src/include/executor/tuptable.h - cloudberry - Git at Google

 /*-------------------------------------------------------------------------
  *
  * tuptable.h
  *	  tuple table support stuff
  *
  *
  * Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group
  * Portions Copyright (c) 1994, Regents of the University of California
  *
  * src/include/executor/tuptable.h
  *
  *-------------------------------------------------------------------------
  */
 #ifndef TUPTABLE_H
 #define TUPTABLE_H

 #include "access/htup.h"
 #include "access/memtup.h"
 #include "access/htup_details.h"
 #include "access/sysattr.h"
 #include "access/tupdesc.h"
 #include "storage/buf.h"

 /*----------
  * The executor stores tuples in a "tuple table" which is a List of
  * independent TupleTableSlots.
  *
  * There's various different types of tuple table slots, each being able to
  * store different types of tuples. Additional types of slots can be added
  * without modifying core code. The type of a slot is determined by the
  * TupleTableSlotOps* passed to the slot creation routine. The builtin types
  * of slots are
  *
  * 1. physical tuple in a disk buffer page (TTSOpsBufferHeapTuple)
  * 2. physical tuple constructed in palloc'ed memory (TTSOpsHeapTuple)
  * 3. "minimal" physical tuple constructed in palloc'ed memory
  *    (TTSOpsMinimalTuple)
  * 4. "virtual" tuple consisting of Datum/isnull arrays (TTSOpsVirtual)
  *
  * The first two cases are similar in that they both deal with "materialized"
  * tuples, but resource management is different.  For a tuple in a disk page
  * we need to hold a pin on the buffer until the TupleTableSlot's reference
  * to the tuple is dropped; while for a palloc'd tuple we usually want the
  * tuple pfree'd when the TupleTableSlot's reference is dropped.
  *
  * A "minimal" tuple is handled similarly to a palloc'd regular tuple.
  * At present, minimal tuples never are stored in buffers, so there is no
  * parallel to case 1.  Note that a minimal tuple has no "system columns".
  * (Actually, it could have an OID, but we have no need to access the OID.)
  *
  * A "virtual" tuple is an optimization used to minimize physical data copying
  * in a nest of plan nodes.  Until materialized pass-by-reference Datums in
  * the slot point to storage that is not directly associated with the
  * TupleTableSlot; generally they will point to part of a tuple stored in a
  * lower plan node's output TupleTableSlot, or to a function result
  * constructed in a plan node's per-tuple econtext.  It is the responsibility
  * of the generating plan node to be sure these resources are not released for
  * as long as the virtual tuple needs to be valid or is materialized.  Note
  * also that a virtual tuple does not have any "system columns".
  *
  * The Datum/isnull arrays of a TupleTableSlot serve double duty.  For virtual
  * slots they are the authoritative data.  For the other builtin slots,
  * the arrays contain data extracted from the tuple.  (In this state, any
  * pass-by-reference Datums point into the physical tuple.)  The extracted
  * information is built "lazily", ie, only as needed.  This serves to avoid
  * repeated extraction of data from the physical tuple.
  *
  * A TupleTableSlot can also be "empty", indicated by flag TTS_FLAG_EMPTY set
  * in tts_flags, holding no valid data.  This is the only valid state for a
  * freshly-created slot that has not yet had a tuple descriptor assigned to
  * it.  In this state, TTS_SHOULDFREE should not be set in tts_flags, tts_tuple
  * must be NULL and tts_nvalid zero.
  *
  * The tupleDescriptor is simply referenced, not copied, by the TupleTableSlot
  * code.  The caller of ExecSetSlotDescriptor() is responsible for providing
  * a descriptor that will live as long as the slot does.  (Typically, both
  * slots and descriptors are in per-query memory and are freed by memory
  * context deallocation at query end; so it's not worth providing any extra
  * mechanism to do more.  However, the slot will increment the tupdesc
  * reference count if a reference-counted tupdesc is supplied.)
  *
  * When TTS_SHOULDFREE is set in tts_flags, the physical tuple is "owned" by
  * the slot and should be freed when the slot's reference to the tuple is
  * dropped.
  *
  * tts_values/tts_isnull are allocated either when the slot is created (when
  * the descriptor is provided), or when a descriptor is assigned to the slot;
  * they are of length equal to the descriptor's natts.
  *
  * The TTS_FLAG_SLOW flag is saved state for
  * slot_deform_heap_tuple, and should not be touched by any other code.
  *----------
  */

 /* true = slot is empty */
 #define			TTS_FLAG_EMPTY			(1 << 1)
 #define TTS_EMPTY(slot)	(((slot)->tts_flags & TTS_FLAG_EMPTY) != 0)

 /* should pfree tuple "owned" by the slot? */
 #define			TTS_FLAG_SHOULDFREE		(1 << 2)
 #define TTS_SHOULDFREE(slot) (((slot)->tts_flags & TTS_FLAG_SHOULDFREE) != 0)

 /* saved state for slot_deform_heap_tuple */
 #define			TTS_FLAG_SLOW		(1 << 3)
 #define TTS_SLOW(slot) (((slot)->tts_flags & TTS_FLAG_SLOW) != 0)

