nbtree.h File Reference

#include "access/amapi.h"
#include "access/itup.h"
#include "access/sdir.h"
#include "access/xlogreader.h"
#include "catalog/pg_am_d.h"
#include "catalog/pg_index.h"
#include "lib/stringinfo.h"
#include "storage/bufmgr.h"
#include "storage/shm_toc.h"

Include dependency graph for nbtree.h:

This graph shows which files directly or indirectly include this file:

Go to the source code of this file.

Data Structures
struct	BTPageOpaqueData
struct	BTMetaPageData
struct	BTStackData
struct	BTScanInsertData
struct	BTInsertStateData
struct	BTScanPosItem
struct	BTScanPosData
struct	BTArrayKeyInfo
struct	BTScanOpaqueData
struct	BTOptions

Macros
#define	BTP_LEAF   (1 << 0) /* leaf page, i.e. not internal page */
#define	BTP_ROOT   (1 << 1) /* root page (has no parent) */
#define	BTP_DELETED   (1 << 2) /* page has been deleted from tree */
#define	BTP_META   (1 << 3) /* meta-page */
#define	BTP_HALF_DEAD   (1 << 4) /* empty, but still in tree */
#define	BTP_SPLIT_END   (1 << 5) /* rightmost page of split group */
#define	BTP_HAS_GARBAGE   (1 << 6) /* page has LP_DEAD tuples */
#define	BTP_INCOMPLETE_SPLIT   (1 << 7) /* right sibling's downlink is missing */
#define	MAX_BT_CYCLE_ID   0xFF7F
#define	BTPageGetMeta(p)   ((BTMetaPageData *) PageGetContents(p))
#define	BTREE_METAPAGE   0 /* first page is meta */
#define	BTREE_MAGIC   0x053162 /* magic number in metapage */
#define	BTREE_VERSION   4 /* current version number */
#define	BTREE_MIN_VERSION   2 /* minimum supported version */
#define	BTREE_NOVAC_VERSION   3 /* version with all meta fields set */
#define	BTMaxItemSize(page)
#define	BTMaxItemSizeNoHeapTid(page)
#define	BTREE_MIN_FILLFACTOR   10
#define	BTREE_DEFAULT_FILLFACTOR   90
#define	BTREE_NONLEAF_FILLFACTOR   70
#define	BTREE_SINGLEVAL_FILLFACTOR   96
#define	P_NONE   0
#define	P_LEFTMOST(opaque)   ((opaque)->btpo_prev == P_NONE)
#define	P_RIGHTMOST(opaque)   ((opaque)->btpo_next == P_NONE)
#define	P_ISLEAF(opaque)   (((opaque)->btpo_flags & BTP_LEAF) != 0)
#define	P_ISROOT(opaque)   (((opaque)->btpo_flags & BTP_ROOT) != 0)
#define	P_ISDELETED(opaque)   (((opaque)->btpo_flags & BTP_DELETED) != 0)
#define	P_ISMETA(opaque)   (((opaque)->btpo_flags & BTP_META) != 0)
#define	P_ISHALFDEAD(opaque)   (((opaque)->btpo_flags & BTP_HALF_DEAD) != 0)
#define	P_IGNORE(opaque)   (((opaque)->btpo_flags & (BTP_DELETED|BTP_HALF_DEAD)) != 0)
#define	P_HAS_GARBAGE(opaque)   (((opaque)->btpo_flags & BTP_HAS_GARBAGE) != 0)
#define	P_INCOMPLETE_SPLIT(opaque)   (((opaque)->btpo_flags & BTP_INCOMPLETE_SPLIT) != 0)
#define	P_HIKEY   ((OffsetNumber) 1)
#define	P_FIRSTKEY   ((OffsetNumber) 2)
#define	P_FIRSTDATAKEY(opaque)   (P_RIGHTMOST(opaque) ? P_HIKEY : P_FIRSTKEY)
#define	INDEX_ALT_TID_MASK   INDEX_AM_RESERVED_BIT
#define	BT_RESERVED_OFFSET_MASK   0xF000
#define	BT_N_KEYS_OFFSET_MASK   0x0FFF
#define	BT_PIVOT_HEAP_TID_ATTR   0x1000
#define	BTreeTupleGetDownLink(itup)   ItemPointerGetBlockNumberNoCheck(&((itup)->t_tid))
#define	BTreeTupleSetDownLink(itup, blkno)   ItemPointerSetBlockNumber(&((itup)->t_tid), (blkno))
#define	BTreeTupleGetTopParent(itup)   ItemPointerGetBlockNumberNoCheck(&((itup)->t_tid))
#define	BTreeTupleSetTopParent(itup, blkno)
#define	BTreeTupleGetNAtts(itup, rel)
#define	BTreeTupleSetNAtts(itup, n)
#define	BTreeTupleGetHeapTID(itup)
#define	BTreeTupleSetAltHeapTID(itup)
#define	BTCommuteStrategyNumber(strat)   (BTMaxStrategyNumber + 1 - (strat))
#define	BTORDER_PROC   1
#define	BTSORTSUPPORT_PROC   2
#define	BTINRANGE_PROC   3
#define	BTNProcs   3
#define	BT_READ   BUFFER_LOCK_SHARE
#define	BT_WRITE   BUFFER_LOCK_EXCLUSIVE
#define	BTScanPosIsPinned(scanpos)
#define	BTScanPosUnpin(scanpos)
#define	BTScanPosUnpinIfPinned(scanpos)
#define	BTScanPosIsValid(scanpos)
#define	BTScanPosInvalidate(scanpos)
#define	SK_BT_REQFWD   0x00010000 /* required to continue forward scan */
#define	SK_BT_REQBKWD   0x00020000 /* required to continue backward scan */
#define	SK_BT_INDOPTION_SHIFT   24 /* must clear the above bits */
#define	SK_BT_DESC   (INDOPTION_DESC << SK_BT_INDOPTION_SHIFT)
#define	SK_BT_NULLS_FIRST   (INDOPTION_NULLS_FIRST << SK_BT_INDOPTION_SHIFT)
#define	BTGetFillFactor(relation)
#define	BTGetTargetPageFreeSpace(relation)   (BLCKSZ * (100 - BTGetFillFactor(relation)) / 100)
#define	PROGRESS_BTREE_PHASE_INDEXBUILD_TABLESCAN   2
#define	PROGRESS_BTREE_PHASE_PERFORMSORT_1   3
#define	PROGRESS_BTREE_PHASE_PERFORMSORT_2   4
#define	PROGRESS_BTREE_PHASE_LEAF_LOAD   5

