/* * 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 . */ #ifndef _TD_PLANN_NODES_H_ #define _TD_PLANN_NODES_H_ #ifdef __cplusplus extern "C" { #endif #include "query.h" #include "querynodes.h" #include "tname.h" #define SLOT_NAME_LEN TSDB_TABLE_NAME_LEN + TSDB_COL_NAME_LEN typedef enum EDataOrderLevel { DATA_ORDER_LEVEL_NONE = 1, DATA_ORDER_LEVEL_IN_BLOCK, DATA_ORDER_LEVEL_IN_GROUP, DATA_ORDER_LEVEL_GLOBAL } EDataOrderLevel; typedef enum EGroupAction { GROUP_ACTION_NONE = 1, GROUP_ACTION_SET, GROUP_ACTION_KEEP, GROUP_ACTION_CLEAR } EGroupAction; typedef struct SLogicNode { ENodeType type; SNodeList* pTargets; // SColumnNode SNode* pConditions; SNodeList* pChildren; struct SLogicNode* pParent; int32_t optimizedFlag; uint8_t precision; SNode* pLimit; SNode* pSlimit; EDataOrderLevel requireDataOrder; // requirements for input data EDataOrderLevel resultDataOrder; // properties of the output data EGroupAction groupAction; } SLogicNode; typedef enum EScanType { SCAN_TYPE_TAG = 1, SCAN_TYPE_TABLE, SCAN_TYPE_SYSTEM_TABLE, SCAN_TYPE_STREAM, SCAN_TYPE_TABLE_MERGE, SCAN_TYPE_BLOCK_INFO, SCAN_TYPE_LAST_ROW } EScanType; typedef struct SScanLogicNode { SLogicNode node; SNodeList* pScanCols; SNodeList* pScanPseudoCols; int8_t tableType; uint64_t tableId; uint64_t stableId; SVgroupsInfo* pVgroupList; EScanType scanType; uint8_t scanSeq[2]; // first is scan count, and second is reverse scan count STimeWindow scanRange; SName tableName; bool showRewrite; double ratio; SNodeList* pDynamicScanFuncs; int32_t dataRequired; int64_t interval; int64_t offset; int64_t sliding; int8_t intervalUnit; int8_t slidingUnit; SNode* pTagCond; SNode* pTagIndexCond; int8_t triggerType; int64_t watermark; int8_t igExpired; SArray* pSmaIndexes; SNodeList* pGroupTags; bool groupSort; int8_t cacheLastMode; bool hasNormalCols; // neither tag column nor primary key tag column bool sortPrimaryKey; } SScanLogicNode; typedef struct SJoinLogicNode { SLogicNode node; EJoinType joinType; SNode* pMergeCondition; SNode* pOnConditions; bool isSingleTableJoin; EOrder inputTsOrder; } SJoinLogicNode; typedef struct SAggLogicNode { SLogicNode node; SNodeList* pGroupKeys; SNodeList* pAggFuncs; bool hasLastRow; bool hasTimeLineFunc; bool onlyHasKeepOrderFunc; } SAggLogicNode; typedef struct SProjectLogicNode { SLogicNode node; SNodeList* pProjections; char stmtName[TSDB_TABLE_NAME_LEN]; bool ignoreGroupId; } SProjectLogicNode; typedef struct SIndefRowsFuncLogicNode { SLogicNode node; SNodeList* pFuncs; bool isTailFunc; bool isUniqueFunc; bool isTimeLineFunc; } SIndefRowsFuncLogicNode; typedef struct SInterpFuncLogicNode { SLogicNode node; SNodeList* pFuncs; STimeWindow timeRange; int64_t interval; EFillMode fillMode; SNode* pFillValues; // SNodeListNode SNode* pTimeSeries; // SColumnNode } SInterpFuncLogicNode; typedef enum EModifyTableType { MODIFY_TABLE_TYPE_INSERT = 1, MODIFY_TABLE_TYPE_DELETE } EModifyTableType; typedef struct SVnodeModifyLogicNode { SLogicNode node; EModifyTableType modifyType; int32_t msgType; SArray* pDataBlocks; SVgDataBlocks* pVgDataBlocks; SNode* pAffectedRows; // SColumnNode SNode* pStartTs; // SColumnNode SNode* pEndTs; // SColumnNode uint64_t tableId; uint64_t stableId; int8_t tableType; // table type char tableName[TSDB_TABLE_NAME_LEN]; char tsColName[TSDB_COL_NAME_LEN]; STimeWindow