 /* fixed tuple descriptor */
 #define			TTS_FLAG_FIXED		(1 << 4)
 #define TTS_FIXED(slot) (((slot)->tts_flags & TTS_FLAG_FIXED) != 0)

 struct TupleTableSlotOps;
 typedef struct TupleTableSlotOps TupleTableSlotOps;

 /* base tuple table slot type */
 typedef struct TupleTableSlot
 {
 	NodeTag		type;
 #define FIELDNO_TUPLETABLESLOT_FLAGS 1
 	uint16		tts_flags;		/* Boolean states */
 #define FIELDNO_TUPLETABLESLOT_NVALID 2
 	AttrNumber	tts_nvalid;		/* # of valid values in tts_values */
 	const TupleTableSlotOps *const tts_ops; /* implementation of slot */
 #define FIELDNO_TUPLETABLESLOT_TUPLEDESCRIPTOR 4
 	TupleDesc	tts_tupleDescriptor;	/* slot's tuple descriptor */
 #define FIELDNO_TUPLETABLESLOT_VALUES 5
 	Datum	   *tts_values;		/* current per-attribute values */
 #define FIELDNO_TUPLETABLESLOT_ISNULL 6
 	bool	   *tts_isnull;		/* current per-attribute isnull flags */
 	MemoryContext tts_mcxt;		/* slot itself is in this context */
 	ItemPointerData tts_tid;	/* stored tuple's tid */
 	Oid			tts_tableOid;	/* table oid of tuple */
 } TupleTableSlot;

 /* routines for a TupleTableSlot implementation */
 struct TupleTableSlotOps
 {
 	/* Minimum size of the slot */
 	size_t		base_slot_size;

 	/* Initialization. */
 	void		(*init) (TupleTableSlot *slot);

 	/* Destruction. */
 	void		(*release) (TupleTableSlot *slot);

 	/*
 	 * Clear the contents of the slot. Only the contents are expected to be
 	 * cleared and not the tuple descriptor. Typically an implementation of
 	 * this callback should free the memory allocated for the tuple contained
 	 * in the slot.
 	 */
 	void		(*clear) (TupleTableSlot *slot);

 	/*
 	 * Fill up first natts entries of tts_values and tts_isnull arrays with
 	 * values from the tuple contained in the slot. The function may be called
 	 * with natts more than the number of attributes available in the tuple,
 	 * in which case it should set tts_nvalid to the number of returned
 	 * columns.
 	 */
 	void		(*getsomeattrs) (TupleTableSlot *slot, int natts);

 	/*
 	 * Returns value of the given system attribute as a datum and sets isnull
 	 * to false, if it's not NULL. Throws an error if the slot type does not
 	 * support system attributes.
 	 */
 	Datum		(*getsysattr) (TupleTableSlot *slot, int attnum, bool *isnull);

 	/*
 	 * Make the contents of the slot solely depend on the slot, and not on
 	 * underlying resources (like another memory context, buffers, etc).
 	 */
 	void		(*materialize) (TupleTableSlot *slot);

 	/*
 	 * Copy the contents of the source slot into the destination slot's own
 	 * context. Invoked using callback of the destination slot.
 	 */
 	void		(*copyslot) (TupleTableSlot *dstslot, TupleTableSlot *srcslot);

 	/*
 	 * Return a heap tuple "owned" by the slot. It is slot's responsibility to
 	 * free the memory consumed by the heap tuple. If the slot can not "own" a
 	 * heap tuple, it should not implement this callback and should set it as
 	 * NULL.
 	 */
 	HeapTuple	(*get_heap_tuple) (TupleTableSlot *slot);

 	/*
 	 * Return a minimal tuple "owned" by the slot. It is slot's responsibility
 	 * to free the memory consumed by the minimal tuple. If the slot can not
 	 * "own" a minimal tuple, it should not implement this callback and should
 	 * set it as NULL.
 	 */
 	MinimalTuple (*get_minimal_tuple) (TupleTableSlot *slot);

 	/*
 	 * Return a copy of heap tuple representing the contents of the slot. The
 	 * copy needs to be palloc'd in the current memory context. The slot
 	 * itself is expected to remain unaffected. It is *not* expected to have
 	 * meaningful "system columns" in the copy. The copy is not be "owned" by
 	 * the slot i.e. the caller has to take responsibility to free memory
 	 * consumed by the slot.
 	 */
 	HeapTuple	(*copy_heap_tuple) (TupleTableSlot *slot);

 	/*
 	 * Return a copy of minimal tuple representing the contents of the slot.
 	 * The copy needs to be palloc'd in the current memory context. The slot
 	 * itself is expected to remain unaffected. It is *not* expected to have
 	 * meaningful "system columns" in the copy. The copy is not be "owned" by
 	 * the slot i.e. the caller has to take responsibility to free memory
 	 * consumed by the slot.
 	 */
 	MinimalTuple (*copy_minimal_tuple) (TupleTableSlot *slot);
 };

