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/*-------------------------------------------------------------------------
*
* execnodes.h
* definitions for executor state nodes
* Portions Copyright (c) 1996-2004, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
* $PostgreSQL: pgsql/src/include/nodes/execnodes.h,v 1.118 2004/08/29 04:13:07 momjian Exp $
*
*-------------------------------------------------------------------------
*/
#ifndef EXECNODES_H
#define EXECNODES_H
#include "access/relscan.h"
#include "executor/tuptable.h"
#include "fmgr.h"
#include "nodes/bitmapset.h"
#include "nodes/plannodes.h"
#include "utils/hsearch.h"
#include "utils/tuplestore.h"
* IndexInfo information
* this struct holds the information needed to construct new index
* entries for a particular index. Used for both index_build and
* retail creation of index entries.
* NumIndexAttrs number of columns in this index
* KeyAttrNumbers underlying-rel attribute numbers used as keys
* (zeroes indicate expressions)
* Expressions expr trees for expression entries, or NIL if none
* ExpressionsState exec state for expressions, or NIL if none
* Predicate partial-index predicate, or NIL if none
* PredicateState exec state for predicate, or NIL if none
* Unique is it a unique index?
typedef struct IndexInfo
{
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NodeTag type;
int ii_NumIndexAttrs;
AttrNumber ii_KeyAttrNumbers[INDEX_MAX_KEYS];
List *ii_Expressions; /* list of Expr */
List *ii_ExpressionsState; /* list of ExprState */
List *ii_Predicate; /* list of Expr */
bool ii_Unique;
} IndexInfo;
/* ----------------
* ExprContext_CB
*
* List of callbacks to be called at ExprContext shutdown.
* ----------------
*/
typedef void (*ExprContextCallbackFunction) (Datum arg);
typedef struct ExprContext_CB
{
struct ExprContext_CB *next;
ExprContextCallbackFunction function;
Datum arg;
} ExprContext_CB;
* ExprContext
*
* This class holds the "current context" information
* needed to evaluate expressions for doing tuple qualifications
* and tuple projections. For example, if an expression refers
* to an attribute in the current inner tuple then we need to know
* what the current inner tuple is and so we look at the expression
* context.
*
* There are two memory contexts associated with an ExprContext:
* * ecxt_per_query_memory is a query-lifespan context, typically the same
* context the ExprContext node itself is allocated in. This context
* can be used for purposes such as storing function call cache info.
* * ecxt_per_tuple_memory is a short-term context for expression results.
* As the name suggests, it will typically be reset once per tuple,
* before we begin to evaluate expressions for that tuple. Each
* ExprContext normally has its very own per-tuple memory context.
* CurrentMemoryContext should be set to ecxt_per_tuple_memory before
* calling ExecEvalExpr() --- see ExecEvalExprSwitchContext().
typedef struct ExprContext
{
/* Tuples that Var nodes in expression may refer to */
TupleTableSlot *ecxt_scantuple;
TupleTableSlot *ecxt_innertuple;
TupleTableSlot *ecxt_outertuple;
/* Memory contexts for expression evaluation --- see notes above */
MemoryContext ecxt_per_query_memory;
MemoryContext ecxt_per_tuple_memory;
/* Values to substitute for Param nodes in expression */
ParamExecData *ecxt_param_exec_vals; /* for PARAM_EXEC params */
ParamListInfo ecxt_param_list_info; /* for other param types */
/* Values to substitute for Aggref nodes in expression */
Datum *ecxt_aggvalues; /* precomputed values for Aggref nodes */
bool *ecxt_aggnulls; /* null flags for Aggref nodes */
/* Value to substitute for CaseTestExpr nodes in expression */
Datum caseValue_datum;
bool caseValue_isNull;
/* Value to substitute for CoerceToDomainValue nodes in expression */
Datum domainValue_datum;
bool domainValue_isNull;
/* Link to containing EState */
struct EState *ecxt_estate;
/* Functions to call back when ExprContext is shut down */
ExprContext_CB *ecxt_callbacks;
} ExprContext;
/*
* Set-result status returned by ExecEvalExpr()
*/
typedef enum
{
ExprSingleResult, /* expression does not return a set */
ExprMultipleResult, /* this result is an element of a set */
ExprEndResult /* there are no more elements in the set */
} ExprDoneCond;
/*
* Return modes for functions returning sets. Note values must be chosen
* as separate bits so that a bitmask can be formed to indicate supported
* modes.