Typedefs
typedef uint16	BTCycleId
typedef struct BTPageOpaqueData	BTPageOpaqueData
typedef BTPageOpaqueData *	BTPageOpaque
typedef struct BTMetaPageData	BTMetaPageData
typedef struct BTStackData	BTStackData
typedef BTStackData *	BTStack
typedef struct BTScanInsertData	BTScanInsertData
typedef BTScanInsertData *	BTScanInsert
typedef struct BTInsertStateData	BTInsertStateData
typedef BTInsertStateData *	BTInsertState
typedef struct BTScanPosItem	BTScanPosItem
typedef struct BTScanPosData	BTScanPosData
typedef BTScanPosData *	BTScanPos
typedef struct BTArrayKeyInfo	BTArrayKeyInfo
typedef struct BTScanOpaqueData	BTScanOpaqueData
typedef BTScanOpaqueData *	BTScanOpaque
typedef struct BTOptions	BTOptions

Functions
void	btbuildempty (Relation index)
bool	btinsert (Relation rel, Datum *values, bool *isnull, ItemPointer ht_ctid, Relation heapRel, IndexUniqueCheck checkUnique, struct IndexInfo *indexInfo)
IndexScanDesc	btbeginscan (Relation rel, int nkeys, int norderbys)
Size	btestimateparallelscan (void)
void	btinitparallelscan (void *target)
bool	btgettuple (IndexScanDesc scan, ScanDirection dir)
int64	btgetbitmap (IndexScanDesc scan, TIDBitmap *tbm)
void	btrescan (IndexScanDesc scan, ScanKey scankey, int nscankeys, ScanKey orderbys, int norderbys)
void	btparallelrescan (IndexScanDesc scan)
void	btendscan (IndexScanDesc scan)
void	btmarkpos (IndexScanDesc scan)
void	btrestrpos (IndexScanDesc scan)
IndexBulkDeleteResult *	btbulkdelete (IndexVacuumInfo *info, IndexBulkDeleteResult *stats, IndexBulkDeleteCallback callback, void *callback_state)
IndexBulkDeleteResult *	btvacuumcleanup (IndexVacuumInfo *info, IndexBulkDeleteResult *stats)
bool	btcanreturn (Relation index, int attno)
bool	_bt_parallel_seize (IndexScanDesc scan, BlockNumber *pageno)
void	_bt_parallel_release (IndexScanDesc scan, BlockNumber scan_page)
void	_bt_parallel_done (IndexScanDesc scan)
void	_bt_parallel_advance_array_keys (IndexScanDesc scan)
bool	_bt_doinsert (Relation rel, IndexTuple itup, IndexUniqueCheck checkUnique, Relation heapRel)
void	_bt_finish_split (Relation rel, Buffer lbuf, BTStack stack)
Buffer	_bt_getstackbuf (Relation rel, BTStack stack, BlockNumber child)
OffsetNumber	_bt_findsplitloc (Relation rel, Page page, OffsetNumber newitemoff, Size newitemsz, IndexTuple newitem, bool *newitemonleft)
void	_bt_initmetapage (Page page, BlockNumber rootbknum, uint32 level)
void	_bt_update_meta_cleanup_info (Relation rel, TransactionId oldestBtpoXact, float8 numHeapTuples)
void	_bt_upgrademetapage (Page page)
Buffer	_bt_getroot (Relation rel, int access)
Buffer	_bt_gettrueroot (Relation rel)
int	_bt_getrootheight (Relation rel)
bool	_bt_heapkeyspace (Relation rel)
void	_bt_checkpage (Relation rel, Buffer buf)
Buffer	_bt_getbuf (Relation rel, BlockNumber blkno, int access)
Buffer	_bt_relandgetbuf (Relation rel, Buffer obuf, BlockNumber blkno, int access)
void	_bt_relbuf (Relation rel, Buffer buf)
void	_bt_pageinit (Page page, Size size)
bool	_bt_page_recyclable (Page page)
void	_bt_delitems_vacuum (Relation rel, Buffer buf, OffsetNumber *deletable, int ndeletable)
void	_bt_delitems_delete (Relation rel, Buffer buf, OffsetNumber *deletable, int ndeletable, Relation heapRel)
int	_bt_pagedel (Relation rel, Buffer buf)
BTStack	_bt_search (Relation rel, BTScanInsert key, Buffer *bufP, int access, Snapshot snapshot)
Buffer	_bt_moveright (Relation rel, BTScanInsert key, Buffer buf, bool forupdate, BTStack stack, int access, Snapshot snapshot)
OffsetNumber	_bt_binsrch_insert (Relation rel, BTInsertState insertstate)
int32	_bt_compare (Relation rel, BTScanInsert key, Page page, OffsetNumber offnum)
bool	_bt_first (IndexScanDesc scan, ScanDirection dir)
bool	_bt_next (IndexScanDesc scan, ScanDirection dir)
Buffer	_bt_get_endpoint (Relation rel, uint32 level, bool rightmost, Snapshot snapshot)
BTScanInsert	_bt_mkscankey (Relation rel, IndexTuple itup)
void	_bt_freestack (BTStack stack)
void	_bt_preprocess_array_keys (IndexScanDesc scan)
void	_bt_start_array_keys (IndexScanDesc scan, ScanDirection dir)
bool	_bt_advance_array_keys (IndexScanDesc scan, ScanDirection dir)
void	_bt_mark_array_keys (IndexScanDesc scan)
void	_bt_restore_array_keys (IndexScanDesc scan)
void	_bt_preprocess_keys (IndexScanDesc scan)
bool	_bt_checkkeys (IndexScanDesc scan, IndexTuple tuple, int tupnatts, ScanDirection dir, bool *continuescan)
void	_bt_killitems (IndexScanDesc scan)
BTCycleId	_bt_vacuum_cycleid (Relation rel)
BTCycleId	_bt_start_vacuum (Relation rel)
void	_bt_end_vacuum (Relation rel)
void	_bt_end_vacuum_callback (int code, Datum arg)
Size	BTreeShmemSize (void)
void	BTreeShmemInit (void)
bytea *	btoptions (Datum reloptions, bool validate)
bool	btproperty (Oid index_oid, int attno, IndexAMProperty prop, const char *propname, bool *res, bool *isnull)
char *	btbuildphasename (int64 phasenum)
IndexTuple	_bt_truncate (Relation rel, IndexTuple lastleft, IndexTuple firstright, BTScanInsert itup_key)
int	_bt_keep_natts_fast (Relation rel, IndexTuple lastleft, IndexTuple firstright)
bool	_bt_check_natts (Relation rel, bool heapkeyspace, Page page, OffsetNumber offnum)
void	_bt_check_third_page (Relation rel, Relation heap, bool needheaptidspace, Page page, IndexTuple newtup)
bool	btvalidate (Oid opclassoid)
IndexBuildResult *	btbuild (Relation heap, Relation index, struct IndexInfo *indexInfo)
void	_bt_parallel_build_main (dsm_segment *seg, shm_toc *toc)