 /*
  * Predefined TupleTableSlotOps for various types of TupleTableSlotOps. The
  * same are used to identify the type of a given slot.
  */
 extern PGDLLIMPORT const TupleTableSlotOps TTSOpsVirtual;
 extern PGDLLIMPORT const TupleTableSlotOps TTSOpsHeapTuple;
 extern PGDLLIMPORT const TupleTableSlotOps TTSOpsMinimalTuple;
 extern PGDLLIMPORT const TupleTableSlotOps TTSOpsBufferHeapTuple;

 #define TTS_IS_VIRTUAL(slot) ((slot)->tts_ops == &TTSOpsVirtual)
 #define TTS_IS_HEAPTUPLE(slot) ((slot)->tts_ops == &TTSOpsHeapTuple)
 #define TTS_IS_MINIMALTUPLE(slot) ((slot)->tts_ops == &TTSOpsMinimalTuple)
 #define TTS_IS_BUFFERTUPLE(slot) ((slot)->tts_ops == &TTSOpsBufferHeapTuple)

 /*
  * Tuple table slot implementations.
  */

 typedef struct VirtualTupleTableSlot
 {
 	TupleTableSlot base;

 	char	   *data;			/* data for materialized slots */
 } VirtualTupleTableSlot;

 typedef struct HeapTupleTableSlot
 {
 	TupleTableSlot base;

 #define FIELDNO_HEAPTUPLETABLESLOT_TUPLE 1
 	HeapTuple	tuple;			/* physical tuple */
 #define FIELDNO_HEAPTUPLETABLESLOT_OFF 2
 	uint32		off;			/* saved state for slot_deform_heap_tuple */
 	HeapTupleData tupdata;		/* optional workspace for storing tuple */
 } HeapTupleTableSlot;

 /* heap tuple residing in a buffer */
 typedef struct BufferHeapTupleTableSlot
 {
 	HeapTupleTableSlot base;

 	/*
 	 * If buffer is not InvalidBuffer, then the slot is holding a pin on the
 	 * indicated buffer page; drop the pin when we release the slot's
 	 * reference to that buffer.  (TTS_FLAG_SHOULDFREE should not be set in
 	 * such a case, since presumably tts_tuple is pointing into the buffer.)
 	 */
 	Buffer		buffer;			/* tuple's buffer, or InvalidBuffer */
 } BufferHeapTupleTableSlot;

 typedef struct MinimalTupleTableSlot
 {
 	TupleTableSlot base;

 	/*
 	 * In a minimal slot tuple points at minhdr and the fields of that struct
 	 * are set correctly for access to the minimal tuple; in particular,
 	 * minhdr.t_data points MINIMAL_TUPLE_OFFSET bytes before mintuple.  This
 	 * allows column extraction to treat the case identically to regular
 	 * physical tuples.
 	 */
 #define FIELDNO_MINIMALTUPLETABLESLOT_TUPLE 1
 	HeapTuple	tuple;			/* tuple wrapper */
 	MinimalTuple mintuple;		/* minimal tuple, or NULL if none */
 	HeapTupleData minhdr;		/* workspace for minimal-tuple-only case */
 #define FIELDNO_MINIMALTUPLETABLESLOT_OFF 4
 	uint32		off;			/* saved state for slot_deform_heap_tuple */
 } MinimalTupleTableSlot;

 /*
  * TupIsNull -- is a TupleTableSlot empty?
  */
 #define TupIsNull(slot) \
 	((slot) == NULL || TTS_EMPTY(slot))

 /* in executor/execTuples.c */
 extern TupleTableSlot *MakeTupleTableSlot(TupleDesc tupleDesc,
 										  const TupleTableSlotOps *tts_ops);
 extern TupleTableSlot *ExecAllocTableSlot(List **tupleTable, TupleDesc desc,
 										  const TupleTableSlotOps *tts_ops);
 extern void ExecResetTupleTable(List *tupleTable, bool shouldFree);
 extern TupleTableSlot *MakeSingleTupleTableSlot(TupleDesc tupdesc,
 												const TupleTableSlotOps *tts_ops);
 extern void ExecDropSingleTupleTableSlot(TupleTableSlot *slot);
 extern void ExecSetSlotDescriptor(TupleTableSlot *slot, TupleDesc tupdesc);
 extern TupleTableSlot *ExecStoreHeapTuple(HeapTuple tuple,
 										  TupleTableSlot *slot,
 										  bool shouldFree);
 extern void ExecForceStoreHeapTuple(HeapTuple tuple,
 									TupleTableSlot *slot,
 									bool shouldFree);
 extern TupleTableSlot *ExecStoreBufferHeapTuple(HeapTuple tuple,
 												TupleTableSlot *slot,
 												Buffer buffer);
 extern TupleTableSlot *ExecStorePinnedBufferHeapTuple(HeapTuple tuple,
 													  TupleTableSlot *slot,
 													  Buffer buffer);
 extern TupleTableSlot *ExecStoreMinimalTuple(MinimalTuple mtup,
 											 TupleTableSlot *slot,
 											 bool shouldFree);
 extern void ExecForceStoreMinimalTuple(MinimalTuple mtup, TupleTableSlot *slot,
 									   bool shouldFree);
 extern TupleTableSlot *ExecStoreVirtualTuple(TupleTableSlot *slot);
 extern TupleTableSlot *ExecStoreAllNullTuple(TupleTableSlot *slot);
 extern void ExecStoreHeapTupleDatum(Datum data, TupleTableSlot *slot);
 extern HeapTuple ExecFetchSlotHeapTuple(TupleTableSlot *slot, bool materialize, bool *shouldFree);
 extern MinimalTuple ExecFetchSlotMinimalTuple(TupleTableSlot *slot,
 											  bool *shouldFree);
 extern Datum ExecFetchSlotHeapTupleDatum(TupleTableSlot *slot);
 extern void slot_getmissingattrs(TupleTableSlot *slot, int startAttNum,
 								 int lastAttNum);
 extern void slot_getsomeattrs_int(TupleTableSlot *slot, int attnum);