*/
typedef enum
{
SFRM_ValuePerCall = 0x01, /* one value returned per call */
SFRM_Materialize = 0x02 /* result set instantiated in Tuplestore */
} SetFunctionReturnMode;
/*
* When calling a function that might return a set (multiple rows),
* a node of this type is passed as fcinfo->resultinfo to allow
* return status to be passed back. A function returning set should
* raise an error if no such resultinfo is provided.
*/
typedef struct ReturnSetInfo
{
NodeTag type;
/* values set by caller: */
ExprContext *econtext; /* context function is being called in */
TupleDesc expectedDesc; /* tuple descriptor expected by caller */
int allowedModes; /* bitmask: return modes caller can handle */
/* result status from function (but pre-initialized by caller): */
SetFunctionReturnMode returnMode; /* actual return mode */
ExprDoneCond isDone; /* status for ValuePerCall mode */
/* fields filled by function in Materialize return mode: */
Tuplestorestate *setResult; /* holds the complete returned tuple set */
TupleDesc setDesc; /* actual descriptor for returned tuples */
} ReturnSetInfo;
* ProjectionInfo node information
*
* This is all the information needed to perform projections ---
* that is, form new tuples by evaluation of targetlist expressions.
* Nodes which need to do projections create one of these.
* In theory, when a node wants to perform a projection
* it should just update this information as necessary and then
* call ExecProject(). -cim 6/3/91
*
* ExecProject() evaluates the tlist, forms a tuple, and stores it
* in the given slot. As a side-effect, the actual datum values and
* null indicators are placed in the work arrays tupValues/tupNulls.
*
* targetlist target list for projection
* exprContext expression context in which to evaluate targetlist
* slot slot to place projection result in
* tupValues array of computed values
* tupNull array of null indicators
* itemIsDone workspace for ExecProject
typedef struct ProjectionInfo
{
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NodeTag type;
List *pi_targetlist;
ExprContext *pi_exprContext;
TupleTableSlot *pi_slot;
Datum *pi_tupValues;
char *pi_tupNulls;
ExprDoneCond *pi_itemIsDone;
} ProjectionInfo;
* JunkFilter
*
* This class is used to store information regarding junk attributes.
* A junk attribute is an attribute in a tuple that is needed only for
* storing intermediate information in the executor, and does not belong
* in emitted tuples. For example, when we do an UPDATE query,
* the planner adds a "junk" entry to the targetlist so that the tuples
* returned to ExecutePlan() contain an extra attribute: the ctid of
* the tuple to be updated. This is needed to do the update, but we
* don't want the ctid to be part of the stored new tuple! So, we
* apply a "junk filter" to remove the junk attributes and form the
* real output tuple.
*
* targetList: the original target list (including junk attributes).
* length: the length of 'targetList'.
* tupType: the tuple descriptor for the "original" tuple
* (including the junk attributes).
* cleanTargetList: the "clean" target list (junk attributes removed).
* cleanLength: the length of 'cleanTargetList'
* cleanTupType: the tuple descriptor of the "clean" tuple (with
* junk attributes removed).
* cleanMap: A map with the correspondence between the non-junk
* attribute numbers of the "original" tuple and the
* attribute numbers of the "clean" tuple.
* resultSlot: tuple slot that can be used to hold cleaned tuple.
typedef struct JunkFilter
{
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NodeTag type;
List *jf_targetList;
int jf_length;
TupleDesc jf_tupType;
List *jf_cleanTargetList;
int jf_cleanLength;
TupleDesc jf_cleanTupType;
AttrNumber *jf_cleanMap;
TupleTableSlot *jf_resultSlot;
} JunkFilter;
/* ----------------
* ResultRelInfo information
*
* Whenever we update an existing relation, we have to
* update indices on the relation, and perhaps also fire triggers.