Macro Definition Documentation

BT_N_KEYS_OFFSET_MASK

#define BT_N_KEYS_OFFSET_MASK   0x0FFF

Definition at line 297 of file nbtree.h.

Referenced by _bt_check_natts().

BT_PIVOT_HEAP_TID_ATTR

#define BT_PIVOT_HEAP_TID_ATTR   0x1000

Definition at line 298 of file nbtree.h.

BT_READ

#define BT_READ   BUFFER_LOCK_SHARE

Definition at line 402 of file nbtree.h.

Referenced by _bt_check_unique(), _bt_first(), _bt_get_endpoint(), _bt_getroot(), _bt_getrootheight(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_is_page_halfdead(), _bt_killitems(), _bt_lock_branch_parent(), _bt_moveright(), _bt_pagedel(), _bt_readnextpage(), _bt_search(), _bt_unlink_halfdead_page(), _bt_update_meta_cleanup_info(), _bt_vacuum_needs_cleanup(), _bt_walk_left(), bt_rootdescend(), btvacuumpage(), palloc_btree_page(), and pgstat_btree_page().

BT_RESERVED_OFFSET_MASK

#define BT_RESERVED_OFFSET_MASK   0xF000

Definition at line 296 of file nbtree.h.

BT_WRITE

#define BT_WRITE   BUFFER_LOCK_EXCLUSIVE

Definition at line 403 of file nbtree.h.

Referenced by _bt_doinsert(), _bt_finish_split(), _bt_getbuf(), _bt_getroot(), _bt_getstackbuf(), _bt_insertonpg(), _bt_moveright(), _bt_newroot(), _bt_pagedel(), _bt_search(), _bt_split(), _bt_stepright(), _bt_unlink_halfdead_page(), and _bt_update_meta_cleanup_info().

BTCommuteStrategyNumber

#define BTCommuteStrategyNumber

(

strat

)

(BTMaxStrategyNumber + 1 - (strat))

Definition at line 374 of file nbtree.h.

Referenced by _bt_compare_scankey_args(), and _bt_fix_scankey_strategy().

BTGetFillFactor

#define BTGetFillFactor

(

relation

)

Value:

(AssertMacro(relation->rd_rel->relkind == RELKIND_INDEX && \
                 relation->rd_rel->relam == BTREE_AM_OID), \
     (relation)->rd_options ? \
     ((BTOptions *) (relation)->rd_options)->fillfactor : \
     BTREE_DEFAULT_FILLFACTOR)

Definition at line 691 of file nbtree.h.

Referenced by _bt_findsplitloc().

BTGetTargetPageFreeSpace

#define BTGetTargetPageFreeSpace

(

relation

)

(BLCKSZ * (100 - BTGetFillFactor(relation)) / 100)

Definition at line 697 of file nbtree.h.

Referenced by _bt_pagestate().

BTINRANGE_PROC

#define BTINRANGE_PROC   3

Definition at line 394 of file nbtree.h.

Referenced by assignProcTypes(), btvalidate(), and transformFrameOffset().

BTMaxItemSize

#define BTMaxItemSize

(

page

)

Value:

MAXALIGN_DOWN((PageGetPageSize(page) - \
                   MAXALIGN(SizeOfPageHeaderData + \
                            3*sizeof(ItemIdData)  + \
                            3*sizeof(ItemPointerData)) - \
                   MAXALIGN(sizeof(BTPageOpaqueData))) / 3)

Definition at line 148 of file nbtree.h.