 extern MemTuple appendonly_form_memtuple(TupleTableSlot *slot, MemTupleBinding *mt_bind);
 extern void appendonly_free_memtuple(MemTuple tuple);

 #ifndef FRONTEND


 /*
  * This function forces the entries of the slot's Datum/isnull arrays to be
  * valid at least up through the attnum'th entry.
  */
 static inline void
 slot_getsomeattrs(TupleTableSlot *slot, int attnum)
 {
 	if (slot->tts_nvalid < attnum)
 		slot_getsomeattrs_int(slot, attnum);
 }

 /*
  * slot_getallattrs
  *		This function forces all the entries of the slot's Datum/isnull
  *		arrays to be valid.  The caller may then extract data directly
  *		from those arrays instead of using slot_getattr.
  */
 static inline void
 slot_getallattrs(TupleTableSlot *slot)
 {
 	slot_getsomeattrs(slot, slot->tts_tupleDescriptor->natts);
 }


 /*
  * slot_attisnull
  *
  * Detect whether an attribute of the slot is null, without actually fetching
  * it.
  */
 static inline bool
 slot_attisnull(TupleTableSlot *slot, int attnum)
 {
 	AssertArg(attnum > 0);

 	if (attnum > slot->tts_nvalid)
 		slot_getsomeattrs(slot, attnum);

 	return slot->tts_isnull[attnum - 1];
 }

 /*
  * slot_getattr - fetch one attribute of the slot's contents.
  */
 static inline Datum
 slot_getattr(TupleTableSlot *slot, int attnum,
 			 bool *isnull)
 {
 	AssertArg(attnum > 0);

 	if (attnum > slot->tts_nvalid)
 		slot_getsomeattrs(slot, attnum);

 	*isnull = slot->tts_isnull[attnum - 1];

 	return slot->tts_values[attnum - 1];
 }

 /*
  * slot_getsysattr - fetch a system attribute of the slot's current tuple.
  *
  *  If the slot type does not contain system attributes, this will throw an
  *  error.  Hence before calling this function, callers should make sure that
  *  the slot type is the one that supports system attributes.
  */
 static inline Datum
 slot_getsysattr(TupleTableSlot *slot, int attnum, bool *isnull)
 {
 	AssertArg(attnum < 0);		/* caller error */

 	if (attnum == TableOidAttributeNumber)
 	{
 		*isnull = false;
 		return ObjectIdGetDatum(slot->tts_tableOid);
 	}
 	else if (attnum == SelfItemPointerAttributeNumber)
 	{
 		*isnull = false;
 		return PointerGetDatum(&slot->tts_tid);
 	}

 	/* Fetch the system attribute from the underlying tuple. */
 	return slot->tts_ops->getsysattr(slot, attnum, isnull);
 }

 /*
  * ExecClearTuple - clear the slot's contents
  */
 static inline TupleTableSlot *
 ExecClearTuple(TupleTableSlot *slot)
 {
 	slot->tts_ops->clear(slot);

 	return slot;
 }

 /* ExecMaterializeSlot - force a slot into the "materialized" state.
  *
  * This causes the slot's tuple to be a local copy not dependent on any
  * external storage (i.e. pointing into a Buffer, or having allocations in
  * another memory context).
  *
  * A typical use for this operation is to prepare a computed tuple for being
  * stored on disk.  The original data may or may not be virtual, but in any
  * case we need a private copy for heap_insert to scribble on.
  */
 static inline void
 ExecMaterializeSlot(TupleTableSlot *slot)
 {
 	slot->tts_ops->materialize(slot);
 }

 /*
  * ExecCopySlotHeapTuple - return HeapTuple allocated in caller's context
  */
 static inline HeapTuple
 ExecCopySlotHeapTuple(TupleTableSlot *slot)
 {
 	Assert(!TTS_EMPTY(slot));

 	return slot->tts_ops->copy_heap_tuple(slot);
 }

 /*
  * ExecCopySlotMinimalTuple - return MinimalTuple allocated in caller's context
  */
 static inline MinimalTuple
 ExecCopySlotMinimalTuple(TupleTableSlot *slot)
 {
 	return slot->tts_ops->copy_minimal_tuple(slot);
 }