* The ResultRelInfo class is used to hold all the information needed
* about a result relation, including indices.. -cim 10/15/89
*
* RangeTableIndex result relation's range table index
* RelationDesc relation descriptor for result relation
* NumIndices # of indices existing on result relation
* IndexRelationDescs array of relation descriptors for indices
* IndexRelationInfo array of key/attr info for indices
* TrigDesc triggers to be fired, if any
* TrigFunctions cached lookup info for trigger functions
* ConstraintExprs array of constraint-checking expr states
* junkFilter for removing junk attributes from tuples
* ----------------
*/
typedef struct ResultRelInfo
{
NodeTag type;
Index ri_RangeTableIndex;
Relation ri_RelationDesc;
int ri_NumIndices;
RelationPtr ri_IndexRelationDescs;
IndexInfo **ri_IndexRelationInfo;
TriggerDesc *ri_TrigDesc;
FmgrInfo *ri_TrigFunctions;
List **ri_ConstraintExprs;
JunkFilter *ri_junkFilter;
} ResultRelInfo;
* EState information
* Master working state for an Executor invocation
* ----------------
typedef struct EState
{
/* Basic state for all query types: */
Snapshot es_snapshot; /* time qual to use */
Snapshot es_crosscheck_snapshot; /* crosscheck time qual for RI */
/* Info about target table for insert/update/delete queries: */
ResultRelInfo *es_result_relations; /* array of ResultRelInfos */
int es_num_result_relations; /* length of array */
ResultRelInfo *es_result_relation_info; /* currently active array
* elt */
JunkFilter *es_junkFilter; /* currently active junk filter */
Relation es_into_relation_descriptor; /* for SELECT INTO */
/* Parameter info: */
ParamListInfo es_param_list_info; /* values of external params */
ParamExecData *es_param_exec_vals; /* values of internal params */
/* Other working state: */
MemoryContext es_query_cxt; /* per-query context in which EState lives */
TupleTable es_tupleTable; /* Array of TupleTableSlots */
uint32 es_processed; /* # of tuples processed */
Oid es_lastoid; /* last oid processed (by INSERT) */
List *es_rowMark; /* not good place, but there is no other */
bool es_instrument; /* true requests runtime instrumentation */
bool es_select_into; /* true if doing SELECT INTO */
bool es_into_oids; /* true to generate OIDs in SELECT INTO */
List *es_exprcontexts; /* List of ExprContexts within EState */
/*
* this ExprContext is for per-output-tuple operations, such as
* constraint checks and index-value computations. It will be reset
* for each output tuple. Note that it will be created only if
* needed.
*/
ExprContext *es_per_tuple_exprcontext;
/* Below is to re-evaluate plan qual in READ COMMITTED mode */
Plan *es_topPlan; /* link to top of plan tree */
struct evalPlanQual *es_evalPlanQual; /* chain of PlanQual
* states */
bool *es_evTupleNull; /* local array of EPQ status */
HeapTuple *es_evTuple; /* shared array of EPQ substitute tuples */
} EState;
/* ----------------------------------------------------------------
* Tuple Hash Tables
*
* All-in-memory tuple hash tables are used for a number of purposes.
* ----------------------------------------------------------------
*/
typedef struct TupleHashEntryData *TupleHashEntry;
typedef struct TupleHashTableData *TupleHashTable;
typedef struct TupleHashEntryData
{
/* firstTuple must be the first field in this struct! */
HeapTuple firstTuple; /* copy of first tuple in this group */
/* there may be additional data beyond the end of this struct */
} TupleHashEntryData; /* VARIABLE LENGTH STRUCT */
typedef struct TupleHashTableData
{
HTAB *hashtab; /* underlying dynahash table */
int numCols; /* number of columns in lookup key */
AttrNumber *keyColIdx; /* attr numbers of key columns */
FmgrInfo *eqfunctions; /* lookup data for comparison functions */
FmgrInfo *hashfunctions; /* lookup data for hash functions */
MemoryContext tablecxt; /* memory context containing table */
MemoryContext tempcxt; /* context for function evaluations */
Size entrysize; /* actual size to make each hash entry */
TupleDesc tupdesc; /* tuple descriptor */
} TupleHashTableData;
typedef HASH_SEQ_STATUS TupleHashIterator;
#define ResetTupleHashIterator(htable, iter) \
hash_seq_init(iter, (htable)->hashtab)
#define ScanTupleHashTable(iter) \
((TupleHashEntry) hash_seq_search(iter))
/* ----------------------------------------------------------------
* Expression State Trees
*
* Each executable expression tree has a parallel ExprState tree.
*
* Unlike PlanState, there is not an exact one-for-one correspondence between
* ExprState node types and Expr node types. Many Expr node types have no
* need for node-type-specific run-time state, and so they can use plain
* ExprState or GenericExprState as their associated ExprState node type.