Referenced by _bt_buildadd(), _bt_check_third_page(), _bt_findinsertloc(), and bt_target_page_check().

BTMaxItemSizeNoHeapTid

#define BTMaxItemSizeNoHeapTid

(

page

)

Value:

MAXALIGN_DOWN((PageGetPageSize(page) - \
                   MAXALIGN(SizeOfPageHeaderData + 3*sizeof(ItemIdData)) - \
                   MAXALIGN(sizeof(BTPageOpaqueData))) / 3)

Definition at line 154 of file nbtree.h.

Referenced by _bt_check_third_page(), and bt_target_page_check().

BTNProcs

#define BTNProcs   3

Definition at line 395 of file nbtree.h.

Referenced by bthandler().

BTORDER_PROC

#define BTORDER_PROC   1

Definition at line 392 of file nbtree.h.

Referenced by _bt_first(), _bt_mkscankey(), _bt_sort_array_elements(), assignProcTypes(), btvalidate(), ExecIndexBuildScanKeys(), ExecInitExprRec(), FinishSortSupportFunction(), load_rangetype_info(), lookup_type_cache(), match_clause_to_partition_key(), MJExamineQuals(), and RelationBuildPartitionKey().

BTP_DELETED

#define BTP_DELETED   (1 << 2) /* page has been deleted from tree */

Definition at line 74 of file nbtree.h.

Referenced by _bt_unlink_halfdead_page(), and btree_xlog_unlink_page().

BTP_HALF_DEAD

#define BTP_HALF_DEAD   (1 << 4) /* empty, but still in tree */

Definition at line 76 of file nbtree.h.

Referenced by _bt_mark_page_halfdead(), _bt_unlink_halfdead_page(), btree_xlog_mark_page_halfdead(), and btree_xlog_unlink_page().

BTP_HAS_GARBAGE

#define BTP_HAS_GARBAGE   (1 << 6) /* page has LP_DEAD tuples */

Definition at line 78 of file nbtree.h.

Referenced by _bt_check_unique(), _bt_delitems_delete(), _bt_delitems_vacuum(), _bt_killitems(), _bt_split(), btree_mask(), btree_xlog_delete(), and btree_xlog_vacuum().

BTP_INCOMPLETE_SPLIT

#define BTP_INCOMPLETE_SPLIT   (1 << 7) /* right sibling's downlink is missing */

Definition at line 79 of file nbtree.h.

Referenced by _bt_clear_incomplete_split(), _bt_insertonpg(), _bt_newroot(), _bt_split(), and btree_xlog_split().

BTP_LEAF

#define BTP_LEAF   (1 << 0) /* leaf page, i.e. not internal page */

Definition at line 72 of file nbtree.h.

Referenced by _bt_blnewpage(), _bt_getroot(), btree_xlog_mark_page_halfdead(), btree_xlog_newroot(), btree_xlog_split(), and btree_xlog_unlink_page().

BTP_META

#define BTP_META   (1 << 3) /* meta-page */

Definition at line 75 of file nbtree.h.

Referenced by _bt_initmetapage(), _bt_restore_meta(), and _bt_upgrademetapage().

BTP_ROOT

#define BTP_ROOT   (1 << 1) /* root page (has no parent) */

Definition at line 73 of file nbtree.h.

Referenced by _bt_getroot(), _bt_newroot(), _bt_split(), _bt_uppershutdown(), and btree_xlog_newroot().

BTP_SPLIT_END

#define BTP_SPLIT_END   (1 << 5) /* rightmost page of split group */

Definition at line 77 of file nbtree.h.

Referenced by _bt_split(), btree_mask(), and btvacuumpage().

BTPageGetMeta

#define BTPageGetMeta

(

p

)

((BTMetaPageData *) PageGetContents(p))

Definition at line 113 of file nbtree.h.

Referenced by _bt_finish_split(), _bt_getmeta(), _bt_gettrueroot(), _bt_initmetapage(), _bt_insertonpg(), _bt_newroot(), _bt_restore_meta(), _bt_unlink_halfdead_page(), _bt_update_meta_cleanup_info(), _bt_upgrademetapage(), _bt_vacuum_needs_cleanup(), bt_check_every_level(), bt_metap(), palloc_btree_page(), and pgstatindex_impl().

BTREE_DEFAULT_FILLFACTOR

#define BTREE_DEFAULT_FILLFACTOR   90

Definition at line 170 of file nbtree.h.

BTREE_MAGIC

#define BTREE_MAGIC   0x053162 /* magic number in metapage */

Definition at line 133 of file nbtree.h.

Referenced by _bt_getmeta(), _bt_getroot(), _bt_getrootheight(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_initmetapage(), _bt_restore_meta(), and palloc_btree_page().

BTREE_METAPAGE

#define BTREE_METAPAGE   0 /* first page is meta */

Definition at line 132 of file nbtree.h.

Referenced by _bt_finish_split(), _bt_getroot(), _bt_getrootheight(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_insertonpg(), _bt_leafbuild(), _bt_newroot(), _bt_restore_meta(), _bt_unlink_halfdead_page(), _bt_update_meta_cleanup_info(), _bt_uppershutdown(), _bt_vacuum_needs_cleanup(), bt_check_every_level(), btbuildempty(), btvacuumscan(), palloc_btree_page(), and pgstat_relation().

BTREE_MIN_FILLFACTOR

#define BTREE_MIN_FILLFACTOR   10

Definition at line 169 of file nbtree.h.

BTREE_MIN_VERSION

#define BTREE_MIN_VERSION   2 /* minimum supported version */

Definition at line 135 of file nbtree.h.

