery && pBlock->pBlockAgg != NULL) { { // set previous window if (QUERY_IS_INTERVAL_QUERY(pQueryAttr)) { SResultRow* pResult = NULL; bool masterScan = IS_MAIN_SCAN(pRuntimeEnv); TSKEY k = ascQuery? pBlock->info.window.skey : pBlock->info.window.ekey; STimeWindow win = getActiveTimeWindow(pTableScanInfo->pResultRowInfo, k, pQueryAttr); if (setResultOutputBufByKey(pRuntimeEnv, pTableScanInfo->pResultRowInfo, pBlock->info.uid, &win, masterScan, &pResult, groupId, pTableScanInfo->pCtx, pTableScanInfo->numOfOutput, pTableScanInfo->rowCellInfoOffset) != TSDB_CODE_SUCCESS) { longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_OUT_OF_MEMORY); } } } bool load = false; for (int32_t i = 0; i < pQueryAttr->numOfOutput; ++i) { int32_t functionId = pTableScanInfo->pCtx[i].functionId; if (functionId == FUNCTION_TOP || functionId == FUNCTION_BOTTOM) { // load = topbot_datablock_filter(&pTableScanInfo->pCtx[i], (char*)&(pBlock->pBlockAgg[i].min), // (char*)&(pBlock->pBlockAgg[i].max)); if (!load) { // current block has been discard due to filter applied pCost->discardBlocks += 1; //qDebug("QInfo:0x%"PRIx64" data block discard, brange:%" PRId64 "-%" PRId64 ", rows:%d", pQInfo->qId, // pBlockInfo->window.skey, pBlockInfo->window.ekey, pBlockInfo->rows); (*status) = BLK_DATA_DISCARD; return TSDB_CODE_SUCCESS; } } } } // current block has been discard due to filter applied // if (!doFilterByBlockStatistics(pRuntimeEnv, pBlock->pBlockAgg, pTableScanInfo->pCtx, pBlockInfo->rows)) { // pCost->discardBlocks += 1; // qDebug("QInfo:0x%"PRIx64" data block discard, brange:%" PRId64 "-%" PRId64 ", rows:%d", pQInfo->qId, pBlockInfo->window.skey, // pBlockInfo->window.ekey, pBlockInfo->rows); // (*status) = BLK_DATA_DISCARD; // return TSDB_CODE_SUCCESS; // } pCost->totalCheckedRows += pBlockInfo->rows; pCost->loadBlocks += 1; // pBlock->pDataBlock = tsdbRetrieveDataBlock(pTableScanInfo->pTsdbReadHandle, NULL); // if (pBlock->pDataBlock == NULL) { // return terrno; // } // if (pQueryAttr->pFilters != NULL) { // filterSetColFieldData(pQueryAttr->pFilters, pBlock->info.numOfCols, pBlock->pDataBlock); // } // if (pQueryAttr->pFilters != NULL || pRuntimeEnv->pTsBuf != NULL) { // filterColRowsInDataBlock(pRuntimeEnv, pBlock, ascQuery); // } } #endif return TSDB_CODE_SUCCESS; } 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; } /* * set tag value in SqlFunctionCtx * e.g.,tag information into input buffer */ static void doSetTagValueInParam(void* pTable, int32_t tagColId, SVariant* tag, int16_t type, int16_t bytes) { taosVariantDestroy(tag); char* val = NULL; // if (tagColId == TSDB_TBNAME_COLUMN_INDEX) { // val = tsdbGetTableName(pTable); // assert(val != NULL); // } else { // val = tsdbGetTableTagVal(pTable, tagColId, type, bytes); // } if (val == NULL || isNull(val, type)) { tag->nType = TSDB_DATA_TYPE_NULL; return; } if (type == TSDB_DATA_TYPE_BINARY || type == TSDB_DATA_TYPE_NCHAR) { int32_t maxLen = bytes - VARSTR_HEADER_SIZE; int32_t len = (varDataLen(val) > maxLen) ? maxLen : varDataLen(val); taosVariantCreateFromBinary(tag, varDataVal(val), len, type); // taosVariantCreateFromBinary(tag, varDataVal(val), varDataLen(val), type); } else { taosVariantCreateFromBinary(tag, val, bytes, type); } } static SColumnInfo* doGetTagColumnInfoById(SColumnInfo* pTagColList, int32_t numOfTags, int16_t colId) { assert(pTagColList != NULL && numOfTags > 0); for (int32_t i = 0; i < numOfTags; ++i) { if (pTagColList[i].colId == colId) { return &pTagColList[i]; } } return NULL; } void setTagValue(SOperatorInfo* pOperatorInfo, void* pTable, SqlFunctionCtx* pCtx, int32_t numOfOutput) { STaskRuntimeEnv* pRuntimeEnv = pOperatorInfo->pRuntimeEnv; SExprInfo* pExpr = pOperatorInfo->pExpr; STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; SExprInfo* pExprInfo = &pExpr[0]; int32_t functionId = getExprFunctionId(pExprInfo); if (pQueryAttr->numOfOutput == 1 && functionId == FUNCTION_TS_COMP && pQueryAttr->stableQuery) { assert(pExprInfo->base.numOfParams == 1); // int16_t tagColId = (int16_t)pExprInfo->base.param[0].i; int16_t tagColId = -1; SColumnInfo* pColInfo = doGetTagColumnInfoById(pQueryAttr->tagColList, pQueryAttr->numOfTags, tagColId); doSetTagValueInParam(pTable, tagColId, &pCtx[0].tag, pColInfo->type, pColInfo->bytes); } else { // set tag value, by which the results are aggregated. int32_t offset = 0; memset(pRuntimeEnv->tagVal, 0, pQueryAttr->tagLen); for (int32_t idx = 0; idx < numOfOutput; ++idx) { SExprInfo* pLocalExprInfo = &pExpr[idx]; // ts_comp column required the tag value for join filter if (!TSDB_COL_IS_TAG(pLocalExprInfo->base.pParam[0].pCol->flag)) { continue; } // todo use tag column index to optimize performance doSetTagValueInParam(pTable, pLocalExprInfo->base.pParam[0].pCol->colId, &pCtx[idx].tag, pLocalExprInfo->base.resSchema.type, pLocalExprInfo->base.resSchema.bytes); if (IS_NUMERIC_TYPE(pLocalExprInfo->base.resSchema.type) || pLocalExprInfo->base.resSchema.type == TSDB_DATA_TYPE_BOOL || pLocalExprInfo->base.resSchema.type == TSDB_DATA_TYPE_TIMESTAMP) { memcpy(pRuntimeEnv->tagVal + offset, &pCtx[idx].tag.i, pLocalExprInfo->base.resSchema.bytes); } else { if (pCtx[idx].tag.pz != NULL) { memcpy(pRuntimeEnv->tagVal + offset, pCtx[idx].tag.pz, pCtx[idx].tag.nLen); } } offset += pLocalExprInfo->base.resSchema.bytes; } } // set the tsBuf start position before check each data block if (pRuntimeEnv->pTsBuf != NULL) { setCtxTagForJoin(pRuntimeEnv, &pCtx[0], pExprInfo, pTable); } } void copyToSDataBlock(SSDataBlock* pBlock, int32_t* offset, SGroupResInfo* pGroupResInfo, SDiskbasedBuf* pResBuf) { pBlock->info.rows = 0; int32_t code = TSDB_CODE_SUCCESS; while (pGroupResInfo->currentGroup < pGroupResInfo->totalGroup) { // all results in current group have been returned to client, try next group if ((pGroupResInfo->pRows == NULL) || taosArrayGetSize(pGroupResInfo->pRows) == 0) { assert(pGroupResInfo->index == 0); // if ((code = mergeIntoGroupResult(&pGroupResInfo, pRuntimeEnv, offset)) != TSDB_CODE_SUCCESS) { return; // } } // doCopyToSDataBlock(pResBuf, pGroupResInfo, TSDB_ORDER_ASC, pBlock, ); // current data are all dumped to result buffer, clear it if (!hasRemainDataInCurrentGroup(pGroupResInfo)) { cleanupGroupResInfo(pGroupResInfo); if (!incNextGroup(pGroupResInfo)) { break; } } // enough results in data buffer, return // if (pBlock->info.rows >= threshold) { // break; // } } } static void updateTableQueryInfoForReverseScan(STableQueryInfo* pTableQueryInfo) { if (pTableQueryInfo == NULL) { return; } // TSWAP(pTableQueryInfo->win.skey, pTableQueryInfo->win.ekey, TSKEY); // pTableQueryInfo->lastKey = pTableQueryInfo->win.skey; // SWITCH_ORDER(pTableQueryInfo->cur.order); // pTableQueryInfo->cur.vgroupIndex = -1; // set the index to be the end slot of result rows array SResultRowInfo* pResultRowInfo = &pTableQueryInfo->resInfo; if (pResultRowInfo->size > 0) { pResultRowInfo->curPos = pResultRowInfo->size - 1; } else { pResultRowInfo->curPos = -1; } } void initResultRow(SResultRow* pResultRow) { pResultRow->pEntryInfo = (struct SResultRowEntryInfo*)((char*)pResultRow + sizeof(SResultRow)); } /* * The start of each column SResultRowEntryInfo is denote by RowCellInfoOffset. * Note that in case of top/bottom query, the whole multiple rows of result is treated as only one row of results. * +------------+-----------------result column 1------------+------------------result column 2-----------+ * | SResultRow | SResultRowEntryInfo | intermediate buffer1 | SResultRowEntryInfo | intermediate buffer 2| * +------------+--------------------------------------------+--------------------------------------------+ * offset[0] offset[1] offset[2] */ // TODO refactor: some function move away void setFunctionResultOutput(SOptrBasicInfo* pInfo, SAggSupporter* pSup, int32_t stage, SExecTaskInfo* pTaskInfo) { SqlFunctionCtx* pCtx = pInfo->pCtx; SSDataBlock* pDataBlock = pInfo->pRes; int32_t* rowCellInfoOffset = pInfo->rowCellInfoOffset; SResultRowInfo* pResultRowInfo = &pInfo->resultRowInfo; initResultRowInfo(pResultRowInfo, 16); int64_t tid = 0; int64_t groupId = 0; SResultRow* pRow = doSetResultOutBufByKey_rv(pSup->pResultBuf, pResultRowInfo, tid, (char*)&tid, sizeof(tid), true, groupId, pTaskInfo, false, pSup); for (int32_t i = 0; i < pDataBlock->info.numOfCols; ++i) { struct SResultRowEntryInfo* pEntry = getResultCell(pRow, i, rowCellInfoOffset); cleanupResultRowEntry(pEntry); pCtx[i].resultInfo = pEntry; pCtx[i].currentStage = stage; // set the timestamp output buffer for top/bottom/diff query // int32_t fid = pCtx[i].functionId; // if (fid == FUNCTION_TOP || fid == FUNCTION_BOTTOM || fid == FUNCTION_DIFF || fid == FUNCTION_DERIVATIVE) { // if (i > 0) pCtx[i].pTsOutput = pCtx[i-1].pOutput; // } } initCtxOutputBuffer(pCtx, pDataBlock->info.numOfCols); } void updateOutputBuf(SOptrBasicInfo* pBInfo, int32_t* bufCapacity, int32_t numOfInputRows) { SSDataBlock* pDataBlock = pBInfo->pRes; int32_t newSize = pDataBlock->info.rows + numOfInputRows + 5; // extra output buffer if ((*bufCapacity) < newSize) { for (int32_t i = 0; i < pDataBlock->info.numOfCols; ++i) { SColumnInfoData* pColInfo = taosArrayGet(pDataBlock->pDataBlock, i); char* p = taosMemoryRealloc(pColInfo->pData, newSize * pColInfo->info.bytes); if (p != NULL) { pColInfo->pData = p; // it starts from the tail of the previously generated results. pBInfo->pCtx[i].pOutput = pColInfo->pData; (*bufCapacity) = newSize; } else { // longjmp } } } for (int32_t i = 0; i < pDataBlock->info.numOfCols; ++i) { SColumnInfoData* pColInfo = taosArrayGet(pDataBlock->pDataBlock, i); pBInfo->pCtx[i].pOutput = pColInfo->pData + pColInfo->info.bytes * pDataBlock->info.rows; // set the correct pointer after the memory buffer reallocated. int32_t functionId = pBInfo->pCtx[i].functionId; if (functionId == FUNCTION_TOP || functionId == FUNCTION_BOTTOM || functionId == FUNCTION_DIFF || functionId == FUNCTION_DERIVATIVE) { // if (i > 0) pBInfo->pCtx[i].pTsOutput = pBInfo->pCtx[i - 1].pOutput; } } } void copyTsColoum(SSDataBlock* pRes, SqlFunctionCtx* pCtx, int32_t numOfOutput) { bool needCopyTs = false; int32_t tsNum = 0; char* src = NULL; for (int32_t i = 0; i < numOfOutput; i++) { int32_t functionId = pCtx[i].functionId; if (functionId == FUNCTION_DIFF || functionId == FUNCTION_DERIVATIVE) { needCopyTs = true; if (i > 0 && pCtx[i - 1].functionId == FUNCTION_TS_DUMMY) { SColumnInfoData* pColRes = taosArrayGet(pRes->pDataBlock, i - 1); // find ts data src = pColRes->pData; } } else if (functionId == FUNCTION_TS_DUMMY) { tsNum++; } } if (!needCopyTs) return; if (tsNum < 2) return; if (src == NULL) return; for (int32_t i = 0; i < numOfOutput; i++) { int32_t functionId = pCtx[i].functionId; if (functionId == FUNCTION_TS_DUMMY) { SColumnInfoData* pColRes = taosArrayGet(pRes->pDataBlock, i); memcpy(pColRes->pData, src, pColRes->info.bytes * pRes->info.rows); } } } void initCtxOutputBuffer(SqlFunctionCtx* pCtx, int32_t size) { for (int32_t j = 0; j < size; ++j) { struct SResultRowEntryInfo* pResInfo = GET_RES_INFO(&pCtx[j]); if (isRowEntryInitialized(pResInfo) || fmIsPseudoColumnFunc(pCtx[j].functionId) || pCtx[j].functionId == -1 || fmIsScalarFunc(pCtx[j].functionId)) { continue; } pCtx[j].fpSet.init(&pCtx[j], pCtx[j].resultInfo); } } void setTaskStatus(SExecTaskInfo* pTaskInfo, int8_t status) { if (status == TASK_NOT_COMPLETED) { pTaskInfo->status = status; } else { // QUERY_NOT_COMPLETED is not compatible with any other status, so clear its position first CLEAR_QUERY_STATUS(pTaskInfo, TASK_NOT_COMPLETED); pTaskInfo->status |= status; } } void finalizeQueryResult(SqlFunctionCtx* pCtx, int32_t numOfOutput) { for (int32_t j = 0; j < numOfOutput; ++j) { if (pCtx[j].functionId == -1) { continue; } pCtx[j].fpSet.finalize(&pCtx[j]); } } void finalizeMultiTupleQueryResult(SqlFunctionCtx* pCtx, int32_t numOfOutput, SDiskbasedBuf* pBuf, SResultRowInfo* pResultRowInfo, int32_t* rowCellInfoOffset) { for (int32_t i = 0; i < pResultRowInfo->size; ++i) { SResultRowPosition* pPos = &pResultRowInfo->pPosition[i]; SFilePage* bufPage = getBufPage(pBuf, pPos->pageId); SResultRow* pRow = (SResultRow*)((char*)bufPage + pPos->offset); // TODO ignore the close status anyway. // if (!isResultRowClosed(pRow)) { // continue; // } for (int32_t j = 0; j < numOfOutput; ++j) { pCtx[j].resultInfo = getResultCell(pRow, j, rowCellInfoOffset); struct SResultRowEntryInfo* pResInfo = pCtx[j].resultInfo; if (isRowEntryCompleted(pResInfo) && isRowEntryInitialized(pResInfo)) { continue; } if (pCtx[j].fpSet.process) { // TODO set the dummy function, to avoid the check for null ptr. pCtx[j].fpSet.finalize(&pCtx[j]); } if (pRow->numOfRows < pResInfo->numOfRes) { pRow->numOfRows = pResInfo->numOfRes; } } releaseBufPage(pBuf, bufPage); } } void finalizeUpdatedResult(SqlFunctionCtx* pCtx, int32_t numOfOutput, SDiskbasedBuf* pBuf, SArray* pUpdateList, int32_t* rowCellInfoOffset) { size_t num = taosArrayGetSize(pUpdateList); for (int32_t i = 0; i < num; ++i) { SResultRowPosition* pPos = taosArrayGet(pUpdateList, i); SFilePage* bufPage = getBufPage(pBuf, pPos->pageId); SResultRow* pRow = (SResultRow*)((char*)bufPage + pPos->offset); for (int32_t j = 0; j < numOfOutput; ++j) { pCtx[j].resultInfo = getResultCell(pRow, j, rowCellInfoOffset); struct SResultRowEntryInfo* pResInfo = pCtx[j].resultInfo; if (isRowEntryCompleted(pResInfo) && isRowEntryInitialized(pResInfo)) { continue; } if (pCtx[j].fpSet.process) { // TODO set the dummy function. pCtx[j].fpSet.finalize(&pCtx[j]); pResInfo->initialized = true; } if (pRow->numOfRows < pResInfo->numOfRes) { pRow->numOfRows = pResInfo->numOfRes; } } releaseBufPage(pBuf, bufPage); /* * set the number of output results for group by normal columns, the number of output rows usually is 1 except * the top and bottom query */ // buf->numOfRows = (uint16_t)getNumOfResult(pCtx, numOfOutput); } } static bool hasMainOutput(STaskAttr* pQueryAttr) { for (int32_t i = 0; i < pQueryAttr->numOfOutput; ++i) { int32_t functionId = getExprFunctionId(&pQueryAttr->pExpr1[i]); if (functionId != FUNCTION_TS && functionId != FUNCTION_TAG && functionId != FUNCTION_TAGPRJ) { return true; } } return false; } STableQueryInfo* createTableQueryInfo(void* buf, bool groupbyColumn, STimeWindow win) { STableQueryInfo* pTableQueryInfo = buf; pTableQueryInfo->lastKey = win.skey; // set more initial size of interval/groupby query // if (/*QUERY_IS_INTERVAL_QUERY(pQueryAttr) || */groupbyColumn) { int32_t initialSize = 128; int32_t code = initResultRowInfo(&pTableQueryInfo->resInfo, initialSize); if (code != TSDB_CODE_SUCCESS) { return NULL; } // } else { // in other aggregate query, do not initialize the windowResInfo // } return pTableQueryInfo; } void destroyTableQueryInfoImpl(STableQueryInfo* pTableQueryInfo) { if (pTableQueryInfo == NULL) { return; } // taosVariantDestroy(&pTableQueryInfo->tag); cleanupResultRowInfo(&pTableQueryInfo->resInfo); } void setResultRowOutputBufInitCtx(STaskRuntimeEnv* pRuntimeEnv, SResultRow* pResult, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset) { // Note: pResult->pos[i]->num == 0, there is only fixed number of results for each group SFilePage* bufPage = getBufPage(pRuntimeEnv->pResultBuf, pResult->pageId); int32_t offset = 0; for (int32_t i = 0; i < numOfOutput; ++i) { pCtx[i].resultInfo = getResultCell(pResult, i, rowCellInfoOffset); struct SResultRowEntryInfo* pResInfo = pCtx[i].resultInfo; if (isRowEntryCompleted(pResInfo) && isRowEntryInitialized(pResInfo)) { offset += pCtx[i].resDataInfo.bytes; continue; } pCtx[i].pOutput = getPosInResultPage(pRuntimeEnv->pQueryAttr, bufPage, pResult->offset, offset); offset += pCtx[i].resDataInfo.bytes; int32_t functionId = pCtx[i].functionId; if (functionId < 0) { continue; } if (functionId == FUNCTION_TOP || functionId == FUNCTION_BOTTOM || functionId == FUNCTION_DIFF) { // if (i > 0) pCtx[i].pTsOutput = pCtx[i - 1].pOutput; } // if (!pResInfo->initialized) { // aAggs[functionId].init(&pCtx[i], pResInfo); // } } } void setResultRowOutputBufInitCtx_rv(SResultRow* pResult, SqlFunctionCtx* pCtx, int32_t numOfOutput, int32_t* rowCellInfoOffset) { for (int32_t i = 0; i < numOfOutput; ++i) { pCtx[i].resultInfo = getResultCell(pResult, i, rowCellInfoOffset); struct SResultRowEntryInfo* pResInfo = pCtx[i].resultInfo; if (isRowEntryCompleted(pResInfo) && isRowEntryInitialized(pResInfo)) { continue; } if (fmIsWindowPseudoColumnFunc(pCtx[i].functionId)) { continue; } if (!pResInfo->initialized && pCtx[i].functionId != -1) { pCtx[i].fpSet.init(&pCtx[i], pResInfo); } } } void doFilter(const SNode* pFilterNode, SSDataBlock* pBlock) { if (pFilterNode == NULL) { return; } SFilterInfo* filter = NULL; // todo move to the initialization function int32_t code = filterInitFromNode((SNode*)pFilterNode, &filter, 0); SFilterColumnParam param1 = {.numOfCols = pBlock->info.numOfCols, .pDataBlock = pBlock->pDataBlock}; code = filterSetDataFromSlotId(filter, ¶m1); int8_t* rowRes = NULL; bool keep = filterExecute(filter, pBlock, &rowRes, NULL, param1.numOfCols); SSDataBlock* px = createOneDataBlock(pBlock); blockDataEnsureCapacity(px, pBlock->info.rows); // todo extract method int32_t numOfRow = 0; for (int32_t i = 0; i < pBlock->info.numOfCols; ++i) { SColumnInfoData* pDst = taosArrayGet(px->pDataBlock, i); SColumnInfoData* pSrc = taosArrayGet(pBlock->pDataBlock, i); numOfRow = 0; for (int32_t j = 0; j < pBlock->info.rows; ++j) { if (rowRes[j] == 0) { continue; } if (colDataIsNull_s(pSrc, j)) { colDataAppendNULL(pDst, numOfRow); } else { colDataAppend(pDst, numOfRow, colDataGetData(pSrc, j), false); } numOfRow += 1; } *pSrc = *pDst; } pBlock->info.rows = numOfRow; } void doSetTableGroupOutputBuf(SAggOperatorInfo* pAggInfo, int32_t numOfOutput, int32_t tableGroupId, SExecTaskInfo* pTaskInfo) { // for simple group by query without interval, all the tables belong to one group result. int64_t uid = 0; int64_t tid = 0; SResultRowInfo* pResultRowInfo = &pAggInfo->binfo.resultRowInfo; SqlFunctionCtx* pCtx = pAggInfo->binfo.pCtx; int32_t* rowCellInfoOffset = pAggInfo->binfo.rowCellInfoOffset; SResultRow* pResultRow = doSetResultOutBufByKey_rv(pAggInfo->pResultBuf, pResultRowInfo, tid, (char*)&tableGroupId, sizeof(tableGroupId), true, uid, pTaskInfo, false, &pAggInfo->aggSup); assert(pResultRow != NULL); /* * not assign result buffer yet, add new result buffer * all group belong to one result set, and each group result has different group id so set the id to be one */ if (pResultRow->pageId == -1) { int32_t ret = addNewWindowResultBuf(pResultRow, pAggInfo->pResultBuf, tableGroupId, pAggInfo->binfo.pRes->info.rowSize); if (ret != TSDB_CODE_SUCCESS) { return; } } setResultRowOutputBufInitCtx_rv(pResultRow, pCtx, numOfOutput, rowCellInfoOffset); } void setExecutionContext(int32_t numOfOutput, int32_t tableGroupId, TSKEY nextKey, SExecTaskInfo* pTaskInfo, STableQueryInfo* pTableQueryInfo, SAggOperatorInfo* pAggInfo) { // lastKey needs to be updated pTableQueryInfo->lastKey = nextKey; if (pAggInfo->groupId != INT32_MIN && pAggInfo->groupId == tableGroupId) { return; } doSetTableGroupOutputBuf(pAggInfo, numOfOutput, tableGroupId, pTaskInfo); // record the current active group id pAggInfo->groupId = tableGroupId; } void setCtxTagForJoin(STaskRuntimeEnv* pRuntimeEnv, SqlFunctionCtx* pCtx, SExprInfo* pExprInfo, void* pTable) { STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; SExprBasicInfo* pExpr = &pExprInfo->base; // if (pQueryAttr->stableQuery && (pRuntimeEnv->pTsBuf != NULL) && // (pExpr->functionId == FUNCTION_TS || pExpr->functionId == FUNCTION_PRJ) && // (pExpr->colInfo.colIndex == PRIMARYKEY_TIMESTAMP_COL_ID)) { // assert(pExpr->numOfParams == 1); // // int16_t tagColId = (int16_t)pExprInfo->base.param[0].i; // SColumnInfo* pColInfo = doGetTagColumnInfoById(pQueryAttr->tagColList, pQueryAttr->numOfTags, tagColId); // // doSetTagValueInParam(pTable, tagColId, &pCtx->tag, pColInfo->type, pColInfo->bytes); // // int16_t tagType = pCtx[0].tag.nType; // if (tagType == TSDB_DATA_TYPE_BINARY || tagType == TSDB_DATA_TYPE_NCHAR) { // //qDebug("QInfo:0x%"PRIx64" set tag value for join comparison, colId:%" PRId64 ", val:%s", // GET_TASKID(pRuntimeEnv), //// pExprInfo->base.param[0].i, pCtx[0].tag.pz); // } else { // //qDebug("QInfo:0x%"PRIx64" set tag value for join comparison, colId:%" PRId64 ", val:%" PRId64, // GET_TASKID(pRuntimeEnv), //// pExprInfo->base.param[0].i, pCtx[0].tag.i); // } // } } int32_t setTimestampListJoinInfo(STaskRuntimeEnv* pRuntimeEnv, SVariant* pTag, STableQueryInfo* pTableQueryInfo) { STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; assert(pRuntimeEnv->pTsBuf != NULL); #if 0 // both the master and supplement scan needs to set the correct ts comp start position if (pTableQueryInfo->cur.vgroupIndex == -1) { taosVariantAssign(&pTableQueryInfo->tag, pTag); STSElem elem = tsBufGetElemStartPos(pRuntimeEnv->pTsBuf, pQueryAttr->vgId, &pTableQueryInfo->tag); // failed to find data with the specified tag value and vnodeId if (!tsBufIsValidElem(&elem)) { if (pTag->nType == TSDB_DATA_TYPE_BINARY || pTag->nType == TSDB_DATA_TYPE_NCHAR) { //qError("QInfo:0x%"PRIx64" failed to find tag:%s in ts_comp", GET_TASKID(pRuntimeEnv), pTag->pz); } else { //qError("QInfo:0x%"PRIx64" failed to find tag:%" PRId64 " in ts_comp", GET_TASKID(pRuntimeEnv), pTag->i); } return -1; } // Keep the cursor info of current table pTableQueryInfo->cur = tsBufGetCursor(pRuntimeEnv->pTsBuf); if (pTag->nType == TSDB_DATA_TYPE_BINARY || pTag->nType == TSDB_DATA_TYPE_NCHAR) { //qDebug("QInfo:0x%"PRIx64" find tag:%s start pos in ts_comp, blockIndex:%d, tsIndex:%d", GET_TASKID(pRuntimeEnv), pTag->pz, pTableQueryInfo->cur.blockIndex, pTableQueryInfo->cur.tsIndex); } else { //qDebug("QInfo:0x%"PRIx64" find tag:%"PRId64" start pos in ts_comp, blockIndex:%d, tsIndex:%d", GET_TASKID(pRuntimeEnv), pTag->i, pTableQueryInfo->cur.blockIndex, pTableQueryInfo->cur.tsIndex); } } else { tsBufSetCursor(pRuntimeEnv->pTsBuf, &pTableQueryInfo->cur); if (pTag->nType == TSDB_DATA_TYPE_BINARY || pTag->nType == TSDB_DATA_TYPE_NCHAR) { //qDebug("QInfo:0x%"PRIx64" find tag:%s start pos in ts_comp, blockIndex:%d, tsIndex:%d", GET_TASKID(pRuntimeEnv), pTag->pz, pTableQueryInfo->cur.blockIndex, pTableQueryInfo->cur.tsIndex); } else { //qDebug("QInfo:0x%"PRIx64" find tag:%"PRId64" start pos in ts_comp, blockIndex:%d, tsIndex:%d", GET_TASKID(pRuntimeEnv), pTag->i, pTableQueryInfo->cur.blockIndex, pTableQueryInfo->cur.tsIndex); } } #endif return 0; } /* * 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. */ void setIntervalQueryRange(STaskRuntimeEnv* pRuntimeEnv, TSKEY key) { STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; STableQueryInfo* pTableQueryInfo = pRuntimeEnv->current; SResultRowInfo* pResultRowInfo = &pTableQueryInfo->resInfo; if (pResultRowInfo->curPos != -1) { return; } // pTableQueryInfo->win.skey = key; STimeWindow win = {.skey = key, .ekey = pQueryAttr->window.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; } /** * copyToOutputBuf support copy data in ascending/descending order * For interval query of both super table and table, copy the data in ascending order, since the output results are * ordered in SWindowResutl already. While handling the group by query for both table and super table, * all group result are completed already. * * @param pQInfo * @param result */ static int32_t doCopyToSDataBlock(SDiskbasedBuf* pBuf, SGroupResInfo* pGroupResInfo, int32_t orderType, SSDataBlock* pBlock, int32_t rowCapacity, int32_t* rowCellOffset) { int32_t numOfRows = getNumOfTotalRes(pGroupResInfo); int32_t numOfResult = pBlock->info.rows; // there are already exists result rows int32_t start = 0; int32_t step = -1; // qDebug("QInfo:0x%"PRIx64" start to copy data from windowResInfo to output buf", GET_TASKID(pRuntimeEnv)); assert(orderType == TSDB_ORDER_ASC || orderType == TSDB_ORDER_DESC); if (orderType == TSDB_ORDER_ASC) { start = pGroupResInfo->index; step = 1; } else { // desc order copy all data start = numOfRows - pGroupResInfo->index - 1; step = -1; } int32_t nrows = pBlock->info.rows; for (int32_t i = start; (i < numOfRows) && (i >= 0); i += step) { SResultRowPosition* pPos = taosArrayGet(pGroupResInfo->pRows, i); SFilePage* page = getBufPage(pBuf, pPos->pageId); SResultRow* pRow = (SResultRow*)((char*)page + pPos->offset); if (pRow->numOfRows == 0) { pGroupResInfo->index += 1; continue; } // TODO copy multiple rows? int32_t numOfRowsToCopy = pRow->numOfRows; if (numOfResult + numOfRowsToCopy >= rowCapacity) { break; } pGroupResInfo->index += 1; for (int32_t j = 0; j < pBlock->info.numOfCols; ++j) { SColumnInfoData* pColInfoData = taosArrayGet(pBlock->pDataBlock, j); SResultRowEntryInfo* pEntryInfo = getResultCell(pRow, j, rowCellOffset); char* in = GET_ROWCELL_INTERBUF(pEntryInfo); colDataAppend(pColInfoData, nrows, in, pEntryInfo->isNullRes); } releaseBufPage(pBuf, page); nrows += 1; numOfResult += numOfRowsToCopy; if (numOfResult == rowCapacity) { // output buffer is full break; } } // qDebug("QInfo:0x%"PRIx64" copy data to query buf completed", GET_TASKID(pRuntimeEnv)); pBlock->info.rows = numOfResult; return 0; } void toSDatablock(SGroupResInfo* pGroupResInfo, SDiskbasedBuf* pBuf, SSDataBlock* pBlock, int32_t rowCapacity, int32_t* rowCellOffset) { assert(pGroupResInfo->currentGroup <= pGroupResInfo->totalGroup); blockDataCleanup(pBlock); if (!hasRemainDataInCurrentGroup(pGroupResInfo)) { return; } int32_t orderType = TSDB_ORDER_ASC; doCopyToSDataBlock(pBuf, pGroupResInfo, orderType, pBlock, rowCapacity, rowCellOffset); // add condition (pBlock->info.rows >= 1) just to runtime happy blockDataUpdateTsWindow(pBlock); } static void updateNumOfRowsInResultRows(SqlFunctionCtx* pCtx, int32_t numOfOutput, SResultRowInfo* pResultRowInfo, int32_t* rowCellInfoOffset) { // update the number of result for each, only update the number of rows for the corresponding window result. // if (QUERY_IS_INTERVAL_QUERY(pQueryAttr)) { // return; // } #if 0 for (int32_t i = 0; i < pResultRowInfo->size; ++i) { SResultRow* pResult = pResultRowInfo->pResult[i]; for (int32_t j = 0; j < numOfOutput; ++j) { int32_t functionId = pCtx[j].functionId; if (functionId == FUNCTION_TS || functionId == FUNCTION_TAG || functionId == FUNCTION_TAGPRJ) { continue; } SResultRowEntryInfo* pCell = getResultCell(pResult, j, rowCellInfoOffset); pResult->numOfRows = (uint16_t)(TMAX(pResult->numOfRows, pCell->numOfRes)); } } #endif } static int32_t compressQueryColData(SColumnInfoData* pColRes, int32_t numOfRows, char* data, int8_t compressed) { int32_t colSize = pColRes->info.bytes * numOfRows; return (*(tDataTypes[pColRes->info.type].compFunc))(pColRes->pData, colSize, numOfRows, data, colSize + COMP_OVERFLOW_BYTES, compressed, NULL, 0); } int32_t doFillTimeIntervalGapsInResults(struct SFillInfo* pFillInfo, SSDataBlock* pOutput, int32_t capacity, void** p) { // for(int32_t i = 0; i < pFillInfo->numOfCols; ++i) { // SColumnInfoData* pColInfoData = taosArrayGet(pOutput->pDataBlock, i); // p[i] = pColInfoData->pData + (pColInfoData->info.bytes * pOutput->info.rows); // } int32_t numOfRows = (int32_t)taosFillResultDataBlock(pFillInfo, p, capacity - pOutput->info.rows); pOutput->info.rows += numOfRows; return pOutput->info.rows; } void publishOperatorProfEvent(SOperatorInfo* operatorInfo, EQueryProfEventType eventType) { SQueryProfEvent event = {0}; event.eventType = eventType; event.eventTime = taosGetTimestampUs(); event.operatorType = operatorInfo->operatorType; if (operatorInfo->pRuntimeEnv) { // SQInfo* pQInfo = operatorInfo->pRuntimeEnv->qinfo; // if (pQInfo->summary.queryProfEvents) { // taosArrayPush(pQInfo->summary.queryProfEvents, &event); // } } } void publishQueryAbortEvent(SExecTaskInfo* pTaskInfo, int32_t code) { SQueryProfEvent event; event.eventType = QUERY_PROF_QUERY_ABORT; event.eventTime = taosGetTimestampUs(); event.abortCode = code; if (pTaskInfo->cost.queryProfEvents) { taosArrayPush(pTaskInfo->cost.queryProfEvents, &event); } } typedef struct { uint8_t operatorType; int64_t beginTime; int64_t endTime; int64_t selfTime; int64_t descendantsTime; } SOperatorStackItem; static void doOperatorExecProfOnce(SOperatorStackItem* item, SQueryProfEvent* event, SArray* opStack, SHashObj* profResults) { item->endTime = event->eventTime; item->selfTime = (item->endTime - item->beginTime) - (item->descendantsTime); for (int32_t j = 0; j < taosArrayGetSize(opStack); ++j) { SOperatorStackItem* ancestor = taosArrayGet(opStack, j); ancestor->descendantsTime += item->selfTime; } uint8_t operatorType = item->operatorType; SOperatorProfResult* result = taosHashGet(profResults, &operatorType, sizeof(operatorType)); if (result != NULL) { result->sumRunTimes++; result->sumSelfTime += item->selfTime; } else { SOperatorProfResult opResult; opResult.operatorType = operatorType; opResult.sumSelfTime = item->selfTime; opResult.sumRunTimes = 1; taosHashPut(profResults, &(operatorType), sizeof(operatorType), &opResult, sizeof(opResult)); } } void calculateOperatorProfResults(SQInfo* pQInfo) { if (pQInfo->summary.queryProfEvents == NULL) { // qDebug("QInfo:0x%"PRIx64" query prof events array is null", pQInfo->qId); return; } if (pQInfo->summary.operatorProfResults == NULL) { // qDebug("QInfo:0x%"PRIx64" operator prof results hash is null", pQInfo->qId); return; } SArray* opStack = taosArrayInit(32, sizeof(SOperatorStackItem)); if (opStack == NULL) { return; } size_t size = taosArrayGetSize(pQInfo->summary.queryProfEvents); SHashObj* profResults = pQInfo->summary.operatorProfResults; for (int i = 0; i < size; ++i) { SQueryProfEvent* event = taosArrayGet(pQInfo->summary.queryProfEvents, i); if (event->eventType == QUERY_PROF_BEFORE_OPERATOR_EXEC) { SOperatorStackItem opItem; opItem.operatorType = event->operatorType; opItem.beginTime = event->eventTime; opItem.descendantsTime = 0; taosArrayPush(opStack, &opItem); } else if (event->eventType == QUERY_PROF_AFTER_OPERATOR_EXEC) { SOperatorStackItem* item = taosArrayPop(opStack); assert(item->operatorType == event->operatorType); doOperatorExecProfOnce(item, event, opStack, profResults); } else if (event->eventType == QUERY_PROF_QUERY_ABORT) { SOperatorStackItem* item; while ((item = taosArrayPop(opStack)) != NULL) { doOperatorExecProfOnce(item, event, opStack, profResults); } } } taosArrayDestroy(opStack); } void queryCostStatis(SExecTaskInfo* pTaskInfo) { STaskCostInfo* pSummary = &pTaskInfo->cost; // uint64_t hashSize = taosHashGetMemSize(pQInfo->runtimeEnv.pResultRowHashTable); // hashSize += taosHashGetMemSize(pRuntimeEnv->tableqinfoGroupInfo.map); // pSummary->hashSize = hashSize; // add the merge time pSummary->elapsedTime += pSummary->firstStageMergeTime; // SResultRowPool* p = pTaskInfo->pool; // if (p != NULL) { // pSummary->winInfoSize = getResultRowPoolMemSize(p); // pSummary->numOfTimeWindows = getNumOfAllocatedResultRows(p); // } else { // pSummary->winInfoSize = 0; // pSummary->numOfTimeWindows = 0; // } // // calculateOperatorProfResults(pQInfo); qDebug("%s :cost summary: elapsed time:%" PRId64 " us, first merge:%" PRId64 " us, total blocks:%d, " "load block statis:%d, load data block:%d, total rows:%" PRId64 ", check rows:%" PRId64, GET_TASKID(pTaskInfo), pSummary->elapsedTime, pSummary->firstStageMergeTime, pSummary->totalBlocks, pSummary->loadBlockStatis, pSummary->loadBlocks, pSummary->totalRows, pSummary->totalCheckedRows); // // qDebug("QInfo:0x%"PRIx64" :cost summary: winResPool size:%.2f Kb, numOfWin:%"PRId64", tableInfoSize:%.2f Kb, // hashTable:%.2f Kb", pQInfo->qId, pSummary->winInfoSize/1024.0, // pSummary->numOfTimeWindows, pSummary->tableInfoSize/1024.0, pSummary->hashSize/1024.0); if (pSummary->operatorProfResults) { SOperatorProfResult* opRes = taosHashIterate(pSummary->operatorProfResults, NULL); while (opRes != NULL) { // qDebug("QInfo:0x%" PRIx64 " :cost summary: operator : %d, exec times: %" PRId64 ", self time: %" PRId64, // pQInfo->qId, opRes->operatorType, opRes->sumRunTimes, opRes->sumSelfTime); opRes = taosHashIterate(pSummary->operatorProfResults, opRes); } } } // static void updateOffsetVal(STaskRuntimeEnv *pRuntimeEnv, SDataBlockInfo *pBlockInfo) { // STaskAttr *pQueryAttr = pRuntimeEnv->pQueryAttr; // STableQueryInfo* pTableQueryInfo = pRuntimeEnv->current; // // int32_t step = GET_FORWARD_DIRECTION_FACTOR(pQueryAttr->order.order); // // if (pQueryAttr->limit.offset == pBlockInfo->rows) { // current block will ignore completed // pTableQueryInfo->lastKey = QUERY_IS_ASC_QUERY(pQueryAttr) ? pBlockInfo->window.ekey + step : // pBlockInfo->window.skey + step; pQueryAttr->limit.offset = 0; return; // } // // if (QUERY_IS_ASC_QUERY(pQueryAttr)) { // pQueryAttr->pos = (int32_t)pQueryAttr->limit.offset; // } else { // pQueryAttr->pos = pBlockInfo->rows - (int32_t)pQueryAttr->limit.offset - 1; // } // // assert(pQueryAttr->pos >= 0 && pQueryAttr->pos <= pBlockInfo->rows - 1); // // SArray * pDataBlock = tsdbRetrieveDataBlock(pRuntimeEnv->pTsdbReadHandle, NULL); // SColumnInfoData *pColInfoData = taosArrayGet(pDataBlock, 0); // // // update the pQueryAttr->limit.offset value, and pQueryAttr->pos value // TSKEY *keys = (TSKEY *) pColInfoData->pData; // // // update the offset value // pTableQueryInfo->lastKey = keys[pQueryAttr->pos]; // pQueryAttr->limit.offset = 0; // // int32_t numOfRes = tableApplyFunctionsOnBlock(pRuntimeEnv, pBlockInfo, NULL, binarySearchForKey, pDataBlock); // // //qDebug("QInfo:0x%"PRIx64" check data block, brange:%" PRId64 "-%" PRId64 ", numBlocksOfStep:%d, numOfRes:%d, // lastKey:%"PRId64, GET_TASKID(pRuntimeEnv), // pBlockInfo->window.skey, pBlockInfo->window.ekey, pBlockInfo->rows, numOfRes, pQuery->current->lastKey); // } // void skipBlocks(STaskRuntimeEnv *pRuntimeEnv) { // STaskAttr *pQueryAttr = pRuntimeEnv->pQueryAttr; // // if (pQueryAttr->limit.offset <= 0 || pQueryAttr->numOfFilterCols > 0) { // return; // } // // pQueryAttr->pos = 0; // int32_t step = GET_FORWARD_DIRECTION_FACTOR(pQueryAttr->order.order); // // STableQueryInfo* pTableQueryInfo = pRuntimeEnv->current; // TsdbQueryHandleT pTsdbReadHandle = pRuntimeEnv->pTsdbReadHandle; // // SDataBlockInfo blockInfo = SDATA_BLOCK_INITIALIZER; // while (tsdbNextDataBlock(pTsdbReadHandle)) { // if (isTaskKilled(pRuntimeEnv->qinfo)) { // longjmp(pRuntimeEnv->env, TSDB_CODE_TSC_QUERY_CANCELLED); // } // // tsdbRetrieveDataBlockInfo(pTsdbReadHandle, &blockInfo); // // if (pQueryAttr->limit.offset > blockInfo.rows) { // pQueryAttr->limit.offset -= blockInfo.rows; // pTableQueryInfo->lastKey = (QUERY_IS_ASC_QUERY(pQueryAttr)) ? blockInfo.window.ekey : blockInfo.window.skey; // pTableQueryInfo->lastKey += step; // // //qDebug("QInfo:0x%"PRIx64" skip rows:%d, offset:%" PRId64, GET_TASKID(pRuntimeEnv), blockInfo.rows, // pQuery->limit.offset); // } else { // find the appropriated start position in current block // updateOffsetVal(pRuntimeEnv, &blockInfo); // break; // } // } // // if (terrno != TSDB_CODE_SUCCESS) { // longjmp(pRuntimeEnv->env, terrno); // } // } // static TSKEY doSkipIntervalProcess(STaskRuntimeEnv* pRuntimeEnv, STimeWindow* win, SDataBlockInfo* pBlockInfo, // STableQueryInfo* pTableQueryInfo) { // STaskAttr *pQueryAttr = pRuntimeEnv->pQueryAttr; // SResultRowInfo *pWindowResInfo = &pRuntimeEnv->resultRowInfo; // // assert(pQueryAttr->limit.offset == 0); // STimeWindow tw = *win; // getNextTimeWindow(pQueryAttr, &tw); // // if ((tw.skey <= pBlockInfo->window.ekey && QUERY_IS_ASC_QUERY(pQueryAttr)) || // (tw.ekey >= pBlockInfo->window.skey && !QUERY_IS_ASC_QUERY(pQueryAttr))) { // // // load the data block and check data remaining in current data block // // TODO optimize performance // SArray * pDataBlock = tsdbRetrieveDataBlock(pRuntimeEnv->pTsdbReadHandle, NULL); // SColumnInfoData *pColInfoData = taosArrayGet(pDataBlock, 0); // // tw = *win; // int32_t startPos = // getNextQualifiedWindow(pQueryAttr, &tw, pBlockInfo, pColInfoData->pData, binarySearchForKey, -1); // assert(startPos >= 0); // // // set the abort info // pQueryAttr->pos = startPos; // // // reset the query start timestamp // pTableQueryInfo->win.skey = ((TSKEY *)pColInfoData->pData)[startPos]; // pQueryAttr->window.skey = pTableQueryInfo->win.skey; // TSKEY key = pTableQueryInfo->win.skey; // // pWindowResInfo->prevSKey = tw.skey; // int32_t index = pRuntimeEnv->resultRowInfo.curIndex; // // int32_t numOfRes = tableApplyFunctionsOnBlock(pRuntimeEnv, pBlockInfo, NULL, binarySearchForKey, pDataBlock); // pRuntimeEnv->resultRowInfo.curIndex = index; // restore the window index // // //qDebug("QInfo:0x%"PRIx64" check data block, brange:%" PRId64 "-%" PRId64 ", numOfRows:%d, numOfRes:%d, // lastKey:%" PRId64, // GET_TASKID(pRuntimeEnv), pBlockInfo->window.skey, pBlockInfo->window.ekey, pBlockInfo->rows, numOfRes, // pQueryAttr->current->lastKey); // // return key; // } else { // do nothing // pQueryAttr->window.skey = tw.skey; // pWindowResInfo->prevSKey = tw.skey; // pTableQueryInfo->lastKey = tw.skey; // // return tw.skey; // } // // return true; // } // static bool skipTimeInterval(STaskRuntimeEnv *pRuntimeEnv, TSKEY* start) { // STaskAttr *pQueryAttr = pRuntimeEnv->pQueryAttr; // if (QUERY_IS_ASC_QUERY(pQueryAttr)) { // assert(*start <= pRuntimeEnv->current->lastKey); // } else { // assert(*start >= pRuntimeEnv->current->lastKey); // } // // // if queried with value filter, do NOT forward query start position // if (pQueryAttr->limit.offset <= 0 || pQueryAttr->numOfFilterCols > 0 || pRuntimeEnv->pTsBuf != NULL || // pRuntimeEnv->pFillInfo != NULL) { // return true; // } // // /* // * 1. for interval without interpolation query we forward pQueryAttr->interval.interval at a time for // * pQueryAttr->limit.offset times. Since hole exists, pQueryAttr->interval.interval*pQueryAttr->limit.offset // value is // * not valid. otherwise, we only forward pQueryAttr->limit.offset number of points // */ // assert(pRuntimeEnv->resultRowInfo.prevSKey == TSKEY_INITIAL_VAL); // // STimeWindow w = TSWINDOW_INITIALIZER; // bool ascQuery = QUERY_IS_ASC_QUERY(pQueryAttr); // // SResultRowInfo *pWindowResInfo = &pRuntimeEnv->resultRowInfo; // STableQueryInfo *pTableQueryInfo = pRuntimeEnv->current; // // SDataBlockInfo blockInfo = SDATA_BLOCK_INITIALIZER; // while (tsdbNextDataBlock(pRuntimeEnv->pTsdbReadHandle)) { // tsdbRetrieveDataBlockInfo(pRuntimeEnv->pTsdbReadHandle, &blockInfo); // // if (QUERY_IS_ASC_QUERY(pQueryAttr)) { // if (pWindowResInfo->prevSKey == TSKEY_INITIAL_VAL) { // getAlignQueryTimeWindow(pQueryAttr, blockInfo.window.skey, blockInfo.window.skey, pQueryAttr->window.ekey, // &w); pWindowResInfo->prevSKey = w.skey; // } // } else { // getAlignQueryTimeWindow(pQueryAttr, blockInfo.window.ekey, pQueryAttr->window.ekey, blockInfo.window.ekey, &w); // pWindowResInfo->prevSKey = w.skey; // } // // // the first time window // STimeWindow win = getActiveTimeWindow(pWindowResInfo, pWindowResInfo->prevSKey, pQueryAttr); // // while (pQueryAttr->limit.offset > 0) { // STimeWindow tw = win; // // if ((win.ekey <= blockInfo.window.ekey && ascQuery) || (win.ekey >= blockInfo.window.skey && !ascQuery)) { // pQueryAttr->limit.offset -= 1; // pWindowResInfo->prevSKey = win.skey; // // // current time window is aligned with blockInfo.window.ekey // // restart it from next data block by set prevSKey to be TSKEY_INITIAL_VAL; // if ((win.ekey == blockInfo.window.ekey && ascQuery) || (win.ekey == blockInfo.window.skey && !ascQuery)) { // pWindowResInfo->prevSKey = TSKEY_INITIAL_VAL; // } // } // // if (pQueryAttr->limit.offset == 0) { // *start = doSkipIntervalProcess(pRuntimeEnv, &win, &blockInfo, pTableQueryInfo); // return true; // } // // // current window does not ended in current data block, try next data block // getNextTimeWindow(pQueryAttr, &tw); // // /* // * If the next time window still starts from current data block, // * load the primary timestamp column first, and then find the start position for the next queried time window. // * Note that only the primary timestamp column is required. // * TODO: Optimize for this cases. All data blocks are not needed to be loaded, only if the first actually // required // * time window resides in current data block. // */ // if ((tw.skey <= blockInfo.window.ekey && ascQuery) || (tw.ekey >= blockInfo.window.skey && !ascQuery)) { // // SArray *pDataBlock = tsdbRetrieveDataBlock(pRuntimeEnv->pTsdbReadHandle, NULL); // SColumnInfoData *pColInfoData = taosArrayGet(pDataBlock, 0); // // if ((win.ekey > blockInfo.window.ekey && ascQuery) || (win.ekey < blockInfo.window.skey && !ascQuery)) { // pQueryAttr->limit.offset -= 1; // } // // if (pQueryAttr->limit.offset == 0) { // *start = doSkipIntervalProcess(pRuntimeEnv, &win, &blockInfo, pTableQueryInfo); // return true; // } else { // tw = win; // int32_t startPos = // getNextQualifiedWindow(pQueryAttr, &tw, &blockInfo, pColInfoData->pData, binarySearchForKey, -1); // assert(startPos >= 0); // // // set the abort info // pQueryAttr->pos = startPos; // pTableQueryInfo->lastKey = ((TSKEY *)pColInfoData->pData)[startPos]; // pWindowResInfo->prevSKey = tw.skey; // win = tw; // } // } else { // break; // offset is not 0, and next time window begins or ends in the next block. // } // } // } // // // check for error // if (terrno != TSDB_CODE_SUCCESS) { // longjmp(pRuntimeEnv->env, terrno); // } // // return true; // } int32_t appendDownstream(SOperatorInfo* p, SOperatorInfo** pDownstream, int32_t num) { if (p->pDownstream == NULL) { assert(p->numOfDownstream == 0); } p->pDownstream = taosMemoryCalloc(1, num * POINTER_BYTES); if (p->pDownstream == NULL) { return TSDB_CODE_OUT_OF_MEMORY; } memcpy(p->pDownstream, pDownstream, num * POINTER_BYTES); p->numOfDownstream = num; return TSDB_CODE_SUCCESS; } static void doDestroyTableQueryInfo(STableGroupInfo* pTableqinfoGroupInfo); static int32_t setupQueryHandle(void* tsdb, STaskRuntimeEnv* pRuntimeEnv, int64_t qId, bool isSTableQuery) { STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; #if 0 // TODO set the tags scan handle if (onlyQueryTags(pQueryAttr)) { return TSDB_CODE_SUCCESS; } STsdbQueryCond cond = createTsdbQueryCond(pQueryAttr, &pQueryAttr->window); if (pQueryAttr->tsCompQuery || pQueryAttr->pointInterpQuery) { cond.type = BLOCK_LOAD_TABLE_SEQ_ORDER; } if (!isSTableQuery && (pRuntimeEnv->tableqinfoGroupInfo.numOfTables == 1) && (cond.order == TSDB_ORDER_ASC) && (!QUERY_IS_INTERVAL_QUERY(pQueryAttr)) && (!pQueryAttr->groupbyColumn) && (!pQueryAttr->simpleAgg) ) { SArray* pa = GET_TABLEGROUP(pRuntimeEnv, 0); STableQueryInfo* pCheckInfo = taosArrayGetP(pa, 0); cond.twindow = pCheckInfo->win; } terrno = TSDB_CODE_SUCCESS; if (isFirstLastRowQuery(pQueryAttr)) { pRuntimeEnv->pTsdbReadHandle = tsdbQueryLastRow(tsdb, &cond, &pQueryAttr->tableGroupInfo, qId, &pQueryAttr->memRef); // update the query time window pQueryAttr->window = cond.twindow; if (pQueryAttr->tableGroupInfo.numOfTables == 0) { pRuntimeEnv->tableqinfoGroupInfo.numOfTables = 0; } else { size_t numOfGroups = GET_NUM_OF_TABLEGROUP(pRuntimeEnv); for(int32_t i = 0; i < numOfGroups; ++i) { SArray *group = GET_TABLEGROUP(pRuntimeEnv, i); size_t t = taosArrayGetSize(group); for (int32_t j = 0; j < t; ++j) { STableQueryInfo *pCheckInfo = taosArrayGetP(group, j); pCheckInfo->win = pQueryAttr->window; pCheckInfo->lastKey = pCheckInfo->win.skey; } } } } else if (isCachedLastQuery(pQueryAttr)) { pRuntimeEnv->pTsdbReadHandle = tsdbQueryCacheLast(tsdb, &cond, &pQueryAttr->tableGroupInfo, qId, &pQueryAttr->memRef); } else if (pQueryAttr->pointInterpQuery) { pRuntimeEnv->pTsdbReadHandle = tsdbQueryRowsInExternalWindow(tsdb, &cond, &pQueryAttr->tableGroupInfo, qId, &pQueryAttr->memRef); } else { pRuntimeEnv->pTsdbReadHandle = tsdbQueryTables(tsdb, &cond, &pQueryAttr->tableGroupInfo, qId, &pQueryAttr->memRef); } #endif return terrno; } static void doTableQueryInfoTimeWindowCheck(SExecTaskInfo* pTaskInfo, STableQueryInfo* pTableQueryInfo, int32_t order) { #if 0 if (order == TSDB_ORDER_ASC) { assert( (pTableQueryInfo->win.skey <= pTableQueryInfo->win.ekey) && (pTableQueryInfo->lastKey >= pTaskInfo->window.skey) && (pTableQueryInfo->win.skey >= pTaskInfo->window.skey && pTableQueryInfo->win.ekey <= pTaskInfo->window.ekey)); } else { assert( (pTableQueryInfo->win.skey >= pTableQueryInfo->win.ekey) && (pTableQueryInfo->lastKey <= pTaskInfo->window.skey) && (pTableQueryInfo->win.skey <= pTaskInfo->window.skey && pTableQueryInfo->win.ekey >= pTaskInfo->window.ekey)); } #endif } // STsdbQueryCond createTsdbQueryCond(STaskAttr* pQueryAttr, STimeWindow* win) { // STsdbQueryCond cond = { // .colList = pQueryAttr->tableCols, // .order = pQueryAttr->order.order, // .numOfCols = pQueryAttr->numOfCols, // .type = BLOCK_LOAD_OFFSET_SEQ_ORDER, // .loadExternalRows = false, // }; // // TIME_WINDOW_COPY(cond.twindow, *win); // return cond; // } static STableIdInfo createTableIdInfo(STableQueryInfo* pTableQueryInfo) { STableIdInfo tidInfo; // STableId* id = TSDB_TABLEID(pTableQueryInfo->pTable); // // tidInfo.uid = id->uid; // tidInfo.tid = id->tid; // tidInfo.key = pTableQueryInfo->lastKey; return tidInfo; } // static void updateTableIdInfo(STableQueryInfo* pTableQueryInfo, SSDataBlock* pBlock, SHashObj* pTableIdInfo, int32_t // order) { // int32_t step = GET_FORWARD_DIRECTION_FACTOR(order); // pTableQueryInfo->lastKey = ((order == TSDB_ORDER_ASC)? pBlock->info.window.ekey:pBlock->info.window.skey) + step; // // if (pTableQueryInfo->pTable == NULL) { // return; // } // // STableIdInfo tidInfo = createTableIdInfo(pTableQueryInfo); // STableIdInfo *idinfo = taosHashGet(pTableIdInfo, &tidInfo.tid, sizeof(tidInfo.tid)); // if (idinfo != NULL) { // assert(idinfo->tid == tidInfo.tid && idinfo->uid == tidInfo.uid); // idinfo->key = tidInfo.key; // } else { // taosHashPut(pTableIdInfo, &tidInfo.tid, sizeof(tidInfo.tid), &tidInfo, sizeof(STableIdInfo)); // } // } static void doCloseAllTimeWindow(STaskRuntimeEnv* pRuntimeEnv) { size_t numOfGroup = GET_NUM_OF_TABLEGROUP(pRuntimeEnv); for (int32_t i = 0; i < numOfGroup; ++i) { SArray* group = GET_TABLEGROUP(pRuntimeEnv, i); size_t num = taosArrayGetSize(group); for (int32_t j = 0; j < num; ++j) { STableQueryInfo* item = taosArrayGetP(group, j); closeAllResultRows(&item->resInfo); } } } int32_t loadRemoteDataCallback(void* param, const SDataBuf* pMsg, int32_t code) { SSourceDataInfo* pSourceDataInfo = (SSourceDataInfo*)param; if (code == TSDB_CODE_SUCCESS) { pSourceDataInfo->pRsp = pMsg->pData; SRetrieveTableRsp* pRsp = pSourceDataInfo->pRsp; pRsp->numOfRows = htonl(pRsp->numOfRows); pRsp->compLen = htonl(pRsp->compLen); pRsp->useconds = htobe64(pRsp->useconds); } else { pSourceDataInfo->code = code; } pSourceDataInfo->status = EX_SOURCE_DATA_READY; tsem_post(&pSourceDataInfo->pEx->ready); } static void destroySendMsgInfo(SMsgSendInfo* pMsgBody) { assert(pMsgBody != NULL); taosMemoryFreeClear(pMsgBody->msgInfo.pData); taosMemoryFreeClear(pMsgBody); } void qProcessFetchRsp(void* parent, SRpcMsg* pMsg, SEpSet* pEpSet) { SMsgSendInfo* pSendInfo = (SMsgSendInfo*)pMsg->ahandle; assert(pMsg->ahandle != NULL); SDataBuf buf = {.len = pMsg->contLen, .pData = NULL}; if (pMsg->contLen > 0) { buf.pData = taosMemoryCalloc(1, pMsg->contLen); if (buf.pData == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; pMsg->code = TSDB_CODE_OUT_OF_MEMORY; } else { memcpy(buf.pData, pMsg->pCont, pMsg->contLen); } } pSendInfo->fp(pSendInfo->param, &buf, pMsg->code); rpcFreeCont(pMsg->pCont); destroySendMsgInfo(pSendInfo); } static int32_t doSendFetchDataRequest(SExchangeInfo* pExchangeInfo, SExecTaskInfo* pTaskInfo, int32_t sourceIndex) { size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); SResFetchReq* pMsg = taosMemoryCalloc(1, sizeof(SResFetchReq)); if (NULL == pMsg) { pTaskInfo->code = TSDB_CODE_QRY_OUT_OF_MEMORY; return pTaskInfo->code; } SDownstreamSourceNode* pSource = taosArrayGet(pExchangeInfo->pSources, sourceIndex); SSourceDataInfo* pDataInfo = taosArrayGet(pExchangeInfo->pSourceDataInfo, sourceIndex); qDebug("%s build fetch msg and send to vgId:%d, ep:%s, taskId:0x%" PRIx64 ", %d/%" PRIzu, GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->addr.epSet.eps[0].fqdn, pSource->taskId, sourceIndex, totalSources); pMsg->header.vgId = htonl(pSource->addr.nodeId); pMsg->sId = htobe64(pSource->schedId); pMsg->taskId = htobe64(pSource->taskId); pMsg->queryId = htobe64(pTaskInfo->id.queryId); // send the fetch remote task result reques SMsgSendInfo* pMsgSendInfo = taosMemoryCalloc(1, sizeof(SMsgSendInfo)); if (NULL == pMsgSendInfo) { taosMemoryFreeClear(pMsg); qError("%s prepare message %d failed", GET_TASKID(pTaskInfo), (int32_t)sizeof(SMsgSendInfo)); pTaskInfo->code = TSDB_CODE_QRY_OUT_OF_MEMORY; return pTaskInfo->code; } pMsgSendInfo->param = pDataInfo; pMsgSendInfo->msgInfo.pData = pMsg; pMsgSendInfo->msgInfo.len = sizeof(SResFetchReq); pMsgSendInfo->msgType = TDMT_VND_FETCH; pMsgSendInfo->fp = loadRemoteDataCallback; int64_t transporterId = 0; int32_t code = asyncSendMsgToServer(pExchangeInfo->pTransporter, &pSource->addr.epSet, &transporterId, pMsgSendInfo); return TSDB_CODE_SUCCESS; } // TODO if only one or two columnss required, how to extract data? int32_t setSDataBlockFromFetchRsp(SSDataBlock* pRes, SLoadRemoteDataInfo* pLoadInfo, int32_t numOfRows, char* pData, int32_t compLen, int32_t numOfOutput, int64_t startTs, uint64_t* total, SArray* pColList) { blockDataEnsureCapacity(pRes, numOfRows); if (pColList == NULL) { // data from other sources int32_t* colLen = (int32_t*)pData; char* pStart = pData + sizeof(int32_t) * numOfOutput; for (int32_t i = 0; i < numOfOutput; ++i) { colLen[i] = htonl(colLen[i]); ASSERT(colLen[i] > 0); SColumnInfoData* pColInfoData = taosArrayGet(pRes->pDataBlock, i); if (IS_VAR_DATA_TYPE(pColInfoData->info.type)) { pColInfoData->varmeta.length = colLen[i]; pColInfoData->varmeta.allocLen = colLen[i]; memcpy(pColInfoData->varmeta.offset, pStart, sizeof(int32_t) * numOfRows); pStart += sizeof(int32_t) * numOfRows; pColInfoData->pData = taosMemoryMalloc(colLen[i]); } else { memcpy(pColInfoData->nullbitmap, pStart, BitmapLen(numOfRows)); pStart += BitmapLen(numOfRows); } memcpy(pColInfoData->pData, pStart, colLen[i]); pStart += colLen[i]; } } else { // extract data according to pColList ASSERT(numOfOutput == taosArrayGetSize(pColList)); // data from mnode for (int32_t i = 0; i < numOfOutput; ++i) { for (int32_t j = 0; j < numOfOutput; ++j) { int16_t colIndex = *(int16_t*)taosArrayGet(pColList, j); if (colIndex - 1 == i) { SColumnInfoData* pColInfoData = taosArrayGet(pRes->pDataBlock, j); for (int32_t k = 0; k < numOfRows; ++k) { colDataAppend(pColInfoData, k, pData, false); pData += pColInfoData->info.bytes; } break; } } } } pRes->info.rows = numOfRows; int64_t el = taosGetTimestampUs() - startTs; pLoadInfo->totalRows += numOfRows; pLoadInfo->totalSize += compLen; if (total != NULL) { *total += numOfRows; } pLoadInfo->totalElapsed += el; return TSDB_CODE_SUCCESS; } static void* setAllSourcesCompleted(SOperatorInfo* pOperator, int64_t startTs) { SExchangeInfo* pExchangeInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; int64_t el = taosGetTimestampUs() - startTs; SLoadRemoteDataInfo* pLoadInfo = &pExchangeInfo->loadInfo; pLoadInfo->totalElapsed += el; size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); qDebug("%s all %" PRIzu " sources are exhausted, total rows: %" PRIu64 " bytes:%" PRIu64 ", elapsed:%.2f ms", GET_TASKID(pTaskInfo), totalSources, pLoadInfo->totalRows, pLoadInfo->totalSize, pLoadInfo->totalElapsed / 1000.0); doSetOperatorCompleted(pOperator); return NULL; } static SSDataBlock* concurrentlyLoadRemoteDataImpl(SOperatorInfo* pOperator, SExchangeInfo* pExchangeInfo, SExecTaskInfo* pTaskInfo) { int32_t code = 0; int64_t startTs = taosGetTimestampUs(); size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); while (1) { int32_t completed = 0; for (int32_t i = 0; i < totalSources; ++i) { SSourceDataInfo* pDataInfo = taosArrayGet(pExchangeInfo->pSourceDataInfo, i); if (pDataInfo->status == EX_SOURCE_DATA_EXHAUSTED) { completed += 1; continue; } if (pDataInfo->status != EX_SOURCE_DATA_READY) { continue; } SRetrieveTableRsp* pRsp = pDataInfo->pRsp; SDownstreamSourceNode* pSource = taosArrayGet(pExchangeInfo->pSources, i); SSDataBlock* pRes = pExchangeInfo->pResult; SLoadRemoteDataInfo* pLoadInfo = &pExchangeInfo->loadInfo; if (pRsp->numOfRows == 0) { qDebug("%s vgId:%d, taskID:0x%" PRIx64 " index:%d completed, rowsOfSource:%" PRIu64 ", totalRows:%" PRIu64 " try next", GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, i + 1, pDataInfo->totalRows, pExchangeInfo->loadInfo.totalRows); pDataInfo->status = EX_SOURCE_DATA_EXHAUSTED; completed += 1; continue; } SRetrieveTableRsp* pTableRsp = pDataInfo->pRsp; code = setSDataBlockFromFetchRsp(pExchangeInfo->pResult, pLoadInfo, pTableRsp->numOfRows, pTableRsp->data, pTableRsp->compLen, pOperator->numOfOutput, startTs, &pDataInfo->totalRows, NULL); if (code != 0) { goto _error; } if (pRsp->completed == 1) { qDebug("%s fetch msg rsp from vgId:%d, taskId:0x%" PRIx64 " numOfRows:%d, rowsOfSource:%" PRIu64 ", totalRows:%" PRIu64 ", totalBytes:%" PRIu64 " try next %d/%" PRIzu, GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, pRes->info.rows, pDataInfo->totalRows, pLoadInfo->totalRows, pLoadInfo->totalSize, i + 1, totalSources); pDataInfo->status = EX_SOURCE_DATA_EXHAUSTED; } else { qDebug("%s fetch msg rsp from vgId:%d, taskId:0x%" PRIx64 " numOfRows:%d, totalRows:%" PRIu64 ", totalBytes:%" PRIu64, GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, pRes->info.rows, pLoadInfo->totalRows, pLoadInfo->totalSize); } if (pDataInfo->status != EX_SOURCE_DATA_EXHAUSTED) { pDataInfo->status = EX_SOURCE_DATA_NOT_READY; code = doSendFetchDataRequest(pExchangeInfo, pTaskInfo, i); if (code != TSDB_CODE_SUCCESS) { goto _error; } } return pExchangeInfo->pResult; } if (completed == totalSources) { return setAllSourcesCompleted(pOperator, startTs); } } _error: pTaskInfo->code = code; return NULL; } static SSDataBlock* concurrentlyLoadRemoteData(SOperatorInfo* pOperator) { SExchangeInfo* pExchangeInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; if (pOperator->status == OP_RES_TO_RETURN) { return concurrentlyLoadRemoteDataImpl(pOperator, pExchangeInfo, pTaskInfo); } size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); int64_t startTs = taosGetTimestampUs(); // Asynchronously send all fetch requests to all sources. for (int32_t i = 0; i < totalSources; ++i) { int32_t code = doSendFetchDataRequest(pExchangeInfo, pTaskInfo, i); if (code != TSDB_CODE_SUCCESS) { return NULL; } } int64_t endTs = taosGetTimestampUs(); qDebug("%s send all fetch request to %" PRIzu " sources completed, elapsed:%" PRId64, GET_TASKID(pTaskInfo), totalSources, endTs - startTs); tsem_wait(&pExchangeInfo->ready); pOperator->status = OP_RES_TO_RETURN; return concurrentlyLoadRemoteDataImpl(pOperator, pExchangeInfo, pTaskInfo); } static int32_t prepareConcurrentlyLoad(SOperatorInfo* pOperator) { SExchangeInfo* pExchangeInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); int64_t startTs = taosGetTimestampUs(); // Asynchronously send all fetch requests to all sources. for (int32_t i = 0; i < totalSources; ++i) { int32_t code = doSendFetchDataRequest(pExchangeInfo, pTaskInfo, i); if (code != TSDB_CODE_SUCCESS) { pTaskInfo->code = code; return code; } } int64_t endTs = taosGetTimestampUs(); qDebug("%s send all fetch request to %" PRIzu " sources completed, elapsed:%" PRId64, GET_TASKID(pTaskInfo), totalSources, endTs - startTs); tsem_wait(&pExchangeInfo->ready); pOperator->cost.openCost = taosGetTimestampUs() - startTs; return TSDB_CODE_SUCCESS; } static SSDataBlock* seqLoadRemoteData(SOperatorInfo* pOperator) { SExchangeInfo* pExchangeInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); int64_t startTs = taosGetTimestampUs(); while (1) { if (pExchangeInfo->current >= totalSources) { return setAllSourcesCompleted(pOperator, startTs); } doSendFetchDataRequest(pExchangeInfo, pTaskInfo, pExchangeInfo->current); tsem_wait(&pExchangeInfo->ready); SSourceDataInfo* pDataInfo = taosArrayGet(pExchangeInfo->pSourceDataInfo, pExchangeInfo->current); SDownstreamSourceNode* pSource = taosArrayGet(pExchangeInfo->pSources, pExchangeInfo->current); if (pDataInfo->code != TSDB_CODE_SUCCESS) { qError("%s vgId:%d, taskID:0x%" PRIx64 " error happens, code:%s", GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, tstrerror(pDataInfo->code)); pOperator->pTaskInfo->code = pDataInfo->code; return NULL; } SRetrieveTableRsp* pRsp = pDataInfo->pRsp; SLoadRemoteDataInfo* pLoadInfo = &pExchangeInfo->loadInfo; if (pRsp->numOfRows == 0) { qDebug("%s vgId:%d, taskID:0x%" PRIx64 " %d of total completed, rowsOfSource:%" PRIu64 ", totalRows:%" PRIu64 " try next", GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, pExchangeInfo->current + 1, pDataInfo->totalRows, pLoadInfo->totalRows); pDataInfo->status = EX_SOURCE_DATA_EXHAUSTED; pExchangeInfo->current += 1; continue; } SSDataBlock* pRes = pExchangeInfo->pResult; SRetrieveTableRsp* pTableRsp = pDataInfo->pRsp; int32_t code = setSDataBlockFromFetchRsp(pExchangeInfo->pResult, pLoadInfo, pTableRsp->numOfRows, pTableRsp->data, pTableRsp->compLen, pOperator->numOfOutput, startTs, &pDataInfo->totalRows, NULL); if (pRsp->completed == 1) { qDebug("%s fetch msg rsp from vgId:%d, taskId:0x%" PRIx64 " numOfRows:%d, rowsOfSource:%" PRIu64 ", totalRows:%" PRIu64 ", totalBytes:%" PRIu64 " try next %d/%" PRIzu, GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, pRes->info.rows, pDataInfo->totalRows, pLoadInfo->totalRows, pLoadInfo->totalSize, pExchangeInfo->current + 1, totalSources); pDataInfo->status = EX_SOURCE_DATA_EXHAUSTED; pExchangeInfo->current += 1; } else { qDebug("%s fetch msg rsp from vgId:%d, taskId:0x%" PRIx64 " numOfRows:%d, totalRows:%" PRIu64 ", totalBytes:%" PRIu64, GET_TASKID(pTaskInfo), pSource->addr.nodeId, pSource->taskId, pRes->info.rows, pLoadInfo->totalRows, pLoadInfo->totalSize); } return pExchangeInfo->pResult; } } static int32_t prepareLoadRemoteData(SOperatorInfo* pOperator) { if (OPTR_IS_OPENED(pOperator)) { return TSDB_CODE_SUCCESS; } SExchangeInfo* pExchangeInfo = pOperator->info; if (pExchangeInfo->seqLoadData) { // do nothing for sequentially load data } else { int32_t code = prepareConcurrentlyLoad(pOperator); if (code != TSDB_CODE_SUCCESS) { return code; } } OPTR_SET_OPENED(pOperator); return TSDB_CODE_SUCCESS; } static SSDataBlock* doLoadRemoteData(SOperatorInfo* pOperator, bool* newgroup) { SExchangeInfo* pExchangeInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; pTaskInfo->code = pOperator->_openFn(pOperator); if (pTaskInfo->code != TSDB_CODE_SUCCESS) { return NULL; } size_t totalSources = taosArrayGetSize(pExchangeInfo->pSources); SLoadRemoteDataInfo* pLoadInfo = &pExchangeInfo->loadInfo; if (pOperator->status == OP_EXEC_DONE) { qDebug("%s all %" PRIzu " source(s) are exhausted, total rows:%" PRIu64 " bytes:%" PRIu64 ", elapsed:%.2f ms", GET_TASKID(pTaskInfo), totalSources, pLoadInfo->totalRows, pLoadInfo->totalSize, pLoadInfo->totalElapsed / 1000.0); return NULL; } *newgroup = false; if (pExchangeInfo->seqLoadData) { return seqLoadRemoteData(pOperator); } else { return concurrentlyLoadRemoteData(pOperator); } #if 0 _error: taosMemoryFreeClear(pMsg); taosMemoryFreeClear(pMsgSendInfo); terrno = pTaskInfo->code; return NULL; #endif } static int32_t initDataSource(int32_t numOfSources, SExchangeInfo* pInfo) { pInfo->pSourceDataInfo = taosArrayInit(numOfSources, sizeof(SSourceDataInfo)); if (pInfo->pSourceDataInfo == NULL) { return TSDB_CODE_OUT_OF_MEMORY; } for (int32_t i = 0; i < numOfSources; ++i) { SSourceDataInfo dataInfo = {0}; dataInfo.status = EX_SOURCE_DATA_NOT_READY; dataInfo.pEx = pInfo; dataInfo.index = i; void* ret = taosArrayPush(pInfo->pSourceDataInfo, &dataInfo); if (ret == NULL) { taosArrayDestroy(pInfo->pSourceDataInfo); return TSDB_CODE_OUT_OF_MEMORY; } } return TSDB_CODE_SUCCESS; } SOperatorInfo* createExchangeOperatorInfo(const SNodeList* pSources, SSDataBlock* pBlock, SExecTaskInfo* pTaskInfo) { SExchangeInfo* pInfo = taosMemoryCalloc(1, sizeof(SExchangeInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); terrno = TSDB_CODE_QRY_OUT_OF_MEMORY; return NULL; } size_t numOfSources = LIST_LENGTH(pSources); pInfo->pSources = taosArrayInit(numOfSources, sizeof(SDownstreamSourceNode)); pInfo->pSourceDataInfo = taosArrayInit(numOfSources, sizeof(SSourceDataInfo)); if (pInfo->pSourceDataInfo == NULL || pInfo->pSources == NULL) { goto _error; } for (int32_t i = 0; i < numOfSources; ++i) { SNodeListNode* pNode = nodesListGetNode((SNodeList*)pSources, i); taosArrayPush(pInfo->pSources, pNode); } int32_t code = initDataSource(numOfSources, pInfo); if (code != TSDB_CODE_SUCCESS) { goto _error; } size_t size = pBlock->info.numOfCols; pInfo->pResult = pBlock; pInfo->seqLoadData = true; tsem_init(&pInfo->ready, 0, 0); pOperator->name = "ExchangeOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_EXCHANGE; pOperator->blockingOptr = false; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->numOfOutput = size; pOperator->pTaskInfo = pTaskInfo; pOperator->_openFn = prepareLoadRemoteData; // assign a dummy function. pOperator->getNextFn = doLoadRemoteData; pOperator->closeFn = destroyExchangeOperatorInfo; #if 1 { // todo refactor SRpcInit rpcInit; memset(&rpcInit, 0, sizeof(rpcInit)); rpcInit.localPort = 0; rpcInit.label = "EX"; rpcInit.numOfThreads = 1; rpcInit.cfp = qProcessFetchRsp; rpcInit.sessions = tsMaxConnections; rpcInit.connType = TAOS_CONN_CLIENT; rpcInit.user = (char*)"root"; rpcInit.idleTime = tsShellActivityTimer * 1000; rpcInit.ckey = "key"; rpcInit.spi = 1; rpcInit.secret = (char*)"dcc5bed04851fec854c035b2e40263b6"; pInfo->pTransporter = rpcOpen(&rpcInit); if (pInfo->pTransporter == NULL) { return NULL; // todo } } #endif return pOperator; _error: if (pInfo != NULL) { destroyExchangeOperatorInfo(pInfo, numOfSources); } taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); pTaskInfo->code = TSDB_CODE_OUT_OF_MEMORY; return NULL; } SSDataBlock* createResultDataBlock(const SArray* pExprInfo) { SSDataBlock* pResBlock = taosMemoryCalloc(1, sizeof(SSDataBlock)); if (pResBlock == NULL) { return NULL; } size_t numOfCols = taosArrayGetSize(pExprInfo); pResBlock->pDataBlock = taosArrayInit(numOfCols, sizeof(SColumnInfoData)); SArray* pResult = pResBlock->pDataBlock; for (int32_t i = 0; i < numOfCols; ++i) { SColumnInfoData colInfoData = {0}; SExprInfo* p = taosArrayGetP(pExprInfo, i); SResSchema* pSchema = &p->base.resSchema; colInfoData.info.type = pSchema->type; colInfoData.info.colId = pSchema->colId; colInfoData.info.bytes = pSchema->bytes; colInfoData.info.scale = pSchema->scale; colInfoData.info.precision = pSchema->precision; taosArrayPush(pResult, &colInfoData); } return pResBlock; } static int32_t doInitAggInfoSup(SAggSupporter* pAggSup, SqlFunctionCtx* pCtx, int32_t numOfOutput, const char* pKey); static void cleanupAggSup(SAggSupporter* pAggSup); static void destroySortedMergeOperatorInfo(void* param, int32_t numOfOutput) { SSortedMergeOperatorInfo* pInfo = (SSortedMergeOperatorInfo*)param; taosArrayDestroy(pInfo->pSortInfo); taosArrayDestroy(pInfo->groupInfo); if (pInfo->pSortHandle != NULL) { tsortDestroySortHandle(pInfo->pSortHandle); } blockDataDestroy(pInfo->binfo.pRes); cleanupAggSup(&pInfo->aggSup); } static void destroySlimitOperatorInfo(void* param, int32_t numOfOutput) { SSLimitOperatorInfo* pInfo = (SSLimitOperatorInfo*)param; taosArrayDestroy(pInfo->orderColumnList); pInfo->pRes = blockDataDestroy(pInfo->pRes); taosMemoryFreeClear(pInfo->prevRow); } static void assignExprInfo(SExprInfo* dst, const SExprInfo* src) { assert(dst != NULL && src != NULL); *dst = *src; dst->pExpr = exprdup(src->pExpr); dst->base.pParam = taosMemoryCalloc(src->base.numOfParams, sizeof(SColumn)); memcpy(dst->base.pParam, src->base.pParam, sizeof(SColumn) * src->base.numOfParams); // memset(dst->base.param, 0, sizeof(SVariant) * tListLen(dst->base.param)); // for (int32_t j = 0; j < src->base.numOfParams; ++j) { // taosVariantAssign(&dst->base.param[j], &src->base.param[j]); // } } static SExprInfo* exprArrayDup(SArray* pExprList) { size_t numOfOutput = taosArrayGetSize(pExprList); SExprInfo* p = taosMemoryCalloc(numOfOutput, sizeof(SExprInfo)); for (int32_t i = 0; i < numOfOutput; ++i) { SExprInfo* pExpr = taosArrayGetP(pExprList, i); assignExprInfo(&p[i], pExpr); } return p; } // TODO merge aggregate super table static void appendOneRowToDataBlock(SSDataBlock* pBlock, STupleHandle* pTupleHandle) { for (int32_t i = 0; i < pBlock->info.numOfCols; ++i) { SColumnInfoData* pColInfo = taosArrayGet(pBlock->pDataBlock, i); bool isNull = tsortIsNullVal(pTupleHandle, i); if (isNull) { colDataAppend(pColInfo, pBlock->info.rows, NULL, true); } else { char* pData = tsortGetValue(pTupleHandle, i); colDataAppend(pColInfo, pBlock->info.rows, pData, false); } } pBlock->info.rows += 1; } SSDataBlock* getSortedBlockData(SSortHandle* pHandle, SSDataBlock* pDataBlock, int32_t capacity) { blockDataCleanup(pDataBlock); while (1) { STupleHandle* pTupleHandle = tsortNextTuple(pHandle); if (pTupleHandle == NULL) { break; } appendOneRowToDataBlock(pDataBlock, pTupleHandle); if (pDataBlock->info.rows >= capacity) { return pDataBlock; } } return (pDataBlock->info.rows > 0) ? pDataBlock : NULL; } SSDataBlock* loadNextDataBlock(void* param) { SOperatorInfo* pOperator = (SOperatorInfo*)param; bool newgroup = false; return pOperator->getNextFn(pOperator, &newgroup); } static bool needToMerge(SSDataBlock* pBlock, SArray* groupInfo, char** buf, int32_t rowIndex) { size_t size = taosArrayGetSize(groupInfo); if (size == 0) { return true; } for (int32_t i = 0; i < size; ++i) { int32_t* index = taosArrayGet(groupInfo, i); SColumnInfoData* pColInfo = taosArrayGet(pBlock->pDataBlock, *index); bool isNull = colDataIsNull(pColInfo, rowIndex, pBlock->info.rows, NULL); if ((isNull && buf[i] != NULL) || (!isNull && buf[i] == NULL)) { return false; } char* pCell = colDataGetData(pColInfo, rowIndex); if (IS_VAR_DATA_TYPE(pColInfo->info.type)) { if (varDataLen(pCell) != varDataLen(buf[i])) { return false; } else { if (memcmp(varDataVal(pCell), varDataVal(buf[i]), varDataLen(pCell)) != 0) { return false; } } } else { if (memcmp(pCell, buf[i], pColInfo->info.bytes) != 0) { return false; } } } return 0; } static void doMergeResultImpl(SSortedMergeOperatorInfo* pInfo, SqlFunctionCtx* pCtx, int32_t numOfExpr, int32_t rowIndex) { for (int32_t j = 0; j < numOfExpr; ++j) { // TODO set row index pCtx[j].startRow = rowIndex; } for (int32_t j = 0; j < numOfExpr; ++j) { int32_t functionId = pCtx[j].functionId; // pCtx[j].fpSet->addInput(&pCtx[j]); // if (functionId < 0) { // SUdfInfo* pUdfInfo = taosArrayGet(pInfo->udfInfo, -1 * functionId - 1); // doInvokeUdf(pUdfInfo, &pCtx[j], 0, TSDB_UDF_FUNC_MERGE); // } else { // assert(!TSDB_FUNC_IS_SCALAR(functionId)); // aAggs[functionId].mergeFunc(&pCtx[j]); // } } } static void doFinalizeResultImpl(SqlFunctionCtx* pCtx, int32_t numOfExpr) { for (int32_t j = 0; j < numOfExpr; ++j) { int32_t functionId = pCtx[j].functionId; // if (functionId == FUNC_TAG_DUMMY || functionId == FUNC_TS_DUMMY) { // continue; // } // if (functionId < 0) { // SUdfInfo* pUdfInfo = taosArrayGet(pInfo->udfInfo, -1 * functionId - 1); // doInvokeUdf(pUdfInfo, &pCtx[j], 0, TSDB_UDF_FUNC_FINALIZE); // } else { pCtx[j].fpSet.finalize(&pCtx[j]); } } static bool saveCurrentTuple(char** rowColData, SArray* pColumnList, SSDataBlock* pBlock, int32_t rowIndex) { int32_t size = (int32_t)taosArrayGetSize(pColumnList); for (int32_t i = 0; i < size; ++i) { int32_t* index = taosArrayGet(pColumnList, i); SColumnInfoData* pColInfo = taosArrayGet(pBlock->pDataBlock, *index); char* data = colDataGetData(pColInfo, rowIndex); memcpy(rowColData[i], data, colDataGetLength(pColInfo, rowIndex)); } return true; } static void doMergeImpl(SOperatorInfo* pOperator, int32_t numOfExpr, SSDataBlock* pBlock) { SSortedMergeOperatorInfo* pInfo = pOperator->info; SqlFunctionCtx* pCtx = pInfo->binfo.pCtx; for (int32_t i = 0; i < pBlock->info.numOfCols; ++i) { pCtx[i].size = 1; } for (int32_t i = 0; i < pBlock->info.rows; ++i) { if (!pInfo->hasGroupVal) { ASSERT(i == 0); doMergeResultImpl(pInfo, pCtx, numOfExpr, i); pInfo->hasGroupVal = saveCurrentTuple(pInfo->groupVal, pInfo->groupInfo, pBlock, i); } else { if (needToMerge(pBlock, pInfo->groupInfo, pInfo->groupVal, i)) { doMergeResultImpl(pInfo, pCtx, numOfExpr, i); } else { doFinalizeResultImpl(pCtx, numOfExpr); int32_t numOfRows = getNumOfResult(pInfo->binfo.pCtx, pOperator->numOfOutput, NULL); // setTagValueForMultipleRows(pCtx, pOperator->numOfOutput, numOfRows); // TODO check for available buffer; // next group info data pInfo->binfo.pRes->info.rows += numOfRows; for (int32_t j = 0; j < numOfExpr; ++j) { if (pCtx[j].functionId < 0) { continue; } pCtx[j].fpSet.process(&pCtx[j]); } doMergeResultImpl(pInfo, pCtx, numOfExpr, i); pInfo->hasGroupVal = saveCurrentTuple(pInfo->groupVal, pInfo->groupInfo, pBlock, i); } } } } static SSDataBlock* doMerge(SOperatorInfo* pOperator) { SSortedMergeOperatorInfo* pInfo = pOperator->info; SSortHandle* pHandle = pInfo->pSortHandle; SSDataBlock* pDataBlock = createOneDataBlock(pInfo->binfo.pRes); blockDataEnsureCapacity(pDataBlock, pInfo->binfo.capacity); while (1) { blockDataCleanup(pDataBlock); while (1) { STupleHandle* pTupleHandle = tsortNextTuple(pHandle); if (pTupleHandle == NULL) { break; } // build datablock for merge for one group appendOneRowToDataBlock(pDataBlock, pTupleHandle); if (pDataBlock->info.rows >= pInfo->binfo.capacity) { break; } } if (pDataBlock->info.rows == 0) { break; } setInputDataBlock(pOperator, pInfo->binfo.pCtx, pDataBlock, TSDB_ORDER_ASC); // updateOutputBuf(&pInfo->binfo, &pAggInfo->bufCapacity, pBlock->info.rows * pAggInfo->resultRowFactor, // pOperator->pRuntimeEnv, true); doMergeImpl(pOperator, pOperator->numOfOutput, pDataBlock); // flush to tuple store, and after all data have been handled, return to upstream node or sink node } doFinalizeResultImpl(pInfo->binfo.pCtx, pOperator->numOfOutput); int32_t numOfRows = getNumOfResult(pInfo->binfo.pCtx, pOperator->numOfOutput, NULL); // setTagValueForMultipleRows(pCtx, pOperator->numOfOutput, numOfRows); // TODO check for available buffer; // next group info data pInfo->binfo.pRes->info.rows += numOfRows; return (pInfo->binfo.pRes->info.rows > 0) ? pInfo->binfo.pRes : NULL; } static SSDataBlock* doSortedMerge(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SSortedMergeOperatorInfo* pInfo = pOperator->info; if (pOperator->status == OP_RES_TO_RETURN) { return getSortedBlockData(pInfo->pSortHandle, pInfo->binfo.pRes, pInfo->binfo.capacity); } int32_t numOfBufPage = pInfo->sortBufSize / pInfo->bufPageSize; pInfo->pSortHandle = tsortCreateSortHandle(pInfo->pSortInfo, SORT_MULTISOURCE_MERGE, pInfo->bufPageSize, numOfBufPage, pInfo->binfo.pRes, "GET_TASKID(pTaskInfo)"); tsortSetFetchRawDataFp(pInfo->pSortHandle, loadNextDataBlock); for (int32_t i = 0; i < pOperator->numOfDownstream; ++i) { SGenericSource* ps = taosMemoryCalloc(1, sizeof(SGenericSource)); ps->param = pOperator->pDownstream[i]; tsortAddSource(pInfo->pSortHandle, ps); } int32_t code = tsortOpen(pInfo->pSortHandle); if (code != TSDB_CODE_SUCCESS) { longjmp(pTaskInfo->env, terrno); } pOperator->status = OP_RES_TO_RETURN; return doMerge(pOperator); } static int32_t initGroupCol(SExprInfo* pExprInfo, int32_t numOfCols, SArray* pGroupInfo, SSortedMergeOperatorInfo* pInfo) { if (pGroupInfo == NULL || taosArrayGetSize(pGroupInfo) == 0) { return 0; } int32_t len = 0; SArray* plist = taosArrayInit(3, sizeof(SColumn)); pInfo->groupInfo = taosArrayInit(3, sizeof(int32_t)); if (plist == NULL || pInfo->groupInfo == NULL) { return TSDB_CODE_OUT_OF_MEMORY; } size_t numOfGroupCol = taosArrayGetSize(pInfo->groupInfo); for (int32_t i = 0; i < numOfGroupCol; ++i) { SColumn* pCol = taosArrayGet(pGroupInfo, i); for (int32_t j = 0; j < numOfCols; ++j) { SExprInfo* pe = &pExprInfo[j]; if (pe->base.resSchema.colId == pCol->colId) { taosArrayPush(plist, pCol); taosArrayPush(pInfo->groupInfo, &j); len += pCol->bytes; break; } } } ASSERT(taosArrayGetSize(pGroupInfo) == taosArrayGetSize(plist)); pInfo->groupVal = taosMemoryCalloc(1, (POINTER_BYTES * numOfGroupCol + len)); if (pInfo->groupVal == NULL) { taosArrayDestroy(plist); return TSDB_CODE_OUT_OF_MEMORY; } int32_t offset = 0; char* start = (char*)(pInfo->groupVal + (POINTER_BYTES * numOfGroupCol)); for (int32_t i = 0; i < numOfGroupCol; ++i) { pInfo->groupVal[i] = start + offset; SColumn* pCol = taosArrayGet(plist, i); offset += pCol->bytes; } taosArrayDestroy(plist); return TSDB_CODE_SUCCESS; } SOperatorInfo* createSortedMergeOperatorInfo(SOperatorInfo** downstream, int32_t numOfDownstream, SExprInfo* pExprInfo, int32_t num, SArray* pSortInfo, SArray* pGroupInfo, SExecTaskInfo* pTaskInfo) { SSortedMergeOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SSortedMergeOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->binfo.pCtx = createSqlFunctionCtx_rv(pExprInfo, num, &pInfo->binfo.rowCellInfoOffset); initResultRowInfo(&pInfo->binfo.resultRowInfo, (int32_t)1); if (pInfo->binfo.pCtx == NULL || pInfo->binfo.pRes == NULL) { goto _error; } int32_t code = doInitAggInfoSup(&pInfo->aggSup, pInfo->binfo.pCtx, num, pTaskInfo->id.str); if (code != TSDB_CODE_SUCCESS) { goto _error; } setFunctionResultOutput(&pInfo->binfo, &pInfo->aggSup, MAIN_SCAN, pTaskInfo); code = initGroupCol(pExprInfo, num, pGroupInfo, pInfo); if (code != TSDB_CODE_SUCCESS) { goto _error; } // pInfo->resultRowFactor = (int32_t)(getRowNumForMultioutput(pRuntimeEnv->pQueryAttr, // pRuntimeEnv->pQueryAttr->topBotQuery, false)); pInfo->sortBufSize = 1024 * 16; // 1MB pInfo->bufPageSize = 1024; pInfo->pSortInfo = pSortInfo; pInfo->binfo.capacity = blockDataGetCapacityInRow(pInfo->binfo.pRes, pInfo->bufPageSize); pOperator->name = "SortedMerge"; // pOperator->operatorType = OP_SortedMerge; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->numOfOutput = num; pOperator->pExpr = pExprInfo; pOperator->pTaskInfo = pTaskInfo; pOperator->getNextFn = doSortedMerge; pOperator->closeFn = destroySortedMergeOperatorInfo; code = appendDownstream(pOperator, downstream, numOfDownstream); if (code != TSDB_CODE_SUCCESS) { goto _error; } return pOperator; _error: if (pInfo != NULL) { destroySortedMergeOperatorInfo(pInfo, num); } taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); terrno = TSDB_CODE_QRY_OUT_OF_MEMORY; return NULL; } static SSDataBlock* doSort(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SSortOperatorInfo* pInfo = pOperator->info; if (pOperator->status == OP_RES_TO_RETURN) { return getSortedBlockData(pInfo->pSortHandle, pInfo->pDataBlock, pInfo->numOfRowsInRes); } int32_t numOfBufPage = pInfo->sortBufSize / pInfo->bufPageSize; pInfo->pSortHandle = tsortCreateSortHandle(pInfo->pSortInfo, SORT_SINGLESOURCE_SORT, pInfo->bufPageSize, numOfBufPage, pInfo->pDataBlock, pTaskInfo->id.str); tsortSetFetchRawDataFp(pInfo->pSortHandle, loadNextDataBlock); SGenericSource* ps = taosMemoryCalloc(1, sizeof(SGenericSource)); ps->param = pOperator->pDownstream[0]; tsortAddSource(pInfo->pSortHandle, ps); int32_t code = tsortOpen(pInfo->pSortHandle); if (code != TSDB_CODE_SUCCESS) { longjmp(pTaskInfo->env, terrno); } pOperator->status = OP_RES_TO_RETURN; return getSortedBlockData(pInfo->pSortHandle, pInfo->pDataBlock, pInfo->numOfRowsInRes); } SOperatorInfo* createSortOperatorInfo(SOperatorInfo* downstream, SSDataBlock* pResBlock, SArray* pSortInfo, SExecTaskInfo* pTaskInfo) { SSortOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SSortOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->sortBufSize = 1024 * 16; // TODO dynamic set the available sort buffer pInfo->bufPageSize = 1024; pInfo->numOfRowsInRes = 1024; pInfo->pDataBlock = pResBlock; pInfo->pSortInfo = pSortInfo; pOperator->name = "SortOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_SORT; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->pTaskInfo = pTaskInfo; pOperator->getNextFn = doSort; pOperator->closeFn = destroyOrderOperatorInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; _error: pTaskInfo->code = TSDB_CODE_OUT_OF_MEMORY; taosMemoryFree(pInfo); taosMemoryFree(pOperator); return NULL; } static int32_t getTableScanOrder(STableScanInfo* pTableScanInfo) { return pTableScanInfo->order; } // this is a blocking operator static int32_t doOpenAggregateOptr(SOperatorInfo* pOperator) { if (OPTR_IS_OPENED(pOperator)) { return TSDB_CODE_SUCCESS; } SAggOperatorInfo* pAggInfo = pOperator->info; SOptrBasicInfo* pInfo = &pAggInfo->binfo; int32_t order = TSDB_ORDER_ASC; SOperatorInfo* downstream = pOperator->pDownstream[0]; bool