* ----------------------------------------------------------------
*/
/* ----------------
* ExprState node
*
* ExprState is the common superclass for all ExprState-type nodes.
*
* It can also be instantiated directly for leaf Expr nodes that need no
* local run-time state (such as Var, Const, or Param).
*
* To save on dispatch overhead, each ExprState node contains a function
* pointer to the routine to execute to evaluate the node.
* ----------------
*/
typedef struct ExprState ExprState;
typedef Datum (*ExprStateEvalFunc) (ExprState *expression,
ExprContext *econtext,
bool *isNull,
ExprDoneCond *isDone);
struct ExprState
{
NodeTag type;
Expr *expr; /* associated Expr node */
ExprStateEvalFunc evalfunc; /* routine to run to execute node */
};
/* ----------------
* GenericExprState node
*
* This is used for Expr node types that need no local run-time state,
* but have one child Expr node.
* ----------------
*/
typedef struct GenericExprState
{
ExprState xprstate;
ExprState *arg; /* state of my child node */
/* ----------------
* AggrefExprState node
* ----------------
*/
typedef struct AggrefExprState
{
ExprState xprstate;
ExprState *target; /* state of my child node */
int aggno; /* ID number for agg within its plan node */
/* ----------------
* ArrayRefExprState node
*
* Note: array types can be fixed-length (typlen > 0), but only when the
* element type is itself fixed-length. Otherwise they are varlena structures
* and have typlen = -1. In any case, an array type is never pass-by-value.
* ----------------
*/
typedef struct ArrayRefExprState
{
ExprState xprstate;
List *reflowerindexpr;
ExprState *refexpr;
ExprState *refassgnexpr;
int16 refattrlength; /* typlen of array type */
int16 refelemlength; /* typlen of the array element type */
bool refelembyval; /* is the element type pass-by-value? */
char refelemalign; /* typalign of the element type */
/* ----------------
* FuncExprState node
*
* Although named for FuncExpr, this is also used for OpExpr, DistinctExpr,
* and NullIf nodes; be careful to check what xprstate.expr is actually
* pointing at!
* ----------------
*/
typedef struct FuncExprState
{
ExprState xprstate;
List *args; /* states of argument expressions */
/*
* Function manager's lookup info for the target function. If
* func.fn_oid is InvalidOid, we haven't initialized it yet.
*/
FmgrInfo func;
/*
* We also need to store argument values across calls when evaluating
* a function-returning-set.
* setArgsValid is true when we are evaluating a set-valued function and
* we are in the middle of a call series; we want to pass the same
* argument values to the function again (and again, until it returns
* ExprEndResult).
*/
bool setArgsValid;
/*
* Flag to remember whether we found a set-valued argument to the
* function. This causes the function result to be a set as well.
* Valid only when setArgsValid is true.
*/
bool setHasSetArg; /* some argument returns a set */
/*
* Flag to remember whether we have registered a shutdown callback for
* this FuncExprState. We do so only if setArgsValid has been true at
* least once (since all the callback is for is to clear setArgsValid).
*/
bool shutdown_reg; /* a shutdown callback is registered */
/*
* Current argument data for a set-valued function; contains valid
* data only if setArgsValid is true.
*/
FunctionCallInfoData setArgs;
/* ----------------
* ScalarArrayOpExprState node
*
* This is a FuncExprState plus some additional data.