Referenced by _bt_getmeta(), _bt_getroot(), _bt_getrootheight(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_upgrademetapage(), and palloc_btree_page().

BTREE_NONLEAF_FILLFACTOR

#define BTREE_NONLEAF_FILLFACTOR   70

Definition at line 171 of file nbtree.h.

Referenced by _bt_findsplitloc(), and _bt_pagestate().

BTREE_NOVAC_VERSION

#define BTREE_NOVAC_VERSION   3 /* version with all meta fields set */

Definition at line 136 of file nbtree.h.

Referenced by _bt_check_third_page(), _bt_getroot(), _bt_heapkeyspace(), _bt_insertonpg(), _bt_newroot(), _bt_restore_meta(), _bt_unlink_halfdead_page(), _bt_update_meta_cleanup_info(), _bt_upgrademetapage(), _bt_vacuum_needs_cleanup(), and bt_metap().

BTREE_SINGLEVAL_FILLFACTOR

#define BTREE_SINGLEVAL_FILLFACTOR   96

Definition at line 172 of file nbtree.h.

Referenced by _bt_findsplitloc().

BTREE_VERSION

#define BTREE_VERSION   4 /* current version number */

Definition at line 134 of file nbtree.h.

Referenced by _bt_check_third_page(), _bt_getmeta(), _bt_getroot(), _bt_getrootheight(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_initmetapage(), and palloc_btree_page().

BTreeTupleGetDownLink

#define BTreeTupleGetDownLink

(

itup

)

ItemPointerGetBlockNumberNoCheck(&((itup)->t_tid))

Definition at line 301 of file nbtree.h.

Referenced by _bt_get_endpoint(), _bt_getstackbuf(), _bt_mark_page_halfdead(), _bt_search(), _bt_unlink_halfdead_page(), bt_check_level_from_leftmost(), bt_downlink_missing_check(), bt_target_page_check(), and btree_xlog_mark_page_halfdead().

BTreeTupleGetHeapTID

#define BTreeTupleGetHeapTID

(

itup

)

Value:

( \
      (itup)->t_info & INDEX_ALT_TID_MASK && \
      (ItemPointerGetOffsetNumberNoCheck(&(itup)->t_tid) & BT_PIVOT_HEAP_TID_ATTR) != 0 ? \
      ( \
        (ItemPointer) (((char *) (itup) + IndexTupleSize(itup)) - \
                       sizeof(ItemPointerData)) \
      ) \
      : (itup)->t_info & INDEX_ALT_TID_MASK ? NULL : (ItemPointer) &((itup)->t_tid) \
    )

Definition at line 346 of file nbtree.h.

Referenced by _bt_check_natts(), _bt_compare(), _bt_mkscankey(), bt_target_page_check(), and BTreeTupleGetHeapTIDCareful().

BTreeTupleGetNAtts

#define BTreeTupleGetNAtts	(		itup,
			rel
	)

Value:

( \
        (itup)->t_info & INDEX_ALT_TID_MASK ? \
        ( \
            ItemPointerGetOffsetNumberNoCheck(&(itup)->t_tid) & BT_N_KEYS_OFFSET_MASK \
        ) \
        : \
        IndexRelationGetNumberOfAttributes(rel) \
    )

Definition at line 327 of file nbtree.h.

Referenced by _bt_buildadd(), _bt_check_natts(), _bt_checkkeys(), _bt_compare(), _bt_insertonpg(), _bt_mkscankey(), _bt_newroot(), _bt_readpage(), _bt_split(), _bt_truncate(), _bt_uppershutdown(), and bt_target_page_check().

BTreeTupleGetTopParent

#define BTreeTupleGetTopParent

(

itup

)

ItemPointerGetBlockNumberNoCheck(&((itup)->t_tid))

Definition at line 312 of file nbtree.h.

Referenced by _bt_unlink_halfdead_page(), and bt_downlink_missing_check().

BTreeTupleSetAltHeapTID

#define BTreeTupleSetAltHeapTID

(

itup

)

Value:

do { \
        Assert((itup)->t_info & INDEX_ALT_TID_MASK); \
        ItemPointerSetOffsetNumber(&(itup)->t_tid, \
                                   ItemPointerGetOffsetNumberNoCheck(&(itup)->t_tid) | BT_PIVOT_HEAP_TID_ATTR); \
    } while(0)

Definition at line 360 of file nbtree.h.

Referenced by _bt_truncate().

BTreeTupleSetDownLink

#define BTreeTupleSetDownLink	(		itup,
			blkno
	)		ItemPointerSetBlockNumber(&((itup)->t_tid), (blkno))

Definition at line 303 of file nbtree.h.

Referenced by _bt_buildadd(), _bt_insert_parent(), _bt_mark_page_halfdead(), _bt_newroot(), _bt_uppershutdown(), and btree_xlog_mark_page_halfdead().

BTreeTupleSetNAtts

#define BTreeTupleSetNAtts	(		itup,
			n
	)

Value:

do { \
        (itup)->t_info |= INDEX_ALT_TID_MASK; \
        ItemPointerSetOffsetNumber(&(itup)->t_tid, (n) & BT_N_KEYS_OFFSET_MASK); \
    } while(0)

Definition at line 336 of file nbtree.h.

Referenced by _bt_buildadd(), _bt_newroot(), _bt_pgaddtup(), _bt_sortaddtup(), and _bt_truncate().

BTreeTupleSetTopParent

#define BTreeTupleSetTopParent	(		itup,
			blkno
	)

Value:

do { \
        ItemPointerSetBlockNumber(&((itup)->t_tid), (blkno)); \
        BTreeTupleSetNAtts((itup), 0); \
    } while(0)

Definition at line 314 of file nbtree.h.