newgroup = true; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, &newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // if (pAggInfo->current != NULL) { // setTagValue(pOperator, pAggInfo->current->pTable, pInfo->pCtx, pOperator->numOfOutput); // } // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->pCtx, pBlock, order); doAggregateImpl(pOperator, 0, pInfo->pCtx); } finalizeQueryResult(pInfo->pCtx, pOperator->numOfOutput); OPTR_SET_OPENED(pOperator); return TSDB_CODE_SUCCESS; } static SSDataBlock* getAggregateResult(SOperatorInfo* pOperator, bool* newgroup) { SAggOperatorInfo* pAggInfo = pOperator->info; SOptrBasicInfo* pInfo = &pAggInfo->binfo; if (pOperator->status == OP_EXEC_DONE) { return NULL; } SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; pTaskInfo->code = pOperator->_openFn(pOperator); if (pTaskInfo->code != TSDB_CODE_SUCCESS) { return NULL; } getNumOfResult(pInfo->pCtx, pOperator->numOfOutput, pInfo->pRes); doSetOperatorCompleted(pOperator); return (blockDataGetNumOfRows(pInfo->pRes) != 0) ? pInfo->pRes : NULL; } static void aggEncodeResultRow(SOperatorInfo* pOperator, char** result, int32_t* length) { SAggOperatorInfo* pAggInfo = pOperator->info; SAggSupporter* pSup = &pAggInfo->aggSup; int32_t size = taosHashGetSize(pSup->pResultRowHashTable); size_t keyLen = POINTER_BYTES; // estimate the key length int32_t totalSize = sizeof(int32_t) + size * (sizeof(int32_t) + keyLen + sizeof(int32_t) + pSup->resultRowSize); *result = taosMemoryCalloc(1, totalSize); if (*result == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return; } *(int32_t*)(*result) = size; int32_t offset = sizeof(int32_t); void* pIter = taosHashIterate(pSup->pResultRowHashTable, NULL); while (pIter) { void* key = taosHashGetKey(pIter, &keyLen); SResultRow** p1 = (SResultRow**)pIter; // recalculate the result size int32_t realTotalSize = offset + sizeof(int32_t) + keyLen + sizeof(int32_t) + pSup->resultRowSize; if (realTotalSize > totalSize) { char* tmp = taosMemoryRealloc(*result, realTotalSize); if (tmp == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; taosMemoryFree(*result); *result = NULL; return; } else { *result = tmp; } } // save key *(int32_t*)(*result + offset) = keyLen; offset += sizeof(int32_t); memcpy(*result + offset, key, keyLen); offset += keyLen; // save value *(int32_t*)(*result + offset) = pSup->resultRowSize; offset += sizeof(int32_t); memcpy(*result + offset, *p1, pSup->resultRowSize); offset += pSup->resultRowSize; pIter = taosHashIterate(pSup->pResultRowHashTable, pIter); } if (length) { *length = offset; } return; } static bool aggDecodeResultRow(SOperatorInfo* pOperator, char* result, int32_t length) { if (!result || length <= 0) { return false; } SAggOperatorInfo* pAggInfo = pOperator->info; SAggSupporter* pSup = &pAggInfo->aggSup; SOptrBasicInfo* pInfo = &pAggInfo->binfo; // int32_t size = taosHashGetSize(pSup->pResultRowHashTable); int32_t count = *(int32_t*)(result); int32_t offset = sizeof(int32_t); while (count-- > 0 && length > offset) { int32_t keyLen = *(int32_t*)(result + offset); offset += sizeof(int32_t); uint64_t tableGroupId = *(uint64_t*)(result + offset); SResultRow* resultRow = getNewResultRow_rv(pSup->pResultBuf, tableGroupId, pSup->resultRowSize); if (!resultRow) { terrno = TSDB_CODE_TSC_INVALID_INPUT; return false; } // add a new result set for a new group taosHashPut(pSup->pResultRowHashTable, result + offset, keyLen, &resultRow, POINTER_BYTES); offset += keyLen; int32_t valueLen = *(int32_t*)(result + offset); if (valueLen != pSup->resultRowSize) { terrno = TSDB_CODE_TSC_INVALID_INPUT; return false; } offset += sizeof(int32_t); int32_t pageId = resultRow->pageId; int32_t pOffset = resultRow->offset; memcpy(resultRow, result + offset, valueLen); resultRow->pageId = pageId; resultRow->offset = pOffset; offset += valueLen; initResultRow(resultRow); pInfo->resultRowInfo.pPosition[pInfo->resultRowInfo.size++] = (SResultRowPosition){.pageId = resultRow->pageId, .offset = resultRow->offset}; } if (offset != length) { terrno = TSDB_CODE_TSC_INVALID_INPUT; return false; } return true; } static SSDataBlock* doMultiTableAggregate(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SAggOperatorInfo* pAggInfo = pOperator->info; SOptrBasicInfo* pInfo = &pAggInfo->binfo; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; if (pOperator->status == OP_RES_TO_RETURN) { toSDatablock(&pAggInfo->groupResInfo, pAggInfo->pResultBuf, pInfo->pRes, pAggInfo->binfo.capacity, pAggInfo->binfo.rowCellInfoOffset); if (pInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pAggInfo->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } return pInfo->pRes; } // table scan order int32_t order = TSDB_ORDER_ASC; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // setTagValue(pOperator, pRuntimeEnv->current->pTable, pInfo->pCtx, pOperator->numOfOutput); // if (downstream->operatorType == OP_TableScan) { // STableScanInfo* pScanInfo = downstream->info; // order = getTableScanOrder(pScanInfo); // } // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->pCtx, pBlock, order); TSKEY key = 0; if (order == TSDB_ORDER_ASC) { key = pBlock->info.window.ekey; TSKEY_MAX_ADD(key, 1); } else { key = pBlock->info.window.skey; TSKEY_MIN_SUB(key, -1); } setExecutionContext(pOperator->numOfOutput, pAggInfo->current->groupIndex, key, pTaskInfo, pAggInfo->current, pAggInfo); doAggregateImpl(pOperator, 0, pInfo->pCtx); } pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pInfo->resultRowInfo); updateNumOfRowsInResultRows(pInfo->pCtx, pOperator->numOfOutput, &pInfo->resultRowInfo, pInfo->rowCellInfoOffset); initGroupResInfo(&pAggInfo->groupResInfo, &pInfo->resultRowInfo); toSDatablock(&pAggInfo->groupResInfo, pAggInfo->pResultBuf, pInfo->pRes, pAggInfo->binfo.capacity, pAggInfo->binfo.rowCellInfoOffset); if (pInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pAggInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pInfo->pRes; } static SSDataBlock* doProjectOperation(SOperatorInfo* pOperator, bool* newgroup) { SProjectOperatorInfo* pProjectInfo = pOperator->info; SOptrBasicInfo* pInfo = &pProjectInfo->binfo; SSDataBlock* pRes = pInfo->pRes; blockDataCleanup(pRes); #if 0 if (pProjectInfo->existDataBlock) { // TODO refactor SSDataBlock* pBlock = pProjectInfo->existDataBlock; pProjectInfo->existDataBlock = NULL; *newgroup = true; // todo dynamic set tags // if (pTableQueryInfo != NULL) { // setTagValue(pOperator, pTableQueryInfo->pTable, pInfo->pCtx, pOperator->numOfOutput); // } // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->pCtx, pBlock, TSDB_ORDER_ASC); blockDataEnsureCapacity(pInfo->pRes, pBlock->info.rows); projectApplyFunctions(pOperator->pExpr, pInfo->pRes, pBlock, pInfo->pCtx, pOperator->numOfOutput); if (pRes->info.rows >= pProjectInfo->binfo.capacity * 0.8) { copyTsColoum(pRes, pInfo->pCtx, pOperator->numOfOutput); resetResultRowEntryResult(pInfo->pCtx, pOperator->numOfOutput); return pRes; } } #endif SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { bool prevVal = *newgroup; // The downstream exec may change the value of the newgroup, so use a local variable instead. publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { assert(*newgroup == false); *newgroup = prevVal; setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); break; } // Return result of the previous group in the firstly. if (*newgroup) { if (pRes->info.rows > 0) { pProjectInfo->existDataBlock = pBlock; break; } else { // init output buffer for a new group data initCtxOutputBuffer(pInfo->pCtx, pOperator->numOfOutput); } } // todo dynamic set tags // STableQueryInfo* pTableQueryInfo = pRuntimeEnv->current; // if (pTableQueryInfo != NULL) { // setTagValue(pOperator, pTableQueryInfo->pTable, pInfo->pCtx, pOperator->numOfOutput); // } // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->pCtx, pBlock, TSDB_ORDER_ASC); blockDataEnsureCapacity(pInfo->pRes, pInfo->pRes->info.rows + pBlock->info.rows); projectApplyFunctions(pOperator->pExpr, pInfo->pRes, pBlock, pInfo->pCtx, pOperator->numOfOutput, pProjectInfo->pPseudoColInfo); // todo extract method if (pProjectInfo->curOffset < pInfo->pRes->info.rows && pProjectInfo->curOffset > 0) { blockDataTrimFirstNRows(pInfo->pRes, pProjectInfo->curOffset); pProjectInfo->curOffset = 0; } else if (pProjectInfo->curOffset >= pInfo->pRes->info.rows) { pProjectInfo->curOffset -= pInfo->pRes->info.rows; blockDataCleanup(pInfo->pRes); continue; } if (pRes->info.rows >= pOperator->resultInfo.threshold) { break; } } if (pProjectInfo->limit.limit > 0 && pProjectInfo->curOutput + pInfo->pRes->info.rows >= pProjectInfo->limit.limit) { pInfo->pRes->info.rows = (int32_t)(pProjectInfo->limit.limit - pProjectInfo->curOutput); } pProjectInfo->curOutput += pInfo->pRes->info.rows; // copyTsColoum(pRes, pInfo->pCtx, pOperator->numOfOutput); return (pInfo->pRes->info.rows > 0) ? pInfo->pRes : NULL; } static int32_t doOpenIntervalAgg(SOperatorInfo* pOperator) { if (OPTR_IS_OPENED(pOperator)) { return TSDB_CODE_SUCCESS; } STableIntervalOperatorInfo* pInfo = pOperator->info; int32_t order = TSDB_ORDER_ASC; // STimeWindow win = {0}; bool newgroup = false; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, &newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // setTagValue(pOperator, pRuntimeEnv->current->pTable, pInfo->pCtx, pOperator->numOfOutput); // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->binfo.pCtx, pBlock, order); hashIntervalAgg(pOperator, &pInfo->binfo.resultRowInfo, pBlock, 0); } closeAllResultRows(&pInfo->binfo.resultRowInfo); finalizeMultiTupleQueryResult(pInfo->binfo.pCtx, pOperator->numOfOutput, pInfo->aggSup.pResultBuf, &pInfo->binfo.resultRowInfo, pInfo->binfo.rowCellInfoOffset); initGroupResInfo(&pInfo->groupResInfo, &pInfo->binfo.resultRowInfo); OPTR_SET_OPENED(pOperator); return TSDB_CODE_SUCCESS; } static SSDataBlock* doBuildIntervalResult(SOperatorInfo* pOperator, bool* newgroup) { STableIntervalOperatorInfo* pInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; if (pOperator->status == OP_EXEC_DONE) { return NULL; } if (pInfo->execModel == OPTR_EXEC_MODEL_STREAM) { return pOperator->getStreamResFn(pOperator, newgroup); } pTaskInfo->code = pOperator->_openFn(pOperator); if (pTaskInfo->code != TSDB_CODE_SUCCESS) { return NULL; } blockDataEnsureCapacity(pInfo->binfo.pRes, pInfo->binfo.capacity); toSDatablock(&pInfo->groupResInfo, pInfo->aggSup.pResultBuf, pInfo->binfo.pRes, pInfo->binfo.capacity, pInfo->binfo.rowCellInfoOffset); if (pInfo->binfo.pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pInfo->binfo.pRes->info.rows == 0 ? NULL : pInfo->binfo.pRes; } static SSDataBlock* doStreamIntervalAgg(SOperatorInfo *pOperator, bool* newgroup) { STableIntervalOperatorInfo* pInfo = pOperator->info; int32_t order = TSDB_ORDER_ASC; if (pOperator->status == OP_EXEC_DONE) { return NULL; } if (pOperator->status == OP_RES_TO_RETURN) { toSDatablock(&pInfo->groupResInfo, pInfo->aggSup.pResultBuf, pInfo->binfo.pRes, pInfo->binfo.capacity, pInfo->binfo.rowCellInfoOffset); 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}; *newgroup = false; SOperatorInfo* downstream = pOperator->pDownstream[0]; SArray* pUpdated = NULL; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, newgroup); 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->numOfOutput); // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pInfo->binfo.pCtx, pBlock, order); pUpdated = hashIntervalAgg(pOperator, &pInfo->binfo.resultRowInfo, pBlock, 0); } finalizeUpdatedResult(pInfo->binfo.pCtx, pOperator->numOfOutput, pInfo->aggSup.pResultBuf, pUpdated, pInfo->binfo.rowCellInfoOffset); initMultiResInfoFromArrayList(&pInfo->groupResInfo, pUpdated); blockDataEnsureCapacity(pInfo->binfo.pRes, pInfo->binfo.capacity); toSDatablock(&pInfo->groupResInfo, pInfo->aggSup.pResultBuf, pInfo->binfo.pRes, pInfo->binfo.capacity, pInfo->binfo.rowCellInfoOffset); 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 SSDataBlock* doAllIntervalAgg(SOperatorInfo *pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } STableIntervalOperatorInfo* pIntervalInfo = pOperator->info; STaskRuntimeEnv* pRuntimeEnv = pOperator->pRuntimeEnv; if (pOperator->status == OP_RES_TO_RETURN) { // toSDatablock(&pRuntimeEnv->groupResInfo, pRuntimeEnv, pIntervalInfo->pRes); if (pIntervalInfo->binfo.pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pRuntimeEnv->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pIntervalInfo->binfo.pRes; } STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; int32_t order = pQueryAttr->order.order; STimeWindow win = pQueryAttr->window; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // setTagValue(pOperator, pRuntimeEnv->current->pTable, pIntervalInfo->pCtx, pOperator->numOfOutput); // the pDataBlock are always the same one, no need to call this again setInputDataBlock(pOperator, pIntervalInfo->binfo.pCtx, pBlock, pQueryAttr->order.order); hashAllIntervalAgg(pOperator, &pIntervalInfo->binfo.resultRowInfo, pBlock, 0); } // restore the value pQueryAttr->order.order = order; pQueryAttr->window = win; pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pIntervalInfo->binfo.resultRowInfo); setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); finalizeQueryResult(pIntervalInfo->binfo.pCtx, pOperator->numOfOutput); initGroupResInfo(&pRuntimeEnv->groupResInfo, &pIntervalInfo->binfo.resultRowInfo); // toSDatablock(&pRuntimeEnv->groupResInfo, pRuntimeEnv, pIntervalInfo->pRes); if (pIntervalInfo->binfo.pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pRuntimeEnv->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } return pIntervalInfo->binfo.pRes->info.rows == 0 ? NULL : pIntervalInfo->binfo.pRes; } static SSDataBlock* doSTableIntervalAgg(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } STableIntervalOperatorInfo* pIntervalInfo = pOperator->info; STaskRuntimeEnv* pRuntimeEnv = pOperator->pRuntimeEnv; if (pOperator->status == OP_RES_TO_RETURN) { int64_t st = taosGetTimestampUs(); // copyToSDataBlock(NULL, 3000, pIntervalInfo->pRes, pIntervalInfo->rowCellInfoOffset); if (pIntervalInfo->binfo.pRes->info.rows == 0 || !hasRemainData(&pRuntimeEnv->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pIntervalInfo->binfo.pRes; } STaskAttr* pQueryAttr = pRuntimeEnv->pQueryAttr; int32_t order = pQueryAttr->order.order; SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // the pDataBlock are always the same one, no need to call this again STableQueryInfo* pTableQueryInfo = pRuntimeEnv->current; // setTagValue(pOperator, pTableQueryInfo->pTable, pIntervalInfo->pCtx, pOperator->numOfOutput); setInputDataBlock(pOperator, pIntervalInfo->binfo.pCtx, pBlock, pQueryAttr->order.order); setIntervalQueryRange(pRuntimeEnv, pBlock->info.window.skey); hashIntervalAgg(pOperator, &pTableQueryInfo->resInfo, pBlock, pTableQueryInfo->groupIndex); } pOperator->status = OP_RES_TO_RETURN; pQueryAttr->order.order = order; // TODO : restore the order doCloseAllTimeWindow(pRuntimeEnv); setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); // copyToSDataBlock(pRuntimeEnv, 3000, pIntervalInfo->pRes, pIntervalInfo->rowCellInfoOffset); if (pIntervalInfo->binfo.pRes->info.rows == 0 || !hasRemainData(&pRuntimeEnv->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } return pIntervalInfo->binfo.pRes; } static SSDataBlock* doAllSTableIntervalAgg(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } STableIntervalOperatorInfo* pIntervalInfo = pOperator->info; STaskRuntimeEnv* pRuntimeEnv = pOperator->pRuntimeEnv; if (pOperator->status == OP_RES_TO_RETURN) { // copyToSDataBlock(pRuntimeEnv, 3000, pIntervalInfo->pRes, pIntervalInfo->rowCellInfoOffset); if (pIntervalInfo->binfo.pRes->info.rows == 0 || !hasRemainData(&pRuntimeEnv->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } return pIntervalInfo->binfo.pRes; } SOperatorInfo* downstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(downstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = downstream->getNextFn(downstream, newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // the pDataBlock are always the same one, no need to call this again STableQueryInfo* pTableQueryInfo = pRuntimeEnv->current; // setTagValue(pOperator, pTableQueryInfo->pTable, pIntervalInfo->pCtx, pOperator->numOfOutput); // setInputDataBlock(pOperator, pIntervalInfo->binfo.pCtx, pBlock, pQueryAttr->order.order); setIntervalQueryRange(pRuntimeEnv, pBlock->info.window.skey); hashAllIntervalAgg(pOperator, &pTableQueryInfo->resInfo, pBlock, pTableQueryInfo->groupIndex); } pOperator->status = OP_RES_TO_RETURN; // pQueryAttr->order.order = order; // TODO : restore the order doCloseAllTimeWindow(pRuntimeEnv); setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); int64_t st = taosGetTimestampUs(); // copyToSDataBlock(pRuntimeEnv, 3000, pIntervalInfo->pRes, pIntervalInfo->rowCellInfoOffset); if (pIntervalInfo->binfo.pRes->info.rows == 0 || !hasRemainData(&pRuntimeEnv->groupResInfo)) { pOperator->status = OP_EXEC_DONE; } // SQInfo* pQInfo = pRuntimeEnv->qinfo; // pQInfo->summary.firstStageMergeTime += (taosGetTimestampUs() - st); return pIntervalInfo->binfo.pRes; } static void doStateWindowAggImpl(SOperatorInfo* pOperator, SStateWindowOperatorInfo* pInfo, SSDataBlock* pSDataBlock) { STaskRuntimeEnv* pRuntimeEnv = pOperator->pRuntimeEnv; STableQueryInfo* item = pRuntimeEnv->current; SColumnInfoData* pColInfoData = taosArrayGet(pSDataBlock->pDataBlock, pInfo->colIndex); SOptrBasicInfo* pBInfo = &pInfo->binfo; bool masterScan = IS_MAIN_SCAN(pRuntimeEnv); int16_t bytes = pColInfoData->info.bytes; int16_t type = pColInfoData->info.type; SColumnInfoData* pTsColInfoData = taosArrayGet(pSDataBlock->pDataBlock, 0); TSKEY* tsList = (TSKEY*)pTsColInfoData->pData; if (IS_REPEAT_SCAN(pRuntimeEnv) && !pInfo->reptScan) { pInfo->reptScan = true; taosMemoryFreeClear(pInfo->prevData); } pInfo->numOfRows = 0; for (int32_t j = 0; j < pSDataBlock->info.rows; ++j) { char* val = ((char*)pColInfoData->pData) + bytes * j; if (isNull(val, type)) { continue; } if (pInfo->prevData == NULL) { pInfo->prevData = taosMemoryMalloc(bytes); memcpy(pInfo->prevData, val, bytes); pInfo->numOfRows = 1; pInfo->curWindow.skey = tsList[j]; pInfo->curWindow.ekey = tsList[j]; pInfo->start = j; } else if (memcmp(pInfo->prevData, val, bytes) == 0) { pInfo->curWindow.ekey = tsList[j]; pInfo->numOfRows += 1; // pInfo->start = j; if (j == 0 && pInfo->start != 0) { pInfo->numOfRows = 1; pInfo->start = 0; } } else { SResultRow* pResult = NULL; pInfo->curWindow.ekey = pInfo->curWindow.skey; int32_t ret = setResultOutputBufByKey(pRuntimeEnv, &pBInfo->resultRowInfo, pSDataBlock->info.uid, &pInfo->curWindow, masterScan, &pResult, item->groupIndex, pBInfo->pCtx, pOperator->numOfOutput, pBInfo->rowCellInfoOffset); if (ret != TSDB_CODE_SUCCESS) { // null data, too many state code longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_APP_ERROR); } // doApplyFunctions(pRuntimeEnv, pBInfo->pCtx, &pInfo->curWindow, pInfo->start, pInfo->numOfRows, tsList, // pSDataBlock->info.rows, pOperator->numOfOutput); pInfo->curWindow.skey = tsList[j]; pInfo->curWindow.ekey = tsList[j]; memcpy(pInfo->prevData, val, bytes); pInfo->numOfRows = 1; pInfo->start = j; } } SResultRow* pResult = NULL; pInfo->curWindow.ekey = pInfo->curWindow.skey; int32_t ret = setResultOutputBufByKey(pRuntimeEnv, &pBInfo->resultRowInfo, pSDataBlock->info.uid, &pInfo->curWindow, masterScan, &pResult, item->groupIndex, pBInfo->pCtx, pOperator->numOfOutput, pBInfo->rowCellInfoOffset); if (ret != TSDB_CODE_SUCCESS) { // null data, too many state code longjmp(pRuntimeEnv->env, TSDB_CODE_QRY_APP_ERROR); } // doApplyFunctions(pRuntimeEnv, pBInfo->pCtx, &pInfo->curWindow, pInfo->start, pInfo->numOfRows, tsList, // pSDataBlock->info.rows, pOperator->numOfOutput); } static SSDataBlock* doStateWindowAgg(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SStateWindowOperatorInfo* pWindowInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SOptrBasicInfo* pBInfo = &pWindowInfo->binfo; if (pOperator->status == OP_RES_TO_RETURN) { // toSDatablock(&pRuntimeEnv->groupResInfo, pRuntimeEnv, pBInfo->pRes); // if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pRuntimeEnv->groupResInfo)) { // pOperator->status = OP_EXEC_DONE; // } 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->getNextFn(downstream, newgroup); publishOperatorProfEvent(downstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (pBlock == NULL) { break; } // setInputDataBlock(pOperator, pBInfo->pCtx, pDataBlock, TSDB_ORDER_ASC); // if (pWindowInfo->colIndex == -1) { // pWindowInfo->colIndex = getGroupbyColumnIndex(pRuntimeEnv->pQueryAttr->pGroupbyExpr, pBlock); // } doStateWindowAggImpl(pOperator, pWindowInfo, pBlock); } // restore the value // pQueryAttr->order.order = order; // pQueryAttr->window = win; pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pBInfo->resultRowInfo); setTaskStatus(pOperator->pTaskInfo, TASK_COMPLETED); finalizeQueryResult(pBInfo->pCtx, pOperator->numOfOutput); // initGroupResInfo(&pRuntimeEnv->groupResInfo, &pBInfo->resultRowInfo); // toSDatablock(&pRuntimeEnv->groupResInfo, pRuntimeEnv, pBInfo->pRes); // if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pRuntimeEnv->groupResInfo)) { // pOperator->status = OP_EXEC_DONE; // } return pBInfo->pRes->info.rows == 0 ? NULL : pBInfo->pRes; } static SSDataBlock* doSessionWindowAgg(SOperatorInfo* pOperator, bool* newgroup) { if (pOperator->status == OP_EXEC_DONE) { return NULL; } SSessionAggOperatorInfo* pInfo = pOperator->info; SOptrBasicInfo* pBInfo = &pInfo->binfo; if (pOperator->status == OP_RES_TO_RETURN) { toSDatablock(&pInfo->groupResInfo, pInfo->aggSup.pResultBuf, pBInfo->pRes, pBInfo->capacity, pBInfo->rowCellInfoOffset); 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->getNextFn(downstream, newgroup); 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); doSessionWindowAggImpl(pOperator, pInfo, pBlock); } // restore the value pOperator->status = OP_RES_TO_RETURN; closeAllResultRows(&pBInfo->resultRowInfo); finalizeMultiTupleQueryResult(pBInfo->pCtx, pOperator->numOfOutput, pInfo->aggSup.pResultBuf, &pBInfo->resultRowInfo, pBInfo->rowCellInfoOffset); initGroupResInfo(&pInfo->groupResInfo, &pBInfo->resultRowInfo); blockDataEnsureCapacity(pBInfo->pRes, pBInfo->capacity); toSDatablock(&pInfo->groupResInfo, pInfo->aggSup.pResultBuf, pBInfo->pRes, pBInfo->capacity, pBInfo->rowCellInfoOffset); if (pBInfo->pRes->info.rows == 0 || !hasRemainDataInCurrentGroup(&pInfo->groupResInfo)) { doSetOperatorCompleted(pOperator); } return pBInfo->pRes->info.rows == 0 ? NULL : pBInfo->pRes; } static void doHandleRemainBlockForNewGroupImpl(SFillOperatorInfo* pInfo, SResultInfo* pResultInfo, bool* newgroup, SExecTaskInfo* pTaskInfo) { pInfo->totalInputRows = pInfo->existNewGroupBlock->info.rows; int64_t ekey = Q_STATUS_EQUAL(pTaskInfo->status, TASK_COMPLETED) ? pTaskInfo->window.ekey : pInfo->existNewGroupBlock->info.window.ekey; taosResetFillInfo(pInfo->pFillInfo, getFillInfoStart(pInfo->pFillInfo)); taosFillSetStartInfo(pInfo->pFillInfo, pInfo->existNewGroupBlock->info.rows, ekey); taosFillSetInputDataBlock(pInfo->pFillInfo, pInfo->existNewGroupBlock); doFillTimeIntervalGapsInResults(pInfo->pFillInfo, pInfo->pRes, pResultInfo->capacity, pInfo->p); pInfo->existNewGroupBlock = NULL; *newgroup = true; } static void doHandleRemainBlockFromNewGroup(SFillOperatorInfo* pInfo, SResultInfo* pResultInfo, bool* newgroup, SExecTaskInfo* pTaskInfo) { if (taosFillHasMoreResults(pInfo->pFillInfo)) { *newgroup = false; doFillTimeIntervalGapsInResults(pInfo->pFillInfo, pInfo->pRes, (int32_t)pResultInfo->capacity, pInfo->p); if (pInfo->pRes->info.rows > pResultInfo->threshold || (!pInfo->multigroupResult)) { return; } } // handle the cached new group data block if (pInfo->existNewGroupBlock) { doHandleRemainBlockForNewGroupImpl(pInfo, pResultInfo, newgroup, pTaskInfo); } } static SSDataBlock* doFill(SOperatorInfo* pOperator, bool* newgroup) { SFillOperatorInfo* pInfo = pOperator->info; SExecTaskInfo* pTaskInfo = pOperator->pTaskInfo; SResultInfo* pResultInfo = &pOperator->resultInfo; blockDataCleanup(pInfo->pRes); if (pOperator->status == OP_EXEC_DONE) { return NULL; } doHandleRemainBlockFromNewGroup(pInfo, pResultInfo, newgroup, pTaskInfo); if (pInfo->pRes->info.rows > pResultInfo->threshold || (!pInfo->multigroupResult && pInfo->pRes->info.rows > 0)) { return pInfo->pRes; } SOperatorInfo* pDownstream = pOperator->pDownstream[0]; while (1) { publishOperatorProfEvent(pDownstream, QUERY_PROF_BEFORE_OPERATOR_EXEC); SSDataBlock* pBlock = pDownstream->getNextFn(pDownstream, newgroup); publishOperatorProfEvent(pDownstream, QUERY_PROF_AFTER_OPERATOR_EXEC); if (*newgroup) { assert(pBlock != NULL); } if (*newgroup && pInfo->totalInputRows > 0) { // there are already processed current group data block pInfo->existNewGroupBlock = pBlock; *newgroup = false; // Fill the previous group data block, before handle the data block of new group. // Close the fill operation for previous group data block taosFillSetStartInfo(pInfo->pFillInfo, 0, pTaskInfo->window.ekey); } else { if (pBlock == NULL) { if (pInfo->totalInputRows == 0) { pOperator->status = OP_EXEC_DONE; return NULL; } taosFillSetStartInfo(pInfo->pFillInfo, 0, pTaskInfo->window.ekey); } else { pInfo->totalInputRows += pBlock->info.rows; taosFillSetStartInfo(pInfo->pFillInfo, pBlock->info.rows, pBlock->info.window.ekey); taosFillSetInputDataBlock(pInfo->pFillInfo, pBlock); } } doFillTimeIntervalGapsInResults(pInfo->pFillInfo, pInfo->pRes, pInfo->capacity, pInfo->p); // current group has no more result to return if (pInfo->pRes->info.rows > 0) { // 1. The result in current group not reach the threshold of output result, continue // 2. If multiple group results existing in one SSDataBlock is not allowed, return immediately if (pInfo->pRes->info.rows > pResultInfo->threshold || pBlock == NULL || (!pInfo->multigroupResult)) { return pInfo->pRes; } doHandleRemainBlockFromNewGroup(pInfo, pResultInfo, newgroup, pTaskInfo); if (pInfo->pRes->info.rows > pOperator->resultInfo.threshold || pBlock == NULL) { return pInfo->pRes; } } else if (pInfo->existNewGroupBlock) { // try next group assert(pBlock != NULL); doHandleRemainBlockForNewGroupImpl(pInfo, pResultInfo, newgroup, pTaskInfo); if (pInfo->pRes->info.rows > pResultInfo->threshold) { return pInfo->pRes; } } else { return NULL; } } } // todo set the attribute of query scan count static int32_t getNumOfScanTimes(STaskAttr* pQueryAttr) { for (int32_t i = 0; i < pQueryAttr->numOfOutput; ++i) { int32_t functionId = getExprFunctionId(&pQueryAttr->pExpr1[i]); if (functionId == FUNCTION_STDDEV || functionId == FUNCTION_PERCT) { return 2; } } return 1; } static void destroyOperatorInfo(SOperatorInfo* pOperator) { if (pOperator == NULL) { return; } if (pOperator->closeFn != NULL) { pOperator->closeFn(pOperator->info, pOperator->numOfOutput); } if (pOperator->pDownstream != NULL) { for (int32_t i = 0; i < pOperator->numOfDownstream; ++i) { destroyOperatorInfo(pOperator->pDownstream[i]); } taosMemoryFreeClear(pOperator->pDownstream); pOperator->numOfDownstream = 0; } taosMemoryFreeClear(pOperator->info); taosMemoryFreeClear(pOperator); } int32_t doInitAggInfoSup(SAggSupporter* pAggSup, SqlFunctionCtx* pCtx, int32_t numOfOutput, const char* pKey) { _hash_fn_t hashFn = taosGetDefaultHashFunction(TSDB_DATA_TYPE_BINARY); pAggSup->resultRowSize = getResultRowSize(pCtx, numOfOutput); pAggSup->keyBuf = taosMemoryCalloc(1, sizeof(int64_t) + sizeof(int64_t) + POINTER_BYTES); pAggSup->pResultRowHashTable = taosHashInit(10, hashFn, true, HASH_NO_LOCK); pAggSup->pResultRowListSet = taosHashInit(100, hashFn, false, HASH_NO_LOCK); pAggSup->pResultRowArrayList = taosArrayInit(10, sizeof(SResultRowCell)); if (pAggSup->keyBuf == NULL || pAggSup->pResultRowArrayList == NULL || pAggSup->pResultRowListSet == NULL || pAggSup->pResultRowHashTable == NULL) { return TSDB_CODE_OUT_OF_MEMORY; } int32_t code = createDiskbasedBuf(&pAggSup->pResultBuf, 4096, 4096 * 256, pKey, "/tmp/"); if (code != TSDB_CODE_SUCCESS) { return code; } return TSDB_CODE_SUCCESS; } static void cleanupAggSup(SAggSupporter* pAggSup) { taosMemoryFreeClear(pAggSup->keyBuf); taosHashCleanup(pAggSup->pResultRowHashTable); taosHashCleanup(pAggSup->pResultRowListSet); taosArrayDestroy(pAggSup->pResultRowArrayList); destroyDiskbasedBuf(pAggSup->pResultBuf); } int32_t initAggInfo(SOptrBasicInfo* pBasicInfo, SAggSupporter* pAggSup, SExprInfo* pExprInfo, int32_t numOfCols, int32_t numOfRows, SSDataBlock* pResultBlock, const char* pkey) { pBasicInfo->pCtx = createSqlFunctionCtx_rv(pExprInfo, numOfCols, &pBasicInfo->rowCellInfoOffset); pBasicInfo->pRes = pResultBlock; pBasicInfo->capacity = numOfRows; doInitAggInfoSup(pAggSup, pBasicInfo->pCtx, numOfCols, pkey); } static STableQueryInfo* initTableQueryInfo(const STableGroupInfo* pTableGroupInfo) { STableQueryInfo* pTableQueryInfo = taosMemoryCalloc(pTableGroupInfo->numOfTables, sizeof(STableQueryInfo)); if (pTableQueryInfo == NULL) { return NULL; } int32_t index = 0; for (int32_t i = 0; i < taosArrayGetSize(pTableGroupInfo->pGroupList); ++i) { SArray* pa = taosArrayGetP(pTableGroupInfo->pGroupList, i); for (int32_t j = 0; j < taosArrayGetSize(pa); ++j) { STableKeyInfo* pk = taosArrayGet(pa, j); STableQueryInfo* pTQueryInfo = &pTableQueryInfo[index++]; pTQueryInfo->uid = pk->uid; pTQueryInfo->lastKey = pk->lastKey; pTQueryInfo->groupIndex = i; } } STimeWindow win = {0, INT64_MAX}; createTableQueryInfo(pTableQueryInfo, false, win); return pTableQueryInfo; } SOperatorInfo* createAggregateOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResultBlock, SExecTaskInfo* pTaskInfo, const STableGroupInfo* pTableGroupInfo) { SAggOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SAggOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } //(int32_t)(getRowNumForMultioutput(pQueryAttr, pQueryAttr->topBotQuery, pQueryAttr->stableQuery)); int32_t numOfRows = 1; int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, numOfRows, pResultBlock, pTaskInfo->id.str); pInfo->pTableQueryInfo = initTableQueryInfo(pTableGroupInfo); if (code != TSDB_CODE_SUCCESS || pInfo->pTableQueryInfo == NULL) { goto _error; } setFunctionResultOutput(&pInfo->binfo, &pInfo->aggSup, MAIN_SCAN, pTaskInfo); pOperator->name = "TableAggregate"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_AGG; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->pExpr = pExprInfo; pOperator->numOfOutput = numOfCols; pOperator->pTaskInfo = pTaskInfo; pOperator->_openFn = doOpenAggregateOptr; pOperator->getNextFn = getAggregateResult; pOperator->closeFn = destroyAggOperatorInfo; pOperator->encodeResultRow = aggEncodeResultRow; pOperator->decodeResultRow = aggDecodeResultRow; code = appendDownstream(pOperator, &downstream, 1); if (code != TSDB_CODE_SUCCESS) { goto _error; } return pOperator; _error: destroyAggOperatorInfo(pInfo, numOfCols); taosMemoryFreeClear(pInfo); taosMemoryFreeClear(pOperator); pTaskInfo->code = TSDB_CODE_OUT_OF_MEMORY; return NULL; } void doDestroyBasicInfo(SOptrBasicInfo* pInfo, int32_t numOfOutput) { assert(pInfo != NULL); destroySqlFunctionCtx(pInfo->pCtx, numOfOutput); taosMemoryFreeClear(pInfo->rowCellInfoOffset); cleanupResultRowInfo(&pInfo->resultRowInfo); pInfo->pRes = blockDataDestroy(pInfo->pRes); } void destroyBasicOperatorInfo(void* param, int32_t numOfOutput) { SOptrBasicInfo* pInfo = (SOptrBasicInfo*)param; doDestroyBasicInfo(pInfo, numOfOutput); } void destroyStateWindowOperatorInfo(void* param, int32_t numOfOutput) { SStateWindowOperatorInfo* pInfo = (SStateWindowOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); taosMemoryFreeClear(pInfo->prevData); } void destroyAggOperatorInfo(void* param, int32_t numOfOutput) { SAggOperatorInfo* pInfo = (SAggOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); } void destroyIntervalOperatorInfo(void* param, int32_t numOfOutput) { STableIntervalOperatorInfo* pInfo = (STableIntervalOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); cleanupAggSup(&pInfo->aggSup); } void destroySWindowOperatorInfo(void* param, int32_t numOfOutput) { SSessionAggOperatorInfo* pInfo = (SSessionAggOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); } void destroySFillOperatorInfo(void* param, int32_t numOfOutput) { SFillOperatorInfo* pInfo = (SFillOperatorInfo*)param; pInfo->pFillInfo = taosDestroyFillInfo(pInfo->pFillInfo); pInfo->pRes = blockDataDestroy(pInfo->pRes); taosMemoryFreeClear(pInfo->p); } static void destroyProjectOperatorInfo(void* param, int32_t numOfOutput) { SProjectOperatorInfo* pInfo = (SProjectOperatorInfo*)param; doDestroyBasicInfo(&pInfo->binfo, numOfOutput); } static void destroyTagScanOperatorInfo(void* param, int32_t numOfOutput) { STagScanInfo* pInfo = (STagScanInfo*)param; pInfo->pRes = blockDataDestroy(pInfo->pRes); } static void destroyOrderOperatorInfo(void* param, int32_t numOfOutput) { SSortOperatorInfo* pInfo = (SSortOperatorInfo*)param; pInfo->pDataBlock = blockDataDestroy(pInfo->pDataBlock); taosArrayDestroy(pInfo->pSortInfo); } void destroyExchangeOperatorInfo(void* param, int32_t numOfOutput) { SExchangeInfo* pExInfo = (SExchangeInfo*)param; taosArrayDestroy(pExInfo->pSources); taosArrayDestroy(pExInfo->pSourceDataInfo); if (pExInfo->pResult != NULL) { blockDataDestroy(pExInfo->pResult); } tsem_destroy(&pExInfo->ready); } SOperatorInfo* createMultiTableAggOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResBlock, SExecTaskInfo* pTaskInfo, const STableGroupInfo* pTableGroupInfo) { SAggOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SAggOperatorInfo)); int32_t numOfRows = 1; int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, numOfRows, pResBlock, pTaskInfo->id.str); pInfo->pTableQueryInfo = initTableQueryInfo(pTableGroupInfo); if (code != TSDB_CODE_SUCCESS || pInfo->pTableQueryInfo == NULL) { goto _error; } size_t tableGroup = taosArrayGetSize(pTableGroupInfo->pGroupList); initResultRowInfo(&pInfo->binfo.resultRowInfo, (int32_t)tableGroup); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pOperator->name = "MultiTableAggregate"; // pOperator->operatorType = OP_MultiTableAggregate; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->pExpr = pExprInfo; pOperator->numOfOutput = numOfCols; pOperator->pTaskInfo = pTaskInfo; pOperator->getNextFn = doMultiTableAggregate; pOperator->closeFn = destroyAggOperatorInfo; code = appendDownstream(pOperator, &downstream, 1); if (code != TSDB_CODE_SUCCESS) { goto _error; } return pOperator; _error: return NULL; } static SArray* setRowTsColumnOutputInfo(SqlFunctionCtx* pCtx, int32_t numOfCols) { SArray* pList = taosArrayInit(4, sizeof(int32_t)); for(int32_t i = 0; i < numOfCols; ++i) { if (fmIsPseudoColumnFunc(pCtx[i].functionId)) { taosArrayPush(pList, &i); } } return pList; } SOperatorInfo* createProjectOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t num, SSDataBlock* pResBlock, SLimit* pLimit, SExecTaskInfo* pTaskInfo) { SProjectOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SProjectOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->limit = *pLimit; pInfo->curOffset = pLimit->offset; pInfo->binfo.pRes = pResBlock; int32_t numOfCols = num; int32_t numOfRows = 4096; initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, numOfRows, pResBlock, pTaskInfo->id.str); setFunctionResultOutput(&pInfo->binfo, &pInfo->aggSup, MAIN_SCAN, pTaskInfo); pInfo->pPseudoColInfo = setRowTsColumnOutputInfo(pInfo->binfo.pCtx, numOfCols); pOperator->name = "ProjectOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_PROJECT; pOperator->blockingOptr = false; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->pExpr = pExprInfo; pOperator->numOfOutput = num; pOperator->_openFn = operatorDummyOpenFn; pOperator->getNextFn = doProjectOperation; pOperator->closeFn = destroyProjectOperatorInfo; pOperator->pTaskInfo = pTaskInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); if (code != TSDB_CODE_SUCCESS) { goto _error; } return pOperator; _error: pTaskInfo->code = TSDB_CODE_OUT_OF_MEMORY; return NULL; } SOperatorInfo* createIntervalOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResBlock, SInterval* pInterval, int32_t primaryTsSlot, const STableGroupInfo* pTableGroupInfo, SExecTaskInfo* pTaskInfo) { STableIntervalOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(STableIntervalOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } pInfo->order = TSDB_ORDER_ASC; pInfo->interval = *pInterval; pInfo->execModel = pTaskInfo->execModel; pInfo->win = pTaskInfo->window; pInfo->win.skey = 0; pInfo->win.ekey = INT64_MAX; pInfo->primaryTsIndex = primaryTsSlot; int32_t numOfRows = 4096; int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, numOfRows, pResBlock, pTaskInfo->id.str); initExecTimeWindowInfo(&pInfo->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 = "TimeIntervalAggOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_INTERVAL; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExprInfo; pOperator->pTaskInfo = pTaskInfo; pOperator->numOfOutput = numOfCols; pOperator->info = pInfo; pOperator->_openFn = doOpenIntervalAgg; pOperator->getNextFn = doBuildIntervalResult; pOperator->getStreamResFn= doStreamIntervalAgg; pOperator->closeFn = destroyIntervalOperatorInfo; 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* createAllTimeIntervalOperatorInfo(STaskRuntimeEnv* pRuntimeEnv, SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfOutput) { STableIntervalOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(STableIntervalOperatorInfo)); // pInfo->binfo.pCtx = createSqlFunctionCtx(pRuntimeEnv, pExpr, numOfOutput, &pInfo->binfo.rowCellInfoOffset); // pInfo->binfo.pRes = createOutputBuf(pExpr, numOfOutput, pResultInfo->capacity); initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pOperator->name = "AllTimeIntervalAggOperator"; // pOperator->operatorType = OP_AllTimeWindow; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExpr; pOperator->numOfOutput = numOfOutput; pOperator->info = pInfo; pOperator->pRuntimeEnv = pRuntimeEnv; pOperator->getNextFn = doAllIntervalAgg; pOperator->closeFn = destroyBasicOperatorInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; } SOperatorInfo* createStatewindowOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfCols, SSDataBlock* pResBlock, SExecTaskInfo* pTaskInfo) { SStateWindowOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SStateWindowOperatorInfo)); pInfo->colIndex = -1; pInfo->reptScan = false; // pInfo->binfo.pCtx = createSqlFunctionCtx(pRuntimeEnv, pExpr, numOfOutput, &pInfo->binfo.rowCellInfoOffset); // pInfo->binfo.pRes = createOutputBuf(pExpr, numOfOutput, pResultInfo->capacity); initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pOperator->name = "StateWindowOperator"; // pOperator->operatorType = OP_StateWindow; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExpr; pOperator->numOfOutput = numOfCols; pOperator->pTaskInfo = pTaskInfo; pOperator->info = pInfo; pOperator->getNextFn = doStateWindowAgg; pOperator->closeFn = destroyStateWindowOperatorInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; } SOperatorInfo* createSessionAggOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExprInfo, int32_t numOfCols, SSDataBlock* pResBlock, int64_t gap, SExecTaskInfo* pTaskInfo) { SSessionAggOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SSessionAggOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); if (pInfo == NULL || pOperator == NULL) { goto _error; } int32_t numOfRows = 4096; int32_t code = initAggInfo(&pInfo->binfo, &pInfo->aggSup, pExprInfo, numOfCols, numOfRows, pResBlock, pTaskInfo->id.str); if (code != TSDB_CODE_SUCCESS) { goto _error; } initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); initExecTimeWindowInfo(&pInfo->timeWindowData, &pTaskInfo->window); pInfo->gap = gap; pInfo->binfo.pRes = pResBlock; pInfo->prevTs = INT64_MIN; pInfo->reptScan = false; pOperator->name = "SessionWindowAggOperator"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_SESSION_WINDOW; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExprInfo; pOperator->numOfOutput = numOfCols; pOperator->info = pInfo; pOperator->getNextFn = doSessionWindowAgg; pOperator->closeFn = destroySWindowOperatorInfo; 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; } SOperatorInfo* createMultiTableTimeIntervalOperatorInfo(STaskRuntimeEnv* pRuntimeEnv, SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfOutput) { STableIntervalOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(STableIntervalOperatorInfo)); // pInfo->binfo.pCtx = createSqlFunctionCtx(pRuntimeEnv, pExpr, numOfOutput, &pInfo->binfo.rowCellInfoOffset); // pInfo->binfo.pRes = createOutputBuf(pExpr, numOfOutput, pResultInfo->capacity); initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pOperator->name = "MultiTableTimeIntervalOperator"; // pOperator->operatorType = OP_MultiTableTimeInterval; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExpr; pOperator->numOfOutput = numOfOutput; pOperator->info = pInfo; pOperator->pRuntimeEnv = pRuntimeEnv; pOperator->getNextFn = doSTableIntervalAgg; pOperator->closeFn = destroyBasicOperatorInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; } SOperatorInfo* createAllMultiTableTimeIntervalOperatorInfo(STaskRuntimeEnv* pRuntimeEnv, SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfOutput) { STableIntervalOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(STableIntervalOperatorInfo)); // pInfo->binfo.pCtx = createSqlFunctionCtx(pRuntimeEnv, pExpr, numOfOutput, &pInfo->binfo.rowCellInfoOffset); // pInfo->binfo.pRes = createOutputBuf(pExpr, numOfOutput, pResultInfo->capacity); initResultRowInfo(&pInfo->binfo.resultRowInfo, 8); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pOperator->name = "AllMultiTableTimeIntervalOperator"; // pOperator->operatorType = OP_AllMultiTableTimeInterval; pOperator->blockingOptr = true; pOperator->status = OP_NOT_OPENED; pOperator->pExpr = pExpr; pOperator->numOfOutput = numOfOutput; pOperator->info = pInfo; pOperator->pRuntimeEnv = pRuntimeEnv; pOperator->getNextFn = doAllSTableIntervalAgg; pOperator->closeFn = destroyBasicOperatorInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; } static int32_t initFillInfo(SFillOperatorInfo* pInfo, SExprInfo* pExpr, int32_t numOfCols, int64_t* fillVal, STimeWindow win, int32_t capacity, const char* id, SInterval* pInterval, int32_t fillType) { struct SFillColInfo* pColInfo = createFillColInfo(pExpr, numOfCols, (int64_t*)fillVal); TSKEY sk = TMIN(win.skey, win.ekey); TSKEY ek = TMAX(win.skey, win.ekey); // TODO set correct time precision STimeWindow w = TSWINDOW_INITIALIZER; getAlignQueryTimeWindow(pInterval, TSDB_TIME_PRECISION_MILLI, win.skey, sk, ek, &w); int32_t order = TSDB_ORDER_ASC; pInfo->pFillInfo = taosCreateFillInfo(order, w.skey, 0, capacity, numOfCols, pInterval->sliding, pInterval->slidingUnit, (int8_t)pInterval->precision, fillType, pColInfo, id); pInfo->p = taosMemoryCalloc(numOfCols, POINTER_BYTES); if (pInfo->pFillInfo == NULL || pInfo->p == NULL) { return TSDB_CODE_OUT_OF_MEMORY; } else { return TSDB_CODE_SUCCESS; } } SOperatorInfo* createFillOperatorInfo(SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfCols, SInterval* pInterval, SSDataBlock* pResBlock, int32_t fillType, char* fillVal, bool multigroupResult, SExecTaskInfo* pTaskInfo) { SFillOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SFillOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pInfo->pRes = pResBlock; pInfo->multigroupResult = multigroupResult; pInfo->intervalInfo = *pInterval; SResultInfo* pResultInfo = &pOperator->resultInfo; int32_t code = initFillInfo(pInfo, pExpr, numOfCols, (int64_t*)fillVal, pTaskInfo->window, pResultInfo->capacity, pTaskInfo->id.str, pInterval, fillType); if (code != TSDB_CODE_SUCCESS) { goto _error; } pOperator->name = "FillOperator"; pOperator->blockingOptr = false; pOperator->status = OP_NOT_OPENED; // pOperator->operatorType = OP_Fill; pOperator->pExpr = pExpr; pOperator->numOfOutput = numOfCols; pOperator->info = pInfo; pOperator->_openFn = operatorDummyOpenFn; pOperator->getNextFn = doFill; pOperator->pTaskInfo = pTaskInfo; pOperator->closeFn = destroySFillOperatorInfo; code = appendDownstream(pOperator, &downstream, 1); return pOperator; _error: taosMemoryFreeClear(pOperator); taosMemoryFreeClear(pInfo); return NULL; } SOperatorInfo* createSLimitOperatorInfo(STaskRuntimeEnv* pRuntimeEnv, SOperatorInfo* downstream, SExprInfo* pExpr, int32_t numOfOutput, void* pMerger, bool multigroupResult) { SSLimitOperatorInfo* pInfo = taosMemoryCalloc(1, sizeof(SSLimitOperatorInfo)); SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); // pInfo->orderColumnList = getResultGroupCheckColumns(pQueryAttr); // pInfo->slimit = pQueryAttr->slimit; // pInfo->limit = pQueryAttr->limit; // pInfo->capacity = pResultInfo->capacity; // pInfo->threshold = (int64_t)(pInfo->capacity * 0.8); // pInfo->currentOffset = pQueryAttr->limit.offset; // pInfo->currentGroupOffset = pQueryAttr->slimit.offset; pInfo->multigroupResult = multigroupResult; // TODO refactor int32_t len = 0; for (int32_t i = 0; i < numOfOutput; ++i) { len += pExpr[i].base.resSchema.bytes; } int32_t numOfCols = (pInfo->orderColumnList != NULL) ? (int32_t)taosArrayGetSize(pInfo->orderColumnList) : 0; pInfo->prevRow = taosMemoryCalloc(1, (POINTER_BYTES * numOfCols + len)); int32_t offset = POINTER_BYTES * numOfCols; for (int32_t i = 0; i < numOfCols; ++i) { pInfo->prevRow[i] = (char*)pInfo->prevRow + offset; SColIndex* index = taosArrayGet(pInfo->orderColumnList, i); offset += pExpr[index->colIndex].base.resSchema.bytes; } // pInfo->pRes = createOutputBuf(pExpr, numOfOutput, pOperator->resultInfo.capacity); pOperator->name = "SLimitOperator"; // pOperator->operatorType = OP_SLimit; pOperator->blockingOptr = false; pOperator->status = OP_NOT_OPENED; // pOperator->exec = doSLimit; pOperator->info = pInfo; pOperator->pRuntimeEnv = pRuntimeEnv; pOperator->closeFn = destroySlimitOperatorInfo; int32_t code = appendDownstream(pOperator, &downstream, 1); return pOperator; } static SSDataBlock* doTagScan(SOperatorInfo* pOperator, bool* newgroup) { #if 0 SOperatorInfo* pOperator = (SOperatorInfo*) param; if (pOperator->status == OP_EXEC_DONE) { return NULL; } STaskRuntimeEnv* pRuntimeEnv = pOperator->pRuntimeEnv; int32_t maxNumOfTables = (int32_t)pResultInfo->capacity; STagScanInfo *pInfo = pOperator->info; SSDataBlock *pRes = pInfo->pRes; *newgroup = false; int32_t count = 0; SArray* pa = GET_TABLEGROUP(pRuntimeEnv, 0); int32_t functionId = getExprFunctionId(&pOperator->pExpr[0]); if (functionId == FUNCTION_TID_TAG) { // return the tags & table Id assert(pQueryAttr->numOfOutput == 1); SExprInfo* pExprInfo = &pOperator->pExpr[0]; int32_t rsize = pExprInfo->base.resSchema.bytes; count = 0; int16_t bytes = pExprInfo->base.resSchema.bytes; int16_t type = pExprInfo->base.resSchema.type; for(int32_t i = 0; i < pQueryAttr->numOfTags; ++i) { if (pQueryAttr->tagColList[i].colId == pExprInfo->base.pColumns->info.colId) { bytes = pQueryAttr->tagColList[i].bytes; type = pQueryAttr->tagColList[i].type; break; } } SColumnInfoData* pColInfo = taosArrayGet(pRes->pDataBlock, 0); while(pInfo->curPos < pInfo->totalTables && count < maxNumOfTables) { int32_t i = pInfo->curPos++; STableQueryInfo *item = taosArrayGetP(pa, i); char *output = pColInfo->pData + count * rsize; varDataSetLen(output, rsize - VARSTR_HEADER_SIZE); output = varDataVal(output); STableId* id = TSDB_TABLEID(item->pTable); *(int16_t *)output = 0; output += sizeof(int16_t); *(int64_t *)output = id->uid; // memory align problem, todo serialize output += sizeof(id->uid); *(int32_t *)output = id->tid; output += sizeof(id->tid); *(int32_t *)output = pQueryAttr->vgId; output += sizeof(pQueryAttr->vgId); char* data = NULL; if (pExprInfo->base.pColumns->info.colId == TSDB_TBNAME_COLUMN_INDEX) { data = tsdbGetTableName(item->pTable); } else { data = tsdbGetTableTagVal(item->pTable, pExprInfo->base.pColumns->info.colId, type, bytes); } doSetTagValueToResultBuf(output, data, type, bytes); count += 1; } //qDebug("QInfo:0x%"PRIx64" create (tableId, tag) info completed, rows:%d", GET_TASKID(pRuntimeEnv), count); } else if (functionId == FUNCTION_COUNT) {// handle the "count(tbname)" query SColumnInfoData* pColInfo = taosArrayGet(pRes->pDataBlock, 0); *(int64_t*)pColInfo->pData = pInfo->totalTables; count = 1; pOperator->status = OP_EXEC_DONE; //qDebug("QInfo:0x%"PRIx64" create count(tbname) query, res:%d rows:1", GET_TASKID(pRuntimeEnv), count); } else { // return only the tags|table name etc. SExprInfo* pExprInfo = &pOperator->pExpr[0]; // todo use the column list instead of exprinfo count = 0; while(pInfo->curPos < pInfo->totalTables && count < maxNumOfTables) { int32_t i = pInfo->curPos++; STableQueryInfo* item = taosArrayGetP(pa, i); char *data = NULL, *dst = NULL; int16_t type = 0, bytes = 0; for(int32_t j = 0; j < pOperator->numOfOutput; ++j) { // not assign value in case of user defined constant output column if (TSDB_COL_IS_UD_COL(pExprInfo[j].base.pColumns->flag)) { continue; } SColumnInfoData* pColInfo = taosArrayGet(pRes->pDataBlock, j); type = pExprInfo[j].base.resSchema.type; bytes = pExprInfo[j].base.resSchema.bytes; if (pExprInfo[j].base.pColumns->info.colId == TSDB_TBNAME_COLUMN_INDEX) { data = tsdbGetTableName(item->pTable); } else { data = tsdbGetTableTagVal(item->pTable, pExprInfo[j].base.pColumns->info.colId, type, bytes); } dst = pColInfo->pData + count * pExprInfo[j].base.resSchema.bytes; doSetTagValueToResultBuf(dst, data, type, bytes); } count += 1; } if (pInfo->curPos >= pInfo->totalTables) { pOperator->status = OP_EXEC_DONE; } //qDebug("QInfo:0x%"PRIx64" create tag values results completed, rows:%d", GET_TASKID(pRuntimeEnv), count); } if (pOperator->status == OP_EXEC_DONE) { setTaskStatus(pOperator->pRuntimeEnv, TASK_COMPLETED); } pRes->info.rows = count; return (pRes->info.rows == 0)? NULL:pInfo->pRes; #endif } SOperatorInfo* createTagScanOperatorInfo(STaskRuntimeEnv* pRuntimeEnv, SExprInfo* pExpr, int32_t numOfOutput) { STagScanInfo* pInfo = taosMemoryCalloc(1, sizeof(STagScanInfo)); // pInfo->pRes = createOutputBuf(pExpr, numOfOutput, pResultInfo->capacity); size_t numOfGroup = GET_NUM_OF_TABLEGROUP(pRuntimeEnv); assert(numOfGroup == 0 || numOfGroup == 1); pInfo->totalTables = pRuntimeEnv->tableqinfoGroupInfo.numOfTables; pInfo->curPos = 0; SOperatorInfo* pOperator = taosMemoryCalloc(1, sizeof(SOperatorInfo)); pOperator->name = "SeqTableTagScan"; pOperator->operatorType = QUERY_NODE_PHYSICAL_PLAN_TAG_SCAN; pOperator->blockingOptr = false; pOperator->status = OP_NOT_OPENED; pOperator->info = pInfo; pOperator->getNextFn = doTagScan; pOperator->pExpr = pExpr; pOperator->numOfOutput = numOfOutput; pOperator->pRuntimeEnv = pRuntimeEnv; pOperator->closeFn = destroyTagScanOperatorInfo; return pOperator; } static int32_t getColumnIndexInSource(SQueriedTableInfo* pTableInfo, SExprBasicInfo* pExpr, SColumnInfo* pTagCols) { int32_t j = 0; if (TSDB_COL_IS_TAG(pExpr->pParam[0].pCol->type)) { if (pExpr->pParam[0].pCol->colId == TSDB_TBNAME_COLUMN_INDEX) { return TSDB_TBNAME_COLUMN_INDEX; } while (j < pTableInfo->numOfTags) { if (pExpr->pParam[0].pCol->colId == pTagCols[j].colId) { return j; } j += 1; } } /*else if (TSDB_COL_IS_UD_COL(pExpr->colInfo.flag)) { // user specified column data return TSDB_UD_COLUMN_INDEX; } else { while (j < pTableInfo->numOfCols) { if (pExpr->colInfo.colId == pTableInfo->colList[j].colId) { return j; } j += 1; } }*/ return INT32_MIN; // return a less than TSDB_TBNAME_COLUMN_INDEX value } bool validateExprColumnInfo(SQueriedTableInfo* pTableInfo, SExprBasicInfo* pExpr, SColumnInfo* pTagCols) { int32_t j = getColumnIndexInSource(pTableInfo, pExpr, pTagCols); return j != INT32_MIN; } static int32_t deserializeColFilterInfo(SColumnFilterInfo* pColFilters, int16_t numOfFilters, char** pMsg) { for (int32_t f = 0; f < numOfFilters; ++f) { SColumnFilterInfo* pFilterMsg = (SColumnFilterInfo*)(*pMsg); SColumnFilterInfo* pColFilter = &pColFilters[f]; pColFilter->filterstr = htons(pFilterMsg->filterstr); (*pMsg) += sizeof(SColumnFilterInfo); if (pColFilter->filterstr) { pColFilter->len = htobe64(pFilterMsg->len); pColFilter->pz = (int64_t)taosMemoryCalloc(1, (size_t)(pColFilter->len + 1 * TSDB_NCHAR_SIZE)); // note: null-terminator if (pColFilter->pz == 0) { return TSDB_CODE_QRY_OUT_OF_MEMORY; } memcpy((void*)pColFilter->pz, (*pMsg), (size_t)pColFilter->len); (*pMsg) += (pColFilter->len + 1); } else { pColFilter->lowerBndi = htobe64(pFilterMsg->lowerBndi); pColFilter->upperBndi = htobe64(pFilterMsg->upperBndi); } pColFilter->lowerRelOptr = htons(pFilterMsg->lowerRelOptr); pColFilter->upperRelOptr = htons(pFilterMsg->upperRelOptr); } return TSDB_CODE_SUCCESS; } static SResSchema createResSchema(int32_t type, int32_t bytes, int32_t slotId, int32_t scale, int32_t precision, const char* name) { SResSchema s = {0}; s.scale = scale; s.type = type; s.bytes = bytes; s.colId = slotId; s.precision = precision; strncpy(s.name, name, tListLen(s.name)); return s; } static SColumn* createColumn(int32_t blockId, int32_t slotId, SDataType* pType) { SColumn* pCol = taosMemoryCalloc(1, sizeof(SColumn)); if (pCol == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } pCol->slotId = slotId; pCol->bytes = pType->bytes; pCol->type = pType->type; pCol->scale = pType->scale; pCol->precision = pType->precision; pCol->dataBlockId = blockId; return pCol; } SExprInfo* createExprInfo(SNodeList* pNodeList, SNodeList* pGroupKeys, int32_t* numOfExprs) { int32_t numOfFuncs = LIST_LENGTH(pNodeList); int32_t numOfGroupKeys = 0; if (pGroupKeys != NULL) { numOfGroupKeys = LIST_LENGTH(pGroupKeys); } *numOfExprs = numOfFuncs + numOfGroupKeys; SExprInfo* pExprs = taosMemoryCalloc(*numOfExprs, sizeof(SExprInfo)); for (int32_t i = 0; i < (*numOfExprs); ++i) { STargetNode* pTargetNode = NULL; if (i < numOfFuncs) { pTargetNode = (STargetNode*)nodesListGetNode(pNodeList, i); } else { pTargetNode = (STargetNode*)nodesListGetNode(pGroupKeys, i - numOfFuncs); } SExprInfo* pExp = &pExprs[pTargetNode->slotId]; pExp->pExpr = taosMemoryCalloc(1, sizeof(tExprNode)); pExp->pExpr->_function.num = 1; pExp->pExpr->_function.functionId = -1; // it is a project query, or group by column if (nodeType(pTargetNode->pExpr) == QUERY_NODE_COLUMN) { pExp->pExpr->nodeType = QUERY_NODE_COLUMN; SColumnNode* pColNode = (SColumnNode*)pTargetNode->pExpr; pExp->base.pParam = taosMemoryCalloc(1, sizeof(SFunctParam)); pExp->base.numOfParams = 1; SDataType* pType = &pColNode->node.resType; pExp->base.resSchema = createResSchema(pType->type, pType->bytes, pTargetNode->slotId, pType->scale, pType->precision, pColNode->colName); pExp->base.pParam[0].pCol = createColumn(pColNode->dataBlockId, pColNode->slotId, pType); pExp->base.pParam[0].type = FUNC_PARAM_TYPE_COLUMN; } else if (nodeType(pTargetNode->pExpr) == QUERY_NODE_FUNCTION) { pExp->pExpr->nodeType = QUERY_NODE_FUNCTION; SFunctionNode* pFuncNode = (SFunctionNode*)pTargetNode->pExpr; SDataType* pType = &pFuncNode->node.resType; pExp->base.resSchema = createResSchema(pType->type, pType->bytes, pTargetNode->slotId, pType->scale, pType->precision, pFuncNode->node.aliasName); pExp->pExpr->_function.functionId = pFuncNode->funcId; pExp->pExpr->_function.pFunctNode = pFuncNode; strncpy(pExp->pExpr->_function.functionName, pFuncNode->functionName, tListLen(pExp->pExpr->_function.functionName)); // TODO: value parameter needs to be handled int32_t numOfParam = LIST_LENGTH(pFuncNode->pParameterList); pExp->base.pParam = taosMemoryCalloc(numOfParam, sizeof(SFunctParam)); pExp->base.numOfParams = numOfParam; for (int32_t j = 0; j < numOfParam; ++j) { SNode* p1 = nodesListGetNode(pFuncNode->pParameterList, j); if (p1->type == QUERY_NODE_COLUMN) { SColumnNode* pcn = (SColumnNode*) p1; pExp->base.pParam[j].type = FUNC_PARAM_TYPE_COLUMN; pExp->base.pParam[j].pCol = createColumn(pcn->dataBlockId, pcn->slotId, &pcn->node.resType); } else if (p1->type == QUERY_NODE_VALUE) { SValueNode* pvn = (SValueNode*)p1; pExp->base.pParam[j].type = FUNC_PARAM_TYPE_VALUE; } } } else if (nodeType(pTargetNode->pExpr) == QUERY_NODE_OPERATOR) { pExp->pExpr->nodeType = QUERY_NODE_OPERATOR; SOperatorNode* pNode = (SOperatorNode*)pTargetNode->pExpr; pExp->base.pParam = taosMemoryCalloc(1, sizeof(SFunctParam)); pExp->base.numOfParams = 1; SDataType* pType = &pNode->node.resType; pExp->base.resSchema = createResSchema(pType->type, pType->bytes, pTargetNode->slotId, pType->scale, pType->precision, pNode->node.aliasName); pExp->pExpr->_optrRoot.pRootNode = pTargetNode->pExpr; // pExp->base.pParam[0].type = FUNC_PARAM_TYPE_COLUMN; // pExp->base.pParam[0].pCol = createColumn(pTargetNode->dataBlockId, pTargetNode->slotId, pType); } else if (nodeType(pTargetNode->pExpr) == QUERY_NODE_VALUE) { pExp->pExpr->nodeType = QUERY_NODE_VALUE; SValueNode* pValNode = (SValueNode*)pTargetNode->pExpr; pExp->base.pParam = taosMemoryCalloc(1, sizeof(SFunctParam)); pExp->base.numOfParams = 1; SDataType* pType = &pValNode->node.resType; pExp->base.resSchema = createResSchema(pType->type, pType->bytes, pTargetNode->slotId, pType->scale, pType->precision, pValNode->node.aliasName); pExp->base.pParam[0].type = FUNC_PARAM_TYPE_VALUE; valueNodeToVariant(pValNode, &pExp->base.pParam[0].param); } else { ASSERT(0); } } return pExprs; } static SExecTaskInfo* createExecTaskInfo(uint64_t queryId, uint64_t taskId, EOPTR_EXEC_MODEL model) { SExecTaskInfo* pTaskInfo = taosMemoryCalloc(1, sizeof(SExecTaskInfo)); setTaskStatus(pTaskInfo, TASK_NOT_COMPLETED); pTaskInfo->cost.created = taosGetTimestampMs(); pTaskInfo->id.queryId = queryId; pTaskInfo->execModel = model; char* p = taosMemoryCalloc(1, 128); snprintf(p, 128, "TID:0x%" PRIx64 " QID:0x%" PRIx64, taskId, queryId); pTaskInfo->id.str = strdup(p); return pTaskInfo; } static tsdbReaderT doCreateDataReader(STableScanPhysiNode* pTableScanNode, SReadHandle* pHandle, STableGroupInfo* pTableGroupInfo, uint64_t queryId, uint64_t taskId); static int32_t doCreateTableGroup(void* metaHandle, int32_t tableType, uint64_t tableUid, STableGroupInfo* pGroupInfo, uint64_t queryId, uint64_t taskId); static SArray* extractTableIdList(const STableGroupInfo* pTableGroupInfo); static SArray* extractScanColumnId(SNodeList* pNodeList); static SArray* extractColumnInfo(SNodeList* pNodeList); static SArray* extractColMatchInfo(SNodeList* pNodeList, SDataBlockDescNode* pOutputNodeList, int32_t* numOfOutputCols); static SArray* createSortInfo(SNodeList* pNodeList); SOperatorInfo* createOperatorTree(SPhysiNode* pPhyNode, SExecTaskInfo* pTaskInfo, SReadHandle* pHandle, uint64_t queryId, uint64_t taskId, STableGroupInfo* pTableGroupInfo) { if (pPhyNode->pChildren == NULL || LIST_LENGTH(pPhyNode->pChildren) == 0) { int32_t type = nodeType(pPhyNode); if (QUERY_NODE_PHYSICAL_PLAN_TABLE_SCAN == type) { SScanPhysiNode* pScanPhyNode = (SScanPhysiNode*)pPhyNode; int32_t numOfCols = 0; tsdbReaderT pDataReader = doCreateDataReader((STableScanPhysiNode*)pPhyNode, pHandle, pTableGroupInfo, (uint64_t)queryId, taskId); SArray* pColList = extractColMatchInfo(pScanPhyNode->pScanCols, pScanPhyNode->node.pOutputDataBlockDesc, &numOfCols); return createTableScanOperatorInfo(pDataReader, pScanPhyNode->order, numOfCols, pScanPhyNode->count, pScanPhyNode->reverse, pColList, pScanPhyNode->node.pConditions, pTaskInfo); } else if (QUERY_NODE_PHYSICAL_PLAN_EXCHANGE == type) { SExchangePhysiNode* pExchange = (SExchangePhysiNode*)pPhyNode; SSDataBlock* pResBlock = createOutputBuf_rv1(pExchange->node.pOutputDataBlockDesc); return createExchangeOperatorInfo(pExchange->pSrcEndPoints, pResBlock, pTaskInfo); } else if (QUERY_NODE_PHYSICAL_PLAN_STREAM_SCAN == type) { SScanPhysiNode* pScanPhyNode = (SScanPhysiNode*)pPhyNode; // simple child table. int32_t code = doCreateTableGroup(pHandle->meta, pScanPhyNode->tableType, pScanPhyNode->uid, pTableGroupInfo, queryId, taskId); SArray* tableIdList = extractTableIdList(pTableGroupInfo); SSDataBlock* pResBlock = createOutputBuf_rv1(pScanPhyNode->node.pOutputDataBlockDesc); int32_t numOfCols = 0; SArray* pColList = extractColMatchInfo(pScanPhyNode->pScanCols, pScanPhyNode->node.pOutputDataBlockDesc, &numOfCols); SOperatorInfo* pOperator = createStreamScanOperatorInfo(pHandle->reader, pResBlock, pColList, tableIdList, pTaskInfo); taosArrayDestroy(tableIdList); return pOperator; } else if (QUERY_NODE_PHYSICAL_PLAN_SYSTABLE_SCAN == type) { SSystemTableScanPhysiNode* pSysScanPhyNode = (SSystemTableScanPhysiNode*)pPhyNode; SSDataBlock* pResBlock = createOutputBuf_rv1(pSysScanPhyNode->scan.node.pOutputDataBlockDesc); struct SScanPhysiNode* pScanNode = &pSysScanPhyNode->scan; SArray* colList = extractScanColumnId(pScanNode->pScanCols); SOperatorInfo* pOperator = createSysTableScanOperatorInfo( pHandle->meta, pResBlock, &pScanNode->tableName, pScanNode->node.pConditions, pSysScanPhyNode->mgmtEpSet, colList, pTaskInfo, pSysScanPhyNode->showRewrite, pSysScanPhyNode->accountId); return pOperator; } else { ASSERT(0); } } int32_t type = nodeType(pPhyNode); size_t size = LIST_LENGTH(pPhyNode->pChildren); ASSERT(size == 1); SPhysiNode* pChildNode = (SPhysiNode*)nodesListGetNode(pPhyNode->pChildren, 0); SOperatorInfo* op = createOperatorTree(pChildNode, pTaskInfo, pHandle, queryId, taskId, pTableGroupInfo); if (QUERY_NODE_PHYSICAL_PLAN_PROJECT == type) { int32_t num = 0; SProjectPhysiNode* pProjPhyNode = (SProjectPhysiNode*) pPhyNode; SExprInfo* pExprInfo = createExprInfo(pProjPhyNode->pProjections, NULL, &num); SSDataBlock* pResBlock = createOutputBuf_rv1(pPhyNode->pOutputDataBlockDesc); SLimit limit = {.limit = pProjPhyNode->limit, .offset = pProjPhyNode->offset}; return createProjectOperatorInfo(op, pExprInfo, num, pResBlock, &limit, pTaskInfo); } else if (QUERY_NODE_PHYSICAL_PLAN_AGG == type) { int32_t num = 0; SAggPhysiNode* pAggNode = (SAggPhysiNode*)pPhyNode; SExprInfo* pExprInfo = createExprInfo(pAggNode->pAggFuncs, pAggNode->pGroupKeys, &num); SSDataBlock* pResBlock = createOutputBuf_rv1(pPhyNode->pOutputDataBlockDesc); if (pAggNode->pGroupKeys != NULL) { SArray* pColList = extractColumnInfo(pAggNode->pGroupKeys); return createGroupOperatorInfo(op, pExprInfo, num, pResBlock, pColList, pAggNode->node.pConditions, pTaskInfo, NULL); } else { return createAggregateOperatorInfo(op, pExprInfo, num, pResBlock, pTaskInfo, pTableGroupInfo); } } else if (QUERY_NODE_PHYSICAL_PLAN_INTERVAL == type) { SIntervalPhysiNode* pIntervalPhyNode = (SIntervalPhysiNode*)pPhyNode; int32_t num = 0; SExprInfo* pExprInfo = createExprInfo(pIntervalPhyNode->window.pFuncs, NULL, &num); SSDataBlock* pResBlock = createOutputBuf_rv1(pPhyNode->pOutputDataBlockDesc); SInterval interval = { .interval = pIntervalPhyNode->interval, .sliding = pIntervalPhyNode->sliding, .intervalUnit = pIntervalPhyNode->intervalUnit, .slidingUnit = pIntervalPhyNode->slidingUnit, .offset = pIntervalPhyNode->offset, .precision = pIntervalPhyNode->precision }; int32_t primaryTsSlotId = ((SColumnNode*) pIntervalPhyNode->pTspk)->slotId; return createIntervalOperatorInfo(op, pExprInfo, num, pResBlock, &interval, primaryTsSlotId, pTableGroupInfo, pTaskInfo); } else if (QUERY_NODE_PHYSICAL_PLAN_SORT == type) { SSortPhysiNode* pSortPhyNode = (SSortPhysiNode*)pPhyNode; SSDataBlock* pResBlock = createOutputBuf_rv1(pPhyNode->pOutputDataBlockDesc); SArray* info = createSortInfo(pSortPhyNode->pSortKeys); return createSortOperatorInfo(op, pResBlock, info, pTaskInfo); } else if (QUERY_NODE_PHYSICAL_PLAN_SESSION_WINDOW == type) { SSessionWinodwPhysiNode* pSessionNode = (SSessionWinodwPhysiNode*)pPhyNode; int32_t num = 0; SExprInfo* pExprInfo = createExprInfo(pSessionNode->window.pFuncs, NULL, &num); SSDataBlock* pResBlock = createOutputBuf_rv1(pPhyNode->pOutputDataBlockDesc); return createSessionAggOperatorInfo(op, pExprInfo, num, pResBlock, pSessionNode->gap, pTaskInfo); } else if (QUERY_NODE_PHYSICAL_PLAN_PARTITION == type) { SPartitionPhysiNode* pPartNode = (SPartitionPhysiNode*) pPhyNode; SArray* pColList = extractColumnInfo(pPartNode->pPartitionKeys); SSDataBlock* pResBlock = createOutputBuf_rv1(pPhyNode->pOutputDataBlockDesc); return createPartitionOperatorInfo(op, pResBlock, pColList, pTaskInfo, NULL); } else { ASSERT(0); } /*else if (pPhyNode->info.type == OP_MultiTableAggregate) { size_t size = taosArrayGetSize(pPhyNode->pChildren); assert(size == 1); for (int32_t i = 0; i < size; ++i) { SPhysiNode* pChildNode = taosArrayGetP(pPhyNode->pChildren, i); SOperatorInfo* op = createOperatorTree(pChildNode, pTaskInfo, pHandle, queryId, taskId, pTableGroupInfo); return createMultiTableAggOperatorInfo(op, pPhyNode->pTargets, pTaskInfo, pTableGroupInfo); } }*/ } static tsdbReaderT createDataReaderImpl(STableScanPhysiNode* pTableScanNode, STableGroupInfo* pGroupInfo, void* readHandle, uint64_t queryId, uint64_t taskId) { STsdbQueryCond cond = {.loadExternalRows = false}; cond.order = pTableScanNode->scan.order; cond.numOfCols = LIST_LENGTH(pTableScanNode->scan.pScanCols); cond.colList = taosMemoryCalloc(cond.numOfCols, sizeof(SColumnInfo)); if (cond.colList == NULL) { terrno = TSDB_CODE_QRY_OUT_OF_MEMORY; return NULL; } cond.twindow = pTableScanNode->scanRange; cond.type = BLOCK_LOAD_OFFSET_SEQ_ORDER; // cond.type = pTableScanNode->scanFlag; int32_t j = 0; for (int32_t i = 0; i < cond.numOfCols; ++i) { STargetNode* pNode = (STargetNode*)nodesListGetNode(pTableScanNode->scan.pScanCols, i); SColumnNode* pColNode = (SColumnNode*)pNode->pExpr; if (pColNode->colType == COLUMN_TYPE_TAG) { continue; } cond.colList[j].type = pColNode->node.resType.type; cond.colList[j].bytes = pColNode->node.resType.bytes; cond.colList[j].colId = pColNode->colId; j += 1; } cond.numOfCols = j; return tsdbQueryTables(readHandle, &cond, pGroupInfo, queryId, taskId); } SArray* extractScanColumnId(SNodeList* pNodeList) { size_t numOfCols = LIST_LENGTH(pNodeList); SArray* pList = taosArrayInit(numOfCols, sizeof(int16_t)); if (pList == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } for (int32_t i = 0; i < numOfCols; ++i) { for (int32_t j = 0; j < numOfCols; ++j) { STargetNode* pNode = (STargetNode*)nodesListGetNode(pNodeList, j); if (pNode->slotId == i) { SColumnNode* pColNode = (SColumnNode*)pNode->pExpr; taosArrayPush(pList, &pColNode->colId); break; } } } return pList; } SArray* extractColumnInfo(SNodeList* pNodeList) { size_t numOfCols = LIST_LENGTH(pNodeList); SArray* pList = taosArrayInit(numOfCols, sizeof(SColumn)); if (pList == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } for (int32_t i = 0; i < numOfCols; ++i) { STargetNode* pNode = (STargetNode*)nodesListGetNode(pNodeList, i); SColumnNode* pColNode = (SColumnNode*)pNode->pExpr; // todo extract method SColumn c = {0}; c.slotId = pColNode->slotId; c.colId = pColNode->colId; c.type = pColNode->node.resType.type; c.bytes = pColNode->node.resType.bytes; c.precision = pColNode->node.resType.precision; c.scale = pColNode->node.resType.scale; taosArrayPush(pList, &c); } return pList; } SArray* createSortInfo(SNodeList* pNodeList) { size_t numOfCols = LIST_LENGTH(pNodeList); SArray* pList = taosArrayInit(numOfCols, sizeof(SBlockOrderInfo)); if (pList == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return pList; } for (int32_t i = 0; i < numOfCols; ++i) { STargetNode* pNode = (STargetNode*)nodesListGetNode(pNodeList, i); SOrderByExprNode* pSortKey = (SOrderByExprNode*)pNode->pExpr; SBlockOrderInfo bi = {0}; bi.order = (pSortKey->order == ORDER_ASC) ? TSDB_ORDER_ASC : TSDB_ORDER_DESC; bi.nullFirst = (pSortKey->nullOrder == NULL_ORDER_FIRST); SColumnNode* pColNode = (SColumnNode*)pSortKey->pExpr; bi.slotId = pColNode->slotId; taosArrayPush(pList, &bi); } return pList; } SArray* extractColMatchInfo(SNodeList* pNodeList, SDataBlockDescNode* pOutputNodeList, int32_t* numOfOutputCols) { size_t numOfCols = LIST_LENGTH(pNodeList); SArray* pList = taosArrayInit(numOfCols, sizeof(SColMatchInfo)); if (pList == NULL) { terrno = TSDB_CODE_OUT_OF_MEMORY; return NULL; } for (int32_t i = 0; i < numOfCols; ++i) { STargetNode* pNode = (STargetNode*)nodesListGetNode(pNodeList, i); SColumnNode* pColNode = (SColumnNode*)pNode->pExpr; SColMatchInfo c = {0}; c.colId = pColNode->colId; c.targetSlotId = pNode->slotId; c.output = true; taosArrayPush(pList, &c); } *numOfOutputCols = 0; int32_t num = LIST_LENGTH(pOutputNodeList->pSlots); for (int32_t i = 0; i < num; ++i) { SSlotDescNode* pNode = (SSlotDescNode*)nodesListGetNode(pOutputNodeList->pSlots, i); SColMatchInfo* info = taosArrayGet(pList, pNode->slotId); if (pNode->output) { (*numOfOutputCols) += 1; } else { info->output = false; } } return pList; } int32_t doCreateTableGroup(void* metaHandle, int32_t tableType, uint64_t tableUid, STableGroupInfo* pGroupInfo, uint64_t queryId, uint64_t taskId) { int32_t code = 0; if (tableType == TSDB_SUPER_TABLE) { code = tsdbQuerySTableByTagCond(metaHandle, tableUid, 0, NULL, 0, 0, NULL, pGroupInfo, NULL, 0, queryId, taskId); } else { // Create one table group. code = tsdbGetOneTableGroup(metaHandle, tableUid, 0, pGroupInfo); } return code; } SArray* extractTableIdList(const STableGroupInfo* pTableGroupInfo) { SArray* tableIdList = taosArrayInit(4, sizeof(uint64_t)); if (pTableGroupInfo->numOfTables > 0) { SArray* pa = taosArrayGetP(pTableGroupInfo->pGroupList, 0); ASSERT(taosArrayGetSize(pTableGroupInfo->pGroupList) == 1); // Transfer the Array of STableKeyInfo into uid list. size_t numOfTables = taosArrayGetSize(pa); for (int32_t i = 0; i < numOfTables; ++i) { STableKeyInfo* pkeyInfo = taosArrayGet(pa, i); taosArrayPush(tableIdList, &pkeyInfo->uid); } } return tableIdList; } tsdbReaderT doCreateDataReader(STableScanPhysiNode* pTableScanNode, SReadHandle* pHandle, STableGroupInfo* pTableGroupInfo, uint64_t queryId, uint64_t taskId) { uint64_t uid = pTableScanNode->scan.uid; int32_t code = doCreateTableGroup(pHandle->meta, pTableScanNode->scan.tableType, uid, pTableGroupInfo, queryId, taskId); if (code != TSDB_CODE_SUCCESS) { goto _error; } if (pTableGroupInfo->numOfTables == 0) { code = 0; qDebug("no table qualified for query, TID:0x%" PRIx64 ", QID:0x%" PRIx64, taskId, queryId); goto _error; } return createDataReaderImpl(pTableScanNode, pTableGroupInfo, pHandle->reader, queryId, taskId); _error: terrno = code; return NULL; } int32_t createExecTaskInfoImpl(SSubplan* pPlan, SExecTaskInfo** pTaskInfo, SReadHandle* pHandle, uint64_t taskId, EOPTR_EXEC_MODEL model) { uint64_t queryId = pPlan->id.queryId; int32_t code = TSDB_CODE_SUCCESS; *pTaskInfo = createExecTaskInfo(queryId, taskId, model); if (*pTaskInfo == NULL) { code = TSDB_CODE_QRY_OUT_OF_MEMORY; goto _complete; } STableGroupInfo group = {0}; (*pTaskInfo)->pRoot = createOperatorTree(pPlan->pNode, *pTaskInfo, pHandle, queryId, taskId, &group); if (NULL == (*pTaskInfo)->pRoot) { code = terrno; goto _complete; } if ((*pTaskInfo)->pRoot == NULL) { code = TSDB_CODE_QRY_OUT_OF_MEMORY; goto _complete; } return code; _complete: taosMemoryFreeClear(*pTaskInfo); terrno = code; return code; } static int32_t updateOutputBufForTopBotQuery(SQueriedTableInfo* pTableInfo, SColumnInfo* pTagCols, SExprInfo* pExprs, int32_t numOfOutput, int32_t tagLen, bool superTable) { for (int32_t i = 0; i < numOfOutput; ++i) { int16_t functId = getExprFunctionId(&pExprs[i]); if (functId == FUNCTION_TOP || functId == FUNCTION_BOTTOM) { int32_t j = getColumnIndexInSource(pTableInfo, &pExprs[i].base, pTagCols); if (j < 0 || j >= pTableInfo->numOfCols) { return TSDB_CODE_QRY_INVALID_MSG; } else { SColumnInfo* pCol = &pTableInfo->colList[j]; // int32_t ret = getResultDataInfo(pCol->type, pCol->bytes, functId, (int32_t)pExprs[i].base.param[0].i, // &pExprs[i].base.resSchema.type, &pExprs[i].base.resSchema.bytes, // &pExprs[i].base.interBytes, tagLen, superTable, NULL); // assert(ret == TSDB_CODE_SUCCESS); } } } return TSDB_CODE_SUCCESS; } void setResultBufSize(STaskAttr* pQueryAttr, SResultInfo* pResultInfo) { const int32_t DEFAULT_RESULT_MSG_SIZE = 1024 * (1024 + 512); // the minimum number of rows for projection query const int32_t MIN_ROWS_FOR_PRJ_QUERY = 8192; const int32_t DEFAULT_MIN_ROWS = 4096; const float THRESHOLD_RATIO = 0.85f; // if (isProjQuery(pQueryAttr)) { // int32_t numOfRes = DEFAULT_RESULT_MSG_SIZE / pQueryAttr->resultRowSize; // if (numOfRes < MIN_ROWS_FOR_PRJ_QUERY) { // numOfRes = MIN_ROWS_FOR_PRJ_QUERY; // } // // pResultInfo->capacity = numOfRes; // } else { // in case of non-prj query, a smaller output buffer will be used. // pResultInfo->capacity = DEFAULT_MIN_ROWS; // } pResultInfo->threshold = (int32_t)(pResultInfo->capacity * THRESHOLD_RATIO); pResultInfo->totalRows = 0; } // TODO refactor void freeColumnFilterInfo(SColumnFilterInfo* pFilter, int32_t numOfFilters) { if (pFilter == NULL || numOfFilters == 0) { return; } for (int32_t i = 0; i < numOfFilters; i++) { if (pFilter[i].filterstr && pFilter[i].pz) { taosMemoryFree((void*)(pFilter[i].pz)); } } taosMemoryFree(pFilter); } static void doDestroyTableQueryInfo(STableGroupInfo* pTableqinfoGroupInfo) { if (pTableqinfoGroupInfo->pGroupList != NULL) { int32_t numOfGroups = (int32_t)taosArrayGetSize(pTableqinfoGroupInfo->pGroupList); for (int32_t i = 0; i < numOfGroups; ++i) { SArray* p = taosArrayGetP(pTableqinfoGroupInfo->pGroupList, i); size_t num = taosArrayGetSize(p); for (int32_t j = 0; j < num; ++j) { STableQueryInfo* item = taosArrayGetP(p, j); destroyTableQueryInfoImpl(item); } taosArrayDestroy(p); } } taosArrayDestroy(pTableqinfoGroupInfo->pGroupList); taosHashCleanup(pTableqinfoGroupInfo->map); pTableqinfoGroupInfo->pGroupList = NULL; pTableqinfoGroupInfo->map = NULL; pTableqinfoGroupInfo->numOfTables = 0; } void doDestroyTask(SExecTaskInfo* pTaskInfo) { qDebug("%s execTask is freed", GET_TASKID(pTaskInfo)); doDestroyTableQueryInfo(&pTaskInfo->tableqinfoGroupInfo); // taosArrayDestroy(pTaskInfo->summary.queryProfEvents); // taosHashCleanup(pTaskInfo->summary.operatorProfResults); taosMemoryFreeClear(pTaskInfo->sql); taosMemoryFreeClear(pTaskInfo->id.str); taosMemoryFreeClear(pTaskInfo); } static void doSetTagValueToResultBuf(char* output, const char* val, int16_t type, int16_t bytes) { if (val == NULL) { setNull(output, type, bytes); return; } if (IS_VAR_DATA_TYPE(type)) { // Binary data overflows for sort of unknown reasons. Let trim the overflow data if (varDataTLen(val) > bytes) { int32_t maxLen = bytes - VARSTR_HEADER_SIZE; int32_t len = (varDataLen(val) > maxLen) ? maxLen : varDataLen(val); memcpy(varDataVal(output), varDataVal(val), len); varDataSetLen(output, len); } else { varDataCopy(output, val); } } else { memcpy(output, val, bytes); } } static int64_t getQuerySupportBufSize(size_t numOfTables) { size_t s1 = sizeof(STableQueryInfo); // size_t s3 = sizeof(STableCheckInfo); buffer consumption in tsdb return (int64_t)(s1 * 1.5 * numOfTables); } int32_t checkForQueryBuf(size_t numOfTables) { int64_t t = getQuerySupportBufSize(numOfTables); if (tsQueryBufferSizeBytes < 0) { return TSDB_CODE_SUCCESS; } else if (tsQueryBufferSizeBytes > 0) { while (1) { int64_t s = tsQueryBufferSizeBytes; int64_t remain = s - t; if (remain >= 0) { if (atomic_val_compare_exchange_64(&tsQueryBufferSizeBytes, s, remain) == s) { return TSDB_CODE_SUCCESS; } } else { return TSDB_CODE_QRY_NOT_ENOUGH_BUFFER; } } } // disable query processing if the value of tsQueryBufferSize is zero. return TSDB_CODE_QRY_NOT_ENOUGH_BUFFER; } void releaseQueryBuf(size_t numOfTables) { if (tsQueryBufferSizeBytes < 0) { return; } int64_t t = getQuerySupportBufSize(numOfTables); // restore value is not enough buffer available atomic_add_fetch_64(&tsQueryBufferSizeBytes, t); } int32_t getOperatorExplainExecInfo(SOperatorInfo *operatorInfo, SExplainExecInfo **pRes, int32_t *capacity, int32_t *resNum) { if (*resNum >= *capacity) { *capacity += 10; *pRes = taosMemoryRealloc(*pRes, (*capacity) * sizeof(SExplainExecInfo)); if (NULL == *pRes) { qError("malloc %d failed", (*capacity) * (int32_t)sizeof(SExplainExecInfo)); return TSDB_CODE_QRY_OUT_OF_MEMORY; } } (*pRes)[*resNum].numOfRows = operatorInfo->resultInfo.totalRows; (*pRes)[*resNum].startupCost = operatorInfo->cost.openCost; (*pRes)[*resNum].totalCost = operatorInfo->cost.totalCost; if (operatorInfo->getExplainFn) { int32_t code = (*operatorInfo->getExplainFn)(operatorInfo, &(*pRes)->verboseInfo); if (code) { qError("operator getExplainFn failed, error:%s", tstrerror(code)); return code; } } ++(*resNum); int32_t code = 0; for (int32_t i = 0; i < operatorInfo->numOfDownstream; ++i) { code = getOperatorExplainExecInfo(operatorInfo->pDownstream[i], pRes, capacity, resNum); if (code) { taosMemoryFreeClear(*pRes); return TSDB_CODE_QRY_OUT_OF_MEMORY; } } return TSDB_CODE_SUCCESS; }