deleteTimeRange; SVgroupsInfo* pVgroupList; SNodeList* pInsertCols; } SVnodeModifyLogicNode; typedef struct SExchangeLogicNode { SLogicNode node; int32_t srcGroupId; } SExchangeLogicNode; typedef struct SMergeLogicNode { SLogicNode node; SNodeList* pMergeKeys; SNodeList* pInputs; int32_t numOfChannels; int32_t srcGroupId; bool groupSort; } SMergeLogicNode; typedef enum EWindowType { WINDOW_TYPE_INTERVAL = 1, WINDOW_TYPE_SESSION, WINDOW_TYPE_STATE } EWindowType; typedef enum EWindowAlgorithm { INTERVAL_ALGO_HASH = 1, INTERVAL_ALGO_MERGE, INTERVAL_ALGO_STREAM_FINAL, INTERVAL_ALGO_STREAM_SEMI, INTERVAL_ALGO_STREAM_SINGLE, SESSION_ALGO_STREAM_SEMI, SESSION_ALGO_STREAM_FINAL, SESSION_ALGO_STREAM_SINGLE, SESSION_ALGO_MERGE, } EWindowAlgorithm; typedef struct SWindowLogicNode { SLogicNode node; EWindowType winType; SNodeList* pFuncs; int64_t interval; int64_t offset; int64_t sliding; int8_t intervalUnit; int8_t slidingUnit; int64_t sessionGap; SNode* pTspk; SNode* pTsEnd; SNode* pStateExpr; int8_t triggerType; int64_t watermark; int8_t igExpired; EWindowAlgorithm windowAlgo; EOrder inputTsOrder; EOrder outputTsOrder; } SWindowLogicNode; typedef struct SFillLogicNode { SLogicNode node; EFillMode mode; SNodeList* pFillExprs; SNodeList* pNotFillExprs; SNode* pWStartTs; SNode* pValues; // SNodeListNode STimeWindow timeRange; EOrder inputTsOrder; } SFillLogicNode; typedef struct SSortLogicNode { SLogicNode node; SNodeList* pSortKeys; bool groupSort; } SSortLogicNode; typedef struct SPartitionLogicNode { SLogicNode node; SNodeList* pPartitionKeys; } SPartitionLogicNode; typedef enum ESubplanType { SUBPLAN_TYPE_MERGE = 1, SUBPLAN_TYPE_PARTIAL, SUBPLAN_TYPE_SCAN, SUBPLAN_TYPE_MODIFY, SUBPLAN_TYPE_COMPUTE } ESubplanType; typedef struct SSubplanId { uint64_t queryId; int32_t groupId; int32_t subplanId; } SSubplanId; typedef struct SLogicSubplan { ENodeType type; SSubplanId id; SNodeList* pChildren; SNodeList* pParents; SLogicNode* pNode; ESubplanType subplanType; SVgroupsInfo* pVgroupList; int32_t level; int32_t splitFlag; int32_t numOfComputeNodes; } SLogicSubplan; typedef struct SQueryLogicPlan { ENodeType type; SNodeList* pTopSubplans; } SQueryLogicPlan; typedef struct SSlotDescNode { ENodeType type; int16_t slotId; SDataType dataType; bool reserve; bool output; bool tag; char name[SLOT_NAME_LEN]; } SSlotDescNode; typedef struct SDataBlockDescNode { ENodeType type; int16_t dataBlockId; SNodeList* pSlots; int32_t totalRowSize; int32_t outputRowSize; uint8_t precision; } SDataBlockDescNode; typedef struct SPhysiNode { ENodeType type; SDataBlockDescNode* pOutputDataBlockDesc; SNode* pConditions; SNodeList* pChildren; struct SPhysiNode* pParent; SNode* pLimit; SNode* pSlimit; } SPhysiNode; typedef struct SScanPhysiNode { SPhysiNode node; SNodeList* pScanCols; SNodeList* pScanPseudoCols; uint64_t uid; // unique id of the table uint64_t suid; int8_t tableType; SName tableName; } SScanPhysiNode; typedef SScanPhysiNode STagScanPhysiNode; typedef SScanPhysiNode SBlockDistScanPhysiNode; typedef struct SLastRowScanPhysiNode { SScanPhysiNode scan; SNodeList* pGroupTags; bool groupSort; } SLastRowScanPhysiNode; typedef struct SSystemTableScanPhysiNode { SScanPhysiNode scan; SEpSet mgmtEpSet; bool showRewrite; int32_t accountId; bool sysInfo; } SSystemTableScanPhysiNode; typedef struct STableScanPhysiNode { SScanPhysiNode