Referenced by _bt_mark_page_halfdead(), _bt_unlink_halfdead_page(), btree_xlog_mark_page_halfdead(), and btree_xlog_unlink_page().

BTScanPosInvalidate

#define BTScanPosInvalidate

(

scanpos

)

Value:

do { \
        (scanpos).currPage = InvalidBlockNumber; \
        (scanpos).nextPage = InvalidBlockNumber; \
        (scanpos).buf = InvalidBuffer; \
        (scanpos).lsn = InvalidXLogRecPtr; \
        (scanpos).nextTupleOffset = 0; \
    } while (0);

Definition at line 609 of file nbtree.h.

Referenced by _bt_endpoint(), _bt_first(), _bt_readnextpage(), _bt_steppage(), btbeginscan(), btmarkpos(), btrescan(), and btrestrpos().

BTScanPosIsPinned

#define BTScanPosIsPinned

(

scanpos

)

Value:

( \
    AssertMacro(BlockNumberIsValid((scanpos).currPage) || \
                !BufferIsValid((scanpos).buf)), \
    BufferIsValid((scanpos).buf) \
)

Definition at line 586 of file nbtree.h.

Referenced by _bt_killitems(), _bt_readnextpage(), _bt_readpage(), _bt_steppage(), and btrestrpos().

BTScanPosIsValid

#define BTScanPosIsValid

(

scanpos

)

Value:

( \
    AssertMacro(BlockNumberIsValid((scanpos).currPage) || \
                !BufferIsValid((scanpos).buf)), \
    BlockNumberIsValid((scanpos).currPage) \
)

Definition at line 603 of file nbtree.h.

Referenced by _bt_first(), _bt_killitems(), _bt_steppage(), btendscan(), btgettuple(), btmarkpos(), btrescan(), and btrestrpos().

BTScanPosUnpin

#define BTScanPosUnpin

(

scanpos

)

Value:

do { \
        ReleaseBuffer((scanpos).buf); \
        (scanpos).buf = InvalidBuffer; \
    } while (0)

Definition at line 592 of file nbtree.h.

BTScanPosUnpinIfPinned

#define BTScanPosUnpinIfPinned

(

scanpos

)

Value:

do { \
        if (BTScanPosIsPinned(scanpos)) \
            BTScanPosUnpin(scanpos); \
    } while (0)

Definition at line 597 of file nbtree.h.

Referenced by _bt_readnextpage(), _bt_steppage(), btendscan(), btmarkpos(), btrescan(), and btrestrpos().

BTSORTSUPPORT_PROC

#define BTSORTSUPPORT_PROC   2

Definition at line 393 of file nbtree.h.

Referenced by assignProcTypes(), btvalidate(), FinishSortSupportFunction(), and MJExamineQuals().

INDEX_ALT_TID_MASK

#define INDEX_ALT_TID_MASK   INDEX_AM_RESERVED_BIT

Definition at line 293 of file nbtree.h.

Referenced by _bt_check_natts().

MAX_BT_CYCLE_ID

#define MAX_BT_CYCLE_ID   0xFF7F

Definition at line 88 of file nbtree.h.

Referenced by _bt_start_vacuum().

P_FIRSTDATAKEY

#define P_FIRSTDATAKEY

(

opaque

)

(P_RIGHTMOST(opaque) ? P_HIKEY : P_FIRSTKEY)

Definition at line 220 of file nbtree.h.

Referenced by _bt_binsrch(), _bt_binsrch_insert(), _bt_check_natts(), _bt_check_unique(), _bt_compare(), _bt_doinsert(), _bt_endpoint(), _bt_findsplitloc(), _bt_get_endpoint(), _bt_getstackbuf(), _bt_insertonpg(), _bt_killitems(), _bt_lock_branch_parent(), _bt_mark_page_halfdead(), _bt_pagedel(), _bt_pgaddtup(), _bt_readnextpage(), _bt_readpage(), _bt_split(), _bt_unlink_halfdead_page(), _bt_vacuum_one_page(), bt_check_level_from_leftmost(), bt_downlink_check(), bt_downlink_missing_check(), bt_right_page_check_scankey(), bt_target_page_check(), btree_xlog_split(), btvacuumpage(), invariant_l_nontarget_offset(), invariant_l_offset(), offset_is_negative_infinity(), palloc_btree_page(), and pgstat_btree_page().

P_FIRSTKEY

#define P_FIRSTKEY   ((OffsetNumber) 2)

Definition at line 219 of file nbtree.h.

Referenced by _bt_afternewitemoff(), _bt_buildadd(), _bt_newroot(), _bt_slideleft(), and _bt_sortaddtup().

P_HAS_GARBAGE

#define P_HAS_GARBAGE

(

opaque

)

(((opaque)->btpo_flags & BTP_HAS_GARBAGE) != 0)

Definition at line 196 of file nbtree.h.

Referenced by _bt_findinsertloc(), and palloc_btree_page().

P_HIKEY

#define P_HIKEY   ((OffsetNumber) 1)

Definition at line 218 of file nbtree.h.

Referenced by _bt_buildadd(), _bt_check_natts(), _bt_check_unique(), _bt_findinsertloc(), _bt_findsplitloc(), _bt_insert_parent(), _bt_mark_page_halfdead(), _bt_moveright(), _bt_newroot(), _bt_pagedel(), _bt_pagestate(), _bt_readpage(), _bt_slideleft(), _bt_split(), _bt_strategy(), _bt_unlink_halfdead_page(), bt_downlink_missing_check(), bt_target_page_check(), btree_xlog_mark_page_halfdead(), btree_xlog_split(), btree_xlog_unlink_page(), and palloc_btree_page().