* ----------------
*/
typedef struct ScalarArrayOpExprState
{
/* Cached info about array element type */
Oid element_type;
int16 typlen;
bool typbyval;
char typalign;
/* ----------------
* BoolExprState node
* ----------------
*/
typedef struct BoolExprState
{
ExprState xprstate;
List *args; /* states of argument expression(s) */
/* ----------------
* SubPlanState node
* ----------------
*/
typedef struct SubPlanState
{
ExprState xprstate;
EState *sub_estate; /* subselect plan has its own EState */
struct PlanState *planstate; /* subselect plan's state tree */
List *exprs; /* states of combining expression(s) */
List *args; /* states of argument expression(s) */
bool needShutdown; /* TRUE = need to shutdown subplan */
HeapTuple curTuple; /* copy of most recent tuple from subplan */
/* these are used when hashing the subselect's output: */
ProjectionInfo *projLeft; /* for projecting lefthand exprs */
ProjectionInfo *projRight; /* for projecting subselect output */
TupleHashTable hashtable; /* hash table for no-nulls subselect rows */
TupleHashTable hashnulls; /* hash table for rows with null(s) */
bool havehashrows; /* TRUE if hashtable is not empty */
bool havenullrows; /* TRUE if hashnulls is not empty */
MemoryContext tablecxt; /* memory context containing tables */
ExprContext *innerecontext; /* working context for comparisons */
AttrNumber *keyColIdx; /* control data for hash tables */
FmgrInfo *eqfunctions; /* comparison functions for hash tables */
FmgrInfo *hashfunctions; /* lookup data for hash functions */
/* ----------------
* FieldSelectState node
* ----------------
*/
typedef struct FieldSelectState
{
ExprState xprstate;
ExprState *arg; /* input expression */
TupleDesc argdesc; /* tupdesc for most recent input */
} FieldSelectState;
/* ----------------
* FieldStoreState node
* ----------------
*/
typedef struct FieldStoreState
{
ExprState xprstate;
ExprState *arg; /* input tuple value */
List *newvals; /* new value(s) for field(s) */
TupleDesc argdesc; /* tupdesc for most recent input */
} FieldStoreState;
/* ----------------
* CaseExprState node
* ----------------
*/
typedef struct CaseExprState
{
ExprState xprstate;
ExprState *arg; /* implicit equality comparison argument */
List *args; /* the arguments (list of WHEN clauses) */
ExprState *defresult; /* the default result (ELSE clause) */
/* ----------------
* CaseWhenState node
* ----------------
*/
typedef struct CaseWhenState
{
ExprState xprstate;
ExprState *expr; /* condition expression */
ExprState *result; /* substitution result */
/* ----------------
* ArrayExprState node
*
* Note: ARRAY[] expressions always produce varlena arrays, never fixed-length
* arrays.
* ----------------
*/
typedef struct ArrayExprState
{
ExprState xprstate;
List *elements; /* states for child nodes */
int16 elemlength; /* typlen of the array element type */
bool elembyval; /* is the element type pass-by-value? */
char elemalign; /* typalign of the element type */
/* ----------------
* RowExprState node
* ----------------
*/
typedef struct RowExprState
{
ExprState xprstate;
List *args; /* the arguments */
TupleDesc tupdesc; /* descriptor for result tuples */
} RowExprState;
/* ----------------
* CoalesceExprState node
* ----------------
*/
typedef struct CoalesceExprState
{
ExprState xprstate;
/* ----------------
* CoerceToDomainState node
* ----------------
*/
typedef struct CoerceToDomainState
{
ExprState xprstate;
ExprState *arg; /* input expression */
/* Cached list of constraints that need to be checked */
List *constraints; /* list of DomainConstraintState nodes */
/*
* DomainConstraintState - one item to check during CoerceToDomain
*
* Note: this is just a Node, and not an ExprState, because it has no
* corresponding Expr to link to. Nonetheless it is part of an ExprState
* tree, so we give it a name following the xxxState convention.
*/
typedef enum DomainConstraintType
{
DOM_CONSTRAINT_NOTNULL,
DOM_CONSTRAINT_CHECK
typedef struct DomainConstraintState
{
NodeTag type;
DomainConstraintType constrainttype; /* constraint type */
char *name; /* name of constraint (for error msgs) */
ExprState *check_expr; /* for CHECK, a boolean expression */
/* ----------------------------------------------------------------
* Executor State Trees
*
* An executing query has a PlanState tree paralleling the Plan tree
* that describes the plan.
* ----------------------------------------------------------------
*/
/* ----------------
* PlanState node
* We never actually instantiate any PlanState nodes; this is just the common
* abstract superclass for all PlanState-type nodes.
typedef struct PlanState
NodeTag type;
Plan *plan; /* associated Plan node */
EState *state; /* at execution time, state's of
* individual nodes point to one EState
* for the whole top-level plan */
struct Instrumentation *instrument; /* Optional runtime stats for this
* plan node */
/*
* Common structural data for all Plan types. These links to
* subsidiary state trees parallel links in the associated plan tree
* (except for the subPlan list, which does not exist in the plan
* tree).
*/
List *targetlist; /* target list to be computed at this node */
List *qual; /* implicitly-ANDed qual conditions */
struct PlanState *righttree;
List *initPlan; /* Init SubPlanState nodes (un-correlated
* expr subselects) */
List *subPlan; /* SubPlanState nodes in my expressions */
/*
* State for management of parameter-change-driven rescanning
*/
Bitmapset *chgParam; /* set of IDs of changed Params */
/*
* Other run-time state needed by most if not all node types.