 /*
  * ExecCopySlot - copy one slot's contents into another.
  *
  * If a source's system attributes are supposed to be accessed in the target
  * slot, the target slot and source slot types need to match.
  */
 static inline TupleTableSlot *
 ExecCopySlot(TupleTableSlot *dstslot, TupleTableSlot *srcslot)
 {
 	Assert(!TTS_EMPTY(srcslot));
 	AssertArg(srcslot != dstslot);

 	dstslot->tts_ops->copyslot(dstslot, srcslot);

 	return dstslot;
 }

 #endif							/* FRONTEND */

 #endif							/* TUPTABLE_H */
	/*-------------------------------------------------------------------------
	*
	* tuptable.h
	* tuple table support stuff
	*
	*
	* Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group
	* Portions Copyright (c) 1994, Regents of the University of California
	*
	* src/include/executor/tuptable.h
	*
	*-------------------------------------------------------------------------
	*/
	#ifndef TUPTABLE_H
	#define TUPTABLE_H

	#include "access/htup.h"
	#include "access/memtup.h"
	#include "access/htup_details.h"
	#include "access/sysattr.h"
	#include "access/tupdesc.h"
	#include "storage/buf.h"

	/*----------
	* The executor stores tuples in a "tuple table" which is a List of
	* independent TupleTableSlots.
	*
	* There's various different types of tuple table slots, each being able to
	* store different types of tuples. Additional types of slots can be added
	* without modifying core code. The type of a slot is determined by the
	* TupleTableSlotOps* passed to the slot creation routine. The builtin types
	* of slots are
	*
	* 1. physical tuple in a disk buffer page (TTSOpsBufferHeapTuple)
	* 2. physical tuple constructed in palloc'ed memory (TTSOpsHeapTuple)
	* 3. "minimal" physical tuple constructed in palloc'ed memory
	* (TTSOpsMinimalTuple)
	* 4. "virtual" tuple consisting of Datum/isnull arrays (TTSOpsVirtual)
	*
	* The first two cases are similar in that they both deal with "materialized"
	* tuples, but resource management is different. For a tuple in a disk page
	* we need to hold a pin on the buffer until the TupleTableSlot's reference
	* to the tuple is dropped; while for a palloc'd tuple we usually want the
	* tuple pfree'd when the TupleTableSlot's reference is dropped.
	*
	* A "minimal" tuple is handled similarly to a palloc'd regular tuple.
	* At present, minimal tuples never are stored in buffers, so there is no
	* parallel to case 1. Note that a minimal tuple has no "system columns".
	* (Actually, it could have an OID, but we have no need to access the OID.)
	*
	* A "virtual" tuple is an optimization used to minimize physical data copying
	* in a nest of plan nodes. Until materialized pass-by-reference Datums in
	* the slot point to storage that is not directly associated with the
	* TupleTableSlot; generally they will point to part of a tuple stored in a
	* lower plan node's output TupleTableSlot, or to a function result
	* constructed in a plan node's per-tuple econtext. It is the responsibility
	* of the generating plan node to be sure these resources are not released for
	* as long as the virtual tuple needs to be valid or is materialized. Note
	* also that a virtual tuple does not have any "system columns".
	*
	* The Datum/isnull arrays of a TupleTableSlot serve double duty. For virtual
	* slots they are the authoritative data. For the other builtin slots,
	* the arrays contain data extracted from the tuple. (In this state, any
	* pass-by-reference Datums point into the physical tuple.) The extracted
	* information is built "lazily", ie, only as needed. This serves to avoid
	* repeated extraction of data from the physical tuple.
	*
	* A TupleTableSlot can also be "empty", indicated by flag TTS_FLAG_EMPTY set
	* in tts_flags, holding no valid data. This is the only valid state for a
	* freshly-created slot that has not yet had a tuple descriptor assigned to
	* it. In this state, TTS_SHOULDFREE should not be set in tts_flags, tts_tuple
	* must be NULL and tts_nvalid zero.
	*
	* The tupleDescriptor is simply referenced, not copied, by the TupleTableSlot
	* code. The caller of ExecSetSlotDescriptor() is responsible for providing
	* a descriptor that will live as long as the slot does. (Typically, both
	* slots and descriptors are in per-query memory and are freed by memory
	* context deallocation at query end; so it's not worth providing any extra
	* mechanism to do more. However, the slot will increment the tupdesc
	* reference count if a reference-counted tupdesc is supplied.)
	*
	* When TTS_SHOULDFREE is set in tts_flags, the physical tuple is "owned" by
	* the slot and should be freed when the slot's reference to the tuple is
	* dropped.
	*
	* tts_values/tts_isnull are allocated either when the slot is created (when
	* the descriptor is provided), or when a descriptor is assigned to the slot;
	* they are of length equal to the descriptor's natts.
	*
	* The TTS_FLAG_SLOW flag is saved state for
	* slot_deform_heap_tuple, and should not be touched by any other code.
	*----------
	*/

	/* true = slot is empty */
	#define TTS_FLAG_EMPTY (1 << 1)
	#define TTS_EMPTY(slot) (((slot)->tts_flags & TTS_FLAG_EMPTY) != 0)

	/* should pfree tuple "owned" by the slot? */
	#define TTS_FLAG_SHOULDFREE (1 << 2)
	#define TTS_SHOULDFREE(slot) (((slot)->tts_flags & TTS_FLAG_SHOULDFREE) != 0)