P_IGNORE

#define P_IGNORE

(

opaque

)

(((opaque)->btpo_flags & (BTP_DELETED|BTP_HALF_DEAD)) != 0)

Definition at line 195 of file nbtree.h.

Referenced by _bt_check_natts(), _bt_check_unique(), _bt_doinsert(), _bt_get_endpoint(), _bt_getroot(), _bt_getstackbuf(), _bt_gettrueroot(), _bt_moveright(), _bt_readnextpage(), _bt_stepright(), bt_check_level_from_leftmost(), bt_downlink_missing_check(), bt_right_page_check_scankey(), bt_target_page_check(), btvacuumpage(), GetBTPageStatistics(), pgstat_btree_page(), and pgstatindex_impl().

P_INCOMPLETE_SPLIT

#define P_INCOMPLETE_SPLIT

(

opaque

)

(((opaque)->btpo_flags & BTP_INCOMPLETE_SPLIT) != 0)

Definition at line 197 of file nbtree.h.

Referenced by _bt_clear_incomplete_split(), _bt_findinsertloc(), _bt_finish_split(), _bt_getstackbuf(), _bt_insertonpg(), _bt_lock_branch_parent(), _bt_moveright(), _bt_newroot(), _bt_pagedel(), _bt_stepright(), and bt_check_level_from_leftmost().

P_ISDELETED

#define P_ISDELETED

(

opaque

)

(((opaque)->btpo_flags & BTP_DELETED) != 0)

Definition at line 192 of file nbtree.h.

Referenced by _bt_mark_page_halfdead(), _bt_page_recyclable(), _bt_pagedel(), _bt_unlink_halfdead_page(), _bt_walk_left(), bt_check_level_from_leftmost(), bt_downlink_check(), bt_downlink_missing_check(), bt_page_items(), bt_page_items_bytea(), btree_mask(), btvacuumpage(), GetBTPageStatistics(), palloc_btree_page(), and pgstatindex_impl().

P_ISHALFDEAD

#define P_ISHALFDEAD

(

opaque

)

(((opaque)->btpo_flags & BTP_HALF_DEAD) != 0)

Definition at line 194 of file nbtree.h.

Referenced by _bt_is_page_halfdead(), _bt_mark_page_halfdead(), _bt_pagedel(), _bt_unlink_halfdead_page(), bt_downlink_missing_check(), btvacuumpage(), and palloc_btree_page().

P_ISLEAF

#define P_ISLEAF

(

opaque

)

(((opaque)->btpo_flags & BTP_LEAF) != 0)

Definition at line 190 of file nbtree.h.

Referenced by _bt_binsrch(), _bt_binsrch_insert(), _bt_check_natts(), _bt_check_third_page(), _bt_compare(), _bt_doinsert(), _bt_endpoint(), _bt_findinsertloc(), _bt_findsplitloc(), _bt_insertonpg(), _bt_mark_page_halfdead(), _bt_pagedel(), _bt_pgaddtup(), _bt_search(), _bt_sortaddtup(), _bt_split(), _bt_unlink_halfdead_page(), _bt_vacuum_one_page(), bt_check_level_from_leftmost(), bt_downlink_missing_check(), bt_right_page_check_scankey(), bt_target_page_check(), btree_mask(), btvacuumpage(), GetBTPageStatistics(), invariant_l_nontarget_offset(), invariant_l_offset(), offset_is_negative_infinity(), palloc_btree_page(), pgstat_btree_page(), and pgstatindex_impl().

P_ISMETA

#define P_ISMETA

(

opaque

)

(((opaque)->btpo_flags & BTP_META) != 0)

Definition at line 193 of file nbtree.h.

Referenced by _bt_getmeta(), _bt_gettrueroot(), bt_page_items_bytea(), and palloc_btree_page().

P_ISROOT

#define P_ISROOT

(

opaque

)

(((opaque)->btpo_flags & BTP_ROOT) != 0)

Definition at line 191 of file nbtree.h.

Referenced by _bt_insertonpg(), _bt_lock_branch_parent(), _bt_mark_page_halfdead(), _bt_pagedel(), _bt_unlink_halfdead_page(), bt_check_level_from_leftmost(), bt_downlink_missing_check(), and GetBTPageStatistics().

P_LEFTMOST

#define P_LEFTMOST

(

opaque

)

((opaque)->btpo_prev == P_NONE)

Definition at line 188 of file nbtree.h.

Referenced by _bt_buildadd(), _bt_finish_split(), _bt_getroot(), _bt_insertonpg(), _bt_pagedel(), _bt_uppershutdown(), _bt_walk_left(), and bt_check_level_from_leftmost().

P_NONE

#define P_NONE   0

Definition at line 182 of file nbtree.h.

Referenced by _bt_blnewpage(), _bt_buildadd(), _bt_first(), _bt_get_endpoint(), _bt_getroot(), _bt_getrootheight(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_lock_branch_parent(), _bt_newroot(), _bt_parallel_seize(), _bt_readnextpage(), _bt_unlink_halfdead_page(), _bt_uppershutdown(), bt_check_every_level(), bt_check_level_from_leftmost(), btbuildempty(), btree_xlog_newroot(), btree_xlog_split(), btree_xlog_unlink_page(), btvacuumpage(), and pgstatindex_impl().

P_RIGHTMOST

#define P_RIGHTMOST

(

opaque

)

((opaque)->btpo_next == P_NONE)

Definition at line 189 of file nbtree.h.