scan; uint8_t scanSeq[2]; // first is scan count, and second is reverse scan count STimeWindow scanRange; double ratio; int32_t dataRequired; SNodeList* pDynamicScanFuncs; SNodeList* pGroupTags; bool groupSort; int64_t interval; int64_t offset; int64_t sliding; int8_t intervalUnit; int8_t slidingUnit; int8_t triggerType; int64_t watermark; int8_t igExpired; bool assignBlockUid; } STableScanPhysiNode; typedef STableScanPhysiNode STableSeqScanPhysiNode; typedef STableScanPhysiNode STableMergeScanPhysiNode; typedef STableScanPhysiNode SStreamScanPhysiNode; typedef struct SProjectPhysiNode { SPhysiNode node; SNodeList* pProjections; bool mergeDataBlock; bool ignoreGroupId; } SProjectPhysiNode; typedef struct SIndefRowsFuncPhysiNode { SPhysiNode node; SNodeList* pExprs; SNodeList* pFuncs; } SIndefRowsFuncPhysiNode; typedef struct SInterpFuncPhysiNode { SPhysiNode node; SNodeList* pExprs; SNodeList* pFuncs; STimeWindow timeRange; int64_t interval; int8_t intervalUnit; EFillMode fillMode; SNode* pFillValues; // SNodeListNode SNode* pTimeSeries; // SColumnNode } SInterpFuncPhysiNode; typedef struct SSortMergeJoinPhysiNode { SPhysiNode node; EJoinType joinType; SNode* pMergeCondition; SNode* pOnConditions; SNodeList* pTargets; EOrder inputTsOrder; } SSortMergeJoinPhysiNode; typedef struct SAggPhysiNode { SPhysiNode node; SNodeList* pExprs; // these are expression list of group_by_clause and parameter expression of aggregate function SNodeList* pGroupKeys; SNodeList* pAggFuncs; bool mergeDataBlock; } SAggPhysiNode; typedef struct SDownstreamSourceNode { ENodeType type; SQueryNodeAddr addr; uint64_t taskId; uint64_t schedId; int32_t execId; int32_t fetchMsgType; } SDownstreamSourceNode; typedef struct SExchangePhysiNode { SPhysiNode node; int32_t srcGroupId; // group id of datasource suplans bool singleChannel; SNodeList* pSrcEndPoints; // element is SDownstreamSource, scheduler fill by calling qSetSuplanExecutionNode } SExchangePhysiNode; typedef struct SMergePhysiNode { SPhysiNode node; SNodeList* pMergeKeys; SNodeList* pTargets; int32_t numOfChannels; int32_t srcGroupId; bool groupSort; } SMergePhysiNode; typedef struct SWinodwPhysiNode { SPhysiNode node; SNodeList* pExprs; // these are expression list of parameter expression of function SNodeList* pFuncs; SNode* pTspk; // timestamp primary key SNode* pTsEnd; // window end timestamp int8_t triggerType; int64_t watermark; int8_t igExpired; EOrder inputTsOrder; EOrder outputTsOrder; bool mergeDataBlock; } SWinodwPhysiNode; typedef struct SIntervalPhysiNode { SWinodwPhysiNode window; int64_t interval; int64_t offset; int64_t sliding; int8_t intervalUnit; int8_t slidingUnit; } SIntervalPhysiNode; typedef SIntervalPhysiNode SMergeIntervalPhysiNode; typedef SIntervalPhysiNode SMergeAlignedIntervalPhysiNode; typedef SIntervalPhysiNode SStreamIntervalPhysiNode; typedef SIntervalPhysiNode SStreamFinalIntervalPhysiNode; typedef SIntervalPhysiNode SStreamSemiIntervalPhysiNode; typedef struct SFillPhysiNode { SPhysiNode node; EFillMode mode; SNodeList* pFillExprs; SNodeList* pNotFillExprs; SNode* pWStartTs; // SColumnNode SNode* pValues; // SNodeListNode STimeWindow timeRange; EOrder inputTsOrder; } SFillPhysiNode; typedef struct SMultiTableIntervalPhysiNode { SIntervalPhysiNode interval; SNodeList* pPartitionKeys; } SMultiTableIntervalPhysiNode; typedef