	/* saved state for slot_deform_heap_tuple */
	#define TTS_FLAG_SLOW (1 << 3)
	#define TTS_SLOW(slot) (((slot)->tts_flags & TTS_FLAG_SLOW) != 0)

	/* fixed tuple descriptor */
	#define TTS_FLAG_FIXED (1 << 4)
	#define TTS_FIXED(slot) (((slot)->tts_flags & TTS_FLAG_FIXED) != 0)

	struct TupleTableSlotOps;
	typedef struct TupleTableSlotOps TupleTableSlotOps;

	/* base tuple table slot type */
	typedef struct TupleTableSlot
	{
	NodeTag type;
	#define FIELDNO_TUPLETABLESLOT_FLAGS 1
	uint16 tts_flags; /* Boolean states */
	#define FIELDNO_TUPLETABLESLOT_NVALID 2
	AttrNumber tts_nvalid; /* # of valid values in tts_values */
	const TupleTableSlotOps const tts_ops; / implementation of slot */
	#define FIELDNO_TUPLETABLESLOT_TUPLEDESCRIPTOR 4
	TupleDesc tts_tupleDescriptor; /* slot's tuple descriptor */
	#define FIELDNO_TUPLETABLESLOT_VALUES 5
	Datum tts_values; / current per-attribute values */
	#define FIELDNO_TUPLETABLESLOT_ISNULL 6
	bool tts_isnull; / current per-attribute isnull flags */
	MemoryContext tts_mcxt; /* slot itself is in this context */
	ItemPointerData tts_tid; /* stored tuple's tid */
	Oid tts_tableOid; /* table oid of tuple */
	} TupleTableSlot;

	/* routines for a TupleTableSlot implementation */
	struct TupleTableSlotOps
	{
	/* Minimum size of the slot */
	size_t base_slot_size;

	/* Initialization. */
	void (init) (TupleTableSlot slot);

	/* Destruction. */
	void (release) (TupleTableSlot slot);

	/*
	* Clear the contents of the slot. Only the contents are expected to be
	* cleared and not the tuple descriptor. Typically an implementation of
	* this callback should free the memory allocated for the tuple contained
	* in the slot.
	*/
	void (clear) (TupleTableSlot slot);

	/*
	* Fill up first natts entries of tts_values and tts_isnull arrays with
	* values from the tuple contained in the slot. The function may be called
	* with natts more than the number of attributes available in the tuple,
	* in which case it should set tts_nvalid to the number of returned
	* columns.
	*/
	void (getsomeattrs) (TupleTableSlot slot, int natts);

	/*
	* Returns value of the given system attribute as a datum and sets isnull
	* to false, if it's not NULL. Throws an error if the slot type does not
	* support system attributes.
	*/
	Datum (getsysattr) (TupleTableSlot slot, int attnum, bool *isnull);

	/*
	* Make the contents of the slot solely depend on the slot, and not on
	* underlying resources (like another memory context, buffers, etc).
	*/
	void (materialize) (TupleTableSlot slot);

	/*
	* Copy the contents of the source slot into the destination slot's own
	* context. Invoked using callback of the destination slot.
	*/
	void (copyslot) (TupleTableSlot dstslot, TupleTableSlot *srcslot);

	/*
	* Return a heap tuple "owned" by the slot. It is slot's responsibility to
	* free the memory consumed by the heap tuple. If the slot can not "own" a
	* heap tuple, it should not implement this callback and should set it as
	* NULL.
	*/
	HeapTuple (get_heap_tuple) (TupleTableSlot slot);

	/*
	* Return a minimal tuple "owned" by the slot. It is slot's responsibility
	* to free the memory consumed by the minimal tuple. If the slot can not
	* "own" a minimal tuple, it should not implement this callback and should
	* set it as NULL.
	*/
	MinimalTuple (get_minimal_tuple) (TupleTableSlot slot);

	/*
	* Return a copy of heap tuple representing the contents of the slot. The
	* copy needs to be palloc'd in the current memory context. The slot
	* itself is expected to remain unaffected. It is not expected to have
	* meaningful "system columns" in the copy. The copy is not be "owned" by
	* the slot i.e. the caller has to take responsibility to free memory
	* consumed by the slot.
	*/
	HeapTuple (copy_heap_tuple) (TupleTableSlot slot);

	/*
	* Return a copy of minimal tuple representing the contents of the slot.
	* The copy needs to be palloc'd in the current memory context. The slot
	* itself is expected to remain unaffected. It is not expected to have
	* meaningful "system columns" in the copy. The copy is not be "owned" by
	* the slot i.e. the caller has to take responsibility to free memory
	* consumed by the slot.
	*/
	MinimalTuple (copy_minimal_tuple) (TupleTableSlot slot);
	};

	/*
	* Predefined TupleTableSlotOps for various types of TupleTableSlotOps. The
	* same are used to identify the type of a given slot.
	*/
	extern PGDLLIMPORT const TupleTableSlotOps TTSOpsVirtual;
	extern PGDLLIMPORT const TupleTableSlotOps TTSOpsHeapTuple;
	extern PGDLLIMPORT const TupleTableSlotOps TTSOpsMinimalTuple;
	extern PGDLLIMPORT const TupleTableSlotOps TTSOpsBufferHeapTuple;