*/
TupleTableSlot *ps_OuterTupleSlot; /* slot for current "outer" tuple */
TupleTableSlot *ps_ResultTupleSlot; /* slot for my result tuples */
ExprContext *ps_ExprContext; /* node's expression-evaluation context */
ProjectionInfo *ps_ProjInfo; /* info for doing tuple projection */
bool ps_TupFromTlist;/* state flag for processing set-valued
* functions in targetlist */
/* ----------------
* these are are defined to avoid confusion problems with "left"
* and "right" and "inner" and "outer". The convention is that
* the "left" plan is the "outer" plan and the "right" plan is
* the inner plan, but these make the code more readable.
* ----------------
#define innerPlanState(node) (((PlanState *)(node))->righttree)
#define outerPlanState(node) (((PlanState *)(node))->lefttree)
* ResultState information
typedef struct ResultState
{
PlanState ps; /* its first field is NodeTag */
ExprState *resconstantqual;
bool rs_done; /* are we done? */
bool rs_checkqual; /* do we need to check the qual? */
} ResultState;
* AppendState information
*
* nplans how many plans are in the list
* whichplan which plan is being executed (0 .. n-1)
* firstplan first plan to execute (usually 0)
* lastplan last plan to execute (usually n-1)
typedef struct AppendState
{
PlanState ps; /* its first field is NodeTag */
PlanState **appendplans; /* array of PlanStates for my inputs */
int as_nplans;
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int as_whichplan;
int as_firstplan;
int as_lastplan;
/* ----------------------------------------------------------------
* Scan State Information
* ----------------------------------------------------------------
*/
/* ----------------
* ScanState information
* ScanState extends PlanState for node types that represent
* scans of an underlying relation. It can also be used for nodes
* that scan the output of an underlying plan node --- in that case,
* only ScanTupleSlot is actually useful, and it refers to the tuple
* retrieved from the subplan.
* currentRelation relation being scanned (NULL if none)
* currentScanDesc current scan descriptor for scan (NULL if none)
* ScanTupleSlot pointer to slot in tuple table holding scan tuple
typedef struct ScanState
PlanState ps; /* its first field is NodeTag */
Relation ss_currentRelation;
HeapScanDesc ss_currentScanDesc;
TupleTableSlot *ss_ScanTupleSlot;
* SeqScan uses a bare ScanState as its state node, since it needs
* no additional fields.
*/
typedef ScanState SeqScanState;
* IndexScanState information
*
* indxqualorig execution state for indxqualorig expressions
* NumIndices number of indices in this scan
* IndexPtr current index in use
* MarkIndexPtr IndexPtr for marked scan point
* ScanKeys Skey structures to scan index rels
* NumScanKeys array of no of keys in each Skey struct
* RuntimeKeyInfo array of array of exprstates for Skeys
* that will be evaluated at runtime
* RuntimeContext expr context for evaling runtime Skeys
* RuntimeKeysReady true if runtime Skeys have been computed
* RelationDescs ptr to array of relation descriptors
* ScanDescs ptr to array of scan descriptors
* LossyQuals ptr to array of qual lists for lossy operators
* DupHash hashtable for recognizing dups in multiple scan
* MaxHash max # entries we will allow in hashtable
typedef struct IndexScanState
{
ScanState ss; /* its first field is NodeTag */
List *indxqualorig;
int iss_NumIndices;
int iss_IndexPtr;
int iss_MarkIndexPtr;
ScanKey *iss_ScanKeys;
int *iss_NumScanKeys;
ExprState ***iss_RuntimeKeyInfo;
ExprContext *iss_RuntimeContext;
bool iss_RuntimeKeysReady;
RelationPtr iss_RelationDescs;
IndexScanDescPtr iss_ScanDescs;
List **iss_LossyQuals;
HTAB *iss_DupHash;
long iss_MaxHash;
} IndexScanState;
/* ----------------
* TidScanState information
*
* NumTids number of tids in this scan
* TidPtr current tid in use
* TidList evaluated item pointers
* ----------------
*/
typedef struct TidScanState
{
ScanState ss; /* its first field is NodeTag */
List *tss_tideval; /* list of ExprState nodes */
int tss_NumTids;
int tss_TidPtr;
int tss_MarkTidPtr;
ItemPointerData *tss_TidList;
} TidScanState;
/* ----------------
* SubqueryScanState information
*
* SubqueryScanState is used for scanning a sub-query in the range table.