struct SSessionWinodwPhysiNode { SWinodwPhysiNode window; int64_t gap; } SSessionWinodwPhysiNode; typedef SSessionWinodwPhysiNode SStreamSessionWinodwPhysiNode; typedef SSessionWinodwPhysiNode SStreamSemiSessionWinodwPhysiNode; typedef SSessionWinodwPhysiNode SStreamFinalSessionWinodwPhysiNode; typedef struct SStateWinodwPhysiNode { SWinodwPhysiNode window; SNode* pStateKey; } SStateWinodwPhysiNode; typedef SStateWinodwPhysiNode SStreamStateWinodwPhysiNode; typedef struct SSortPhysiNode { SPhysiNode node; SNodeList* pExprs; // these are expression list of order_by_clause and parameter expression of aggregate function SNodeList* pSortKeys; // element is SOrderByExprNode, and SOrderByExprNode::pExpr is SColumnNode SNodeList* pTargets; } SSortPhysiNode; typedef SSortPhysiNode SGroupSortPhysiNode; typedef struct SPartitionPhysiNode { SPhysiNode node; SNodeList* pExprs; // these are expression list of partition_by_clause SNodeList* pPartitionKeys; SNodeList* pTargets; } SPartitionPhysiNode; typedef SPartitionPhysiNode SStreamPartitionPhysiNode; typedef struct SDataSinkNode { ENodeType type; SDataBlockDescNode* pInputDataBlockDesc; } SDataSinkNode; typedef struct SDataDispatcherNode { SDataSinkNode sink; } SDataDispatcherNode; typedef struct SDataInserterNode { SDataSinkNode sink; int32_t numOfTables; uint32_t size; char* pData; } SDataInserterNode; typedef struct SQueryInserterNode { SDataSinkNode sink; SNodeList* pCols; uint64_t tableId; uint64_t stableId; int8_t tableType; // table type char tableName[TSDB_TABLE_NAME_LEN]; int32_t vgId; SEpSet epSet; } SQueryInserterNode; typedef struct SDataDeleterNode { SDataSinkNode sink; uint64_t tableId; int8_t tableType; // table type char tableFName[TSDB_TABLE_NAME_LEN]; char tsColName[TSDB_COL_NAME_LEN]; STimeWindow deleteTimeRange; SNode* pAffectedRows; SNode* pStartTs; SNode* pEndTs; } SDataDeleterNode; typedef struct SSubplan { ENodeType type; SSubplanId id; // unique id of the subplan ESubplanType subplanType; int32_t msgType; // message type for subplan, used to denote the send message type to vnode. int32_t level; // the execution level of current subplan, starting from 0 in a top-down manner. char dbFName[TSDB_DB_FNAME_LEN]; char user[TSDB_USER_LEN]; SQueryNodeAddr execNode; // for the scan/modify subplan, the optional execution node SQueryNodeStat execNodeStat; // only for scan subplan SNodeList* pChildren; // the datasource subplan,from which to fetch the result SNodeList* pParents; // the data destination subplan, get data from current subplan SPhysiNode* pNode; // physical plan of current subplan SDataSinkNode* pDataSink; // data of the subplan flow into the datasink SNode* pTagCond; SNode* pTagIndexCond; } SSubplan; typedef enum EExplainMode { EXPLAIN_MODE_DISABLE = 1, EXPLAIN_MODE_STATIC, EXPLAIN_MODE_ANALYZE } EExplainMode; typedef struct SExplainInfo { EExplainMode mode; bool verbose; double ratio; } SExplainInfo; typedef struct SQueryPlan { ENodeType type; uint64_t queryId; int32_t numOfSubplans; SNodeList* pSubplans; // Element is SNodeListNode. The execution level of subplan, starting from 0. SExplainInfo explainInfo; } SQueryPlan; void nodesWalkPhysiPlan(SNode* pNode, FNodeWalker walker, void* pContext); const char* dataOrderStr(EDataOrderLevel order); #ifdef __cplusplus } #endif #endif /*_TD_PLANN_NODES_H_*/