	#define TTS_IS_VIRTUAL(slot) ((slot)->tts_ops == &TTSOpsVirtual)
	#define TTS_IS_HEAPTUPLE(slot) ((slot)->tts_ops == &TTSOpsHeapTuple)
	#define TTS_IS_MINIMALTUPLE(slot) ((slot)->tts_ops == &TTSOpsMinimalTuple)
	#define TTS_IS_BUFFERTUPLE(slot) ((slot)->tts_ops == &TTSOpsBufferHeapTuple)

	/*
	* Tuple table slot implementations.
	*/

	typedef struct VirtualTupleTableSlot
	{
	TupleTableSlot base;

	char data; / data for materialized slots */
	} VirtualTupleTableSlot;

	typedef struct HeapTupleTableSlot
	{
	TupleTableSlot base;

	#define FIELDNO_HEAPTUPLETABLESLOT_TUPLE 1
	HeapTuple tuple; /* physical tuple */
	#define FIELDNO_HEAPTUPLETABLESLOT_OFF 2
	uint32 off; /* saved state for slot_deform_heap_tuple */
	HeapTupleData tupdata; /* optional workspace for storing tuple */
	} HeapTupleTableSlot;

	/* heap tuple residing in a buffer */
	typedef struct BufferHeapTupleTableSlot
	{
	HeapTupleTableSlot base;

	/*
	* If buffer is not InvalidBuffer, then the slot is holding a pin on the
	* indicated buffer page; drop the pin when we release the slot's
	* reference to that buffer. (TTS_FLAG_SHOULDFREE should not be set in
	* such a case, since presumably tts_tuple is pointing into the buffer.)
	*/
	Buffer buffer; /* tuple's buffer, or InvalidBuffer */
	} BufferHeapTupleTableSlot;

	typedef struct MinimalTupleTableSlot
	{
	TupleTableSlot base;

	/*
	* In a minimal slot tuple points at minhdr and the fields of that struct
	* are set correctly for access to the minimal tuple; in particular,
	* minhdr.t_data points MINIMAL_TUPLE_OFFSET bytes before mintuple. This
	* allows column extraction to treat the case identically to regular
	* physical tuples.
	*/
	#define FIELDNO_MINIMALTUPLETABLESLOT_TUPLE 1
	HeapTuple tuple; /* tuple wrapper */
	MinimalTuple mintuple; /* minimal tuple, or NULL if none */
	HeapTupleData minhdr; /* workspace for minimal-tuple-only case */
	#define FIELDNO_MINIMALTUPLETABLESLOT_OFF 4
	uint32 off; /* saved state for slot_deform_heap_tuple */
	} MinimalTupleTableSlot;

	/*
	* TupIsNull -- is a TupleTableSlot empty?
	*/
	#define TupIsNull(slot) \
	((slot) == NULL \|\| TTS_EMPTY(slot))

	/* in executor/execTuples.c */
	extern TupleTableSlot *MakeTupleTableSlot(TupleDesc tupleDesc,
	const TupleTableSlotOps *tts_ops);
	extern TupleTableSlot ExecAllocTableSlot(List *tupleTable, TupleDesc desc,
	const TupleTableSlotOps *tts_ops);
	extern void ExecResetTupleTable(List *tupleTable, bool shouldFree);
	extern TupleTableSlot *MakeSingleTupleTableSlot(TupleDesc tupdesc,
	const TupleTableSlotOps *tts_ops);
	extern void ExecDropSingleTupleTableSlot(TupleTableSlot *slot);
	extern void ExecSetSlotDescriptor(TupleTableSlot *slot, TupleDesc tupdesc);
	extern TupleTableSlot *ExecStoreHeapTuple(HeapTuple tuple,
	TupleTableSlot *slot,
	bool shouldFree);
	extern void ExecForceStoreHeapTuple(HeapTuple tuple,
	TupleTableSlot *slot,
	bool shouldFree);
	extern TupleTableSlot *ExecStoreBufferHeapTuple(HeapTuple tuple,
	TupleTableSlot *slot,
	Buffer buffer);
	extern TupleTableSlot *ExecStorePinnedBufferHeapTuple(HeapTuple tuple,
	TupleTableSlot *slot,
	Buffer buffer);
	extern TupleTableSlot *ExecStoreMinimalTuple(MinimalTuple mtup,
	TupleTableSlot *slot,
	bool shouldFree);
	extern void ExecForceStoreMinimalTuple(MinimalTuple mtup, TupleTableSlot *slot,
	bool shouldFree);
	extern TupleTableSlot ExecStoreVirtualTuple(TupleTableSlot slot);
	extern TupleTableSlot ExecStoreAllNullTuple(TupleTableSlot slot);
	extern void ExecStoreHeapTupleDatum(Datum data, TupleTableSlot *slot);
	extern HeapTuple ExecFetchSlotHeapTuple(TupleTableSlot slot, bool materialize, bool shouldFree);
	extern MinimalTuple ExecFetchSlotMinimalTuple(TupleTableSlot *slot,
	bool *shouldFree);
	extern Datum ExecFetchSlotHeapTupleDatum(TupleTableSlot *slot);
	extern void slot_getmissingattrs(TupleTableSlot *slot, int startAttNum,
	int lastAttNum);
	extern void slot_getsomeattrs_int(TupleTableSlot *slot, int attnum);

	extern MemTuple appendonly_form_memtuple(TupleTableSlot slot, MemTupleBinding mt_bind);
	extern void appendonly_free_memtuple(MemTuple tuple);