* The sub-query will have its own EState, which we save here.
* ScanTupleSlot references the current output tuple of the sub-query.
*
* SubEState exec state for sub-query
* ----------------
*/
typedef struct SubqueryScanState
{
ScanState ss; /* its first field is NodeTag */
PlanState *subplan;
EState *sss_SubEState;
} SubqueryScanState;
/* ----------------
* FunctionScanState information
*
* Function nodes are used to scan the results of a
* function appearing in FROM (typically a function returning set).
*
* tupdesc expected return tuple description
* tuplestorestate private state of tuplestore.c
* funcexpr state for function expression being evaluated
* ----------------
*/
typedef struct FunctionScanState
{
ScanState ss; /* its first field is NodeTag */
Tuplestorestate *tuplestorestate;
ExprState *funcexpr;
} FunctionScanState;
/* ----------------------------------------------------------------
* Join State Information
* ----------------------------------------------------------------
*/
/* ----------------
* JoinState information
* Superclass for state nodes of join plans.
typedef struct JoinState
{
PlanState ps;
JoinType jointype;
List *joinqual; /* JOIN quals (in addition to ps.qual) */
} JoinState;
* NestLoopState information
* NeedNewOuter true if need new outer tuple on next call
* MatchedOuter true if found a join match for current outer tuple
* NullInnerTupleSlot prepared null tuple for left outer joins
typedef struct NestLoopState
{
JoinState js; /* its first field is NodeTag */
bool nl_NeedNewOuter;
bool nl_MatchedOuter;
TupleTableSlot *nl_NullInnerTupleSlot;
} NestLoopState;
* MergeJoinState information
* OuterSkipQual outerKey1 < innerKey1 ...
* InnerSkipQual outerKey1 > innerKey1 ...
* JoinState current "state" of join. see executor.h
* MatchedOuter true if found a join match for current outer tuple
* MatchedInner true if found a join match for current inner tuple
* OuterTupleSlot pointer to slot in tuple table for cur outer tuple
* InnerTupleSlot pointer to slot in tuple table for cur inner tuple
* MarkedTupleSlot pointer to slot in tuple table for marked tuple
* NullOuterTupleSlot prepared null tuple for right outer joins
* NullInnerTupleSlot prepared null tuple for left outer joins
typedef struct MergeJoinState
{
JoinState js; /* its first field is NodeTag */
List *mergeclauses; /* list of ExprState nodes */
List *mj_OuterSkipQual; /* list of ExprState nodes */
List *mj_InnerSkipQual; /* list of ExprState nodes */
Bruce Momjian
committed
int mj_JoinState;
bool mj_MatchedOuter;
bool mj_MatchedInner;
TupleTableSlot *mj_OuterTupleSlot;
TupleTableSlot *mj_InnerTupleSlot;
TupleTableSlot *mj_MarkedTupleSlot;
TupleTableSlot *mj_NullOuterTupleSlot;
TupleTableSlot *mj_NullInnerTupleSlot;
} MergeJoinState;
* HashJoinState information
*
* hj_HashTable hash table for the hashjoin
* hj_CurBucketNo bucket# for current outer tuple
* hj_CurTuple last inner tuple matched to current outer
* tuple, or NULL if starting search
* (CurBucketNo and CurTuple are meaningless
* unless OuterTupleSlot is nonempty!)
* hj_OuterHashKeys the outer hash keys in the hashjoin condition
* hj_InnerHashKeys the inner hash keys in the hashjoin condition
* hj_HashOperators the join operators in the hashjoin condition
* hj_OuterTupleSlot tuple slot for outer tuples
* hj_HashTupleSlot tuple slot for hashed tuples
* hj_NullInnerTupleSlot prepared null tuple for left outer joins
* hj_NeedNewOuter true if need new outer tuple on next call
* hj_MatchedOuter true if found a join match for current outer
* hj_hashdone true if hash-table-build phase is done
typedef struct HashJoinState
{
JoinState js; /* its first field is NodeTag */
List *hashclauses; /* list of ExprState nodes */
HashJoinTable hj_HashTable;
int hj_CurBucketNo;