	#ifndef FRONTEND


	/*
	* This function forces the entries of the slot's Datum/isnull arrays to be
	* valid at least up through the attnum'th entry.
	*/
	static inline void
	slot_getsomeattrs(TupleTableSlot *slot, int attnum)
	{
	if (slot->tts_nvalid < attnum)
	slot_getsomeattrs_int(slot, attnum);
	}

	/*
	* slot_getallattrs
	* This function forces all the entries of the slot's Datum/isnull
	* arrays to be valid. The caller may then extract data directly
	* from those arrays instead of using slot_getattr.
	*/
	static inline void
	slot_getallattrs(TupleTableSlot *slot)
	{
	slot_getsomeattrs(slot, slot->tts_tupleDescriptor->natts);
	}


	/*
	* slot_attisnull
	*
	* Detect whether an attribute of the slot is null, without actually fetching
	* it.
	*/
	static inline bool
	slot_attisnull(TupleTableSlot *slot, int attnum)
	{
	AssertArg(attnum > 0);

	if (attnum > slot->tts_nvalid)
	slot_getsomeattrs(slot, attnum);

	return slot->tts_isnull[attnum - 1];
	}

	/*
	* slot_getattr - fetch one attribute of the slot's contents.
	*/
	static inline Datum
	slot_getattr(TupleTableSlot *slot, int attnum,
	bool *isnull)
	{
	AssertArg(attnum > 0);

	if (attnum > slot->tts_nvalid)
	slot_getsomeattrs(slot, attnum);

	*isnull = slot->tts_isnull[attnum - 1];

	return slot->tts_values[attnum - 1];
	}

	/*
	* slot_getsysattr - fetch a system attribute of the slot's current tuple.
	*
	* If the slot type does not contain system attributes, this will throw an
	* error. Hence before calling this function, callers should make sure that
	* the slot type is the one that supports system attributes.
	*/
	static inline Datum
	slot_getsysattr(TupleTableSlot slot, int attnum, bool isnull)
	{
	AssertArg(attnum < 0); /* caller error */

	if (attnum == TableOidAttributeNumber)
	{
	*isnull = false;
	return ObjectIdGetDatum(slot->tts_tableOid);
	}
	else if (attnum == SelfItemPointerAttributeNumber)
	{
	*isnull = false;
	return PointerGetDatum(&slot->tts_tid);
	}

	/* Fetch the system attribute from the underlying tuple. */
	return slot->tts_ops->getsysattr(slot, attnum, isnull);
	}

	/*
	* ExecClearTuple - clear the slot's contents
	*/
	static inline TupleTableSlot *
	ExecClearTuple(TupleTableSlot *slot)
	{
	slot->tts_ops->clear(slot);

	return slot;
	}

	/* ExecMaterializeSlot - force a slot into the "materialized" state.
	*
	* This causes the slot's tuple to be a local copy not dependent on any
	* external storage (i.e. pointing into a Buffer, or having allocations in
	* another memory context).
	*
	* A typical use for this operation is to prepare a computed tuple for being
	* stored on disk. The original data may or may not be virtual, but in any
	* case we need a private copy for heap_insert to scribble on.
	*/
	static inline void
	ExecMaterializeSlot(TupleTableSlot *slot)
	{
	slot->tts_ops->materialize(slot);
	}

	/*
	* ExecCopySlotHeapTuple - return HeapTuple allocated in caller's context
	*/
	static inline HeapTuple
	ExecCopySlotHeapTuple(TupleTableSlot *slot)
	{
	Assert(!TTS_EMPTY(slot));

	return slot->tts_ops->copy_heap_tuple(slot);
	}

	/*
	* ExecCopySlotMinimalTuple - return MinimalTuple allocated in caller's context
	*/
	static inline MinimalTuple
	ExecCopySlotMinimalTuple(TupleTableSlot *slot)
	{
	return slot->tts_ops->copy_minimal_tuple(slot);
	}

	/*
	* ExecCopySlot - copy one slot's contents into another.
	*
	* If a source's system attributes are supposed to be accessed in the target
	* slot, the target slot and source slot types need to match.
	*/
	static inline TupleTableSlot *
	ExecCopySlot(TupleTableSlot dstslot, TupleTableSlot srcslot)
	{
	Assert(!TTS_EMPTY(srcslot));
	AssertArg(srcslot != dstslot);

	dstslot->tts_ops->copyslot(dstslot, srcslot);

	return dstslot;
	}

	#endif /* FRONTEND */

	#endif /* TUPTABLE_H */