Referenced by _bt_check_natts(), _bt_check_unique(), _bt_doinsert(), _bt_endpoint(), _bt_findinsertloc(), _bt_findsplitloc(), _bt_finish_split(), _bt_get_endpoint(), _bt_getroot(), _bt_getstackbuf(), _bt_gettrueroot(), _bt_insertonpg(), _bt_lock_branch_parent(), _bt_mark_page_halfdead(), _bt_moveright(), _bt_pagedel(), _bt_readpage(), _bt_split(), _bt_stepright(), _bt_unlink_halfdead_page(), _bt_walk_left(), bt_check_level_from_leftmost(), bt_downlink_missing_check(), bt_right_page_check_scankey(), bt_target_page_check(), btvacuumpage(), and palloc_btree_page().

PROGRESS_BTREE_PHASE_INDEXBUILD_TABLESCAN

#define PROGRESS_BTREE_PHASE_INDEXBUILD_TABLESCAN   2

Definition at line 705 of file nbtree.h.

Referenced by _bt_spools_heapscan(), and btbuildphasename().

PROGRESS_BTREE_PHASE_LEAF_LOAD

#define PROGRESS_BTREE_PHASE_LEAF_LOAD   5

Definition at line 708 of file nbtree.h.

Referenced by _bt_leafbuild(), and btbuildphasename().

PROGRESS_BTREE_PHASE_PERFORMSORT_1

#define PROGRESS_BTREE_PHASE_PERFORMSORT_1   3

Definition at line 706 of file nbtree.h.

Referenced by _bt_leafbuild(), and btbuildphasename().

PROGRESS_BTREE_PHASE_PERFORMSORT_2

#define PROGRESS_BTREE_PHASE_PERFORMSORT_2   4

Definition at line 707 of file nbtree.h.

Referenced by _bt_leafbuild(), and btbuildphasename().

SK_BT_DESC

#define SK_BT_DESC   (INDOPTION_DESC << SK_BT_INDOPTION_SHIFT)

Definition at line 680 of file nbtree.h.

Referenced by _bt_check_rowcompare(), _bt_compare(), _bt_compare_scankey_args(), _bt_first(), _bt_fix_scankey_strategy(), _bt_load(), tuplesort_begin_cluster(), and tuplesort_begin_index_btree().

SK_BT_INDOPTION_SHIFT

#define SK_BT_INDOPTION_SHIFT   24 /* must clear the above bits */

Definition at line 679 of file nbtree.h.

Referenced by _bt_fix_scankey_strategy(), and _bt_mkscankey().

SK_BT_NULLS_FIRST

#define SK_BT_NULLS_FIRST   (INDOPTION_NULLS_FIRST << SK_BT_INDOPTION_SHIFT)

Definition at line 681 of file nbtree.h.

Referenced by _bt_check_rowcompare(), _bt_checkkeys(), _bt_compare(), _bt_compare_scankey_args(), _bt_first(), _bt_fix_scankey_strategy(), _bt_load(), tuplesort_begin_cluster(), and tuplesort_begin_index_btree().

SK_BT_REQBKWD

#define SK_BT_REQBKWD   0x00020000 /* required to continue backward scan */

Definition at line 678 of file nbtree.h.

Referenced by _bt_check_rowcompare(), _bt_checkkeys(), and _bt_mark_scankey_required().

SK_BT_REQFWD

#define SK_BT_REQFWD   0x00010000 /* required to continue forward scan */

Definition at line 677 of file nbtree.h.

Referenced by _bt_check_rowcompare(), _bt_checkkeys(), and _bt_mark_scankey_required().

Typedef Documentation

BTArrayKeyInfo

typedef struct BTArrayKeyInfo BTArrayKeyInfo

BTCycleId

typedef uint16 BTCycleId

Definition at line 28 of file nbtree.h.

BTInsertState

typedef BTInsertStateData* BTInsertState

Definition at line 512 of file nbtree.h.

BTInsertStateData

typedef struct BTInsertStateData BTInsertStateData

BTMetaPageData

typedef struct BTMetaPageData BTMetaPageData

BTOptions

typedef struct BTOptions BTOptions

BTPageOpaque

typedef BTPageOpaqueData* BTPageOpaque

Definition at line 69 of file nbtree.h.

BTPageOpaqueData

typedef struct BTPageOpaqueData BTPageOpaqueData

BTScanInsert

typedef BTScanInsertData* BTScanInsert

Definition at line 480 of file nbtree.h.

BTScanInsertData

typedef struct BTScanInsertData BTScanInsertData

BTScanOpaque

typedef BTScanOpaqueData* BTScanOpaque

Definition at line 670 of file nbtree.h.

BTScanOpaqueData

typedef struct BTScanOpaqueData BTScanOpaqueData

BTScanPos

typedef BTScanPosData* BTScanPos

Definition at line 584 of file nbtree.h.

BTScanPosData

typedef struct BTScanPosData BTScanPosData

BTScanPosItem

typedef struct BTScanPosItem BTScanPosItem

BTStack

typedef BTStackData* BTStack

Definition at line 422 of file nbtree.h.

BTStackData

typedef struct BTStackData BTStackData

Function Documentation

_bt_advance_array_keys()

bool _bt_advance_array_keys	(	IndexScanDesc	scan,
		ScanDirection	dir
	)

Definition at line 533 of file nbtutils.c.

References _bt_parallel_advance_array_keys(), BTScanOpaqueData::arrayKeyData, BTScanOpaqueData::arrayKeys, BTArrayKeyInfo::cur_elem, BTArrayKeyInfo::elem_values, i, BTArrayKeyInfo::num_elems, BTScanOpaqueData::numArrayKeys, IndexScanDescData::opaque, IndexScanDescData::parallel_scan, BTArrayKeyInfo::scan_key, ScanDirectionIsBackward, and ScanKeyData::sk_argument.

Referenced by btgetbitmap(), and btgettuple().

{
    BTScanOpaque so = (BTScanOpaque) scan->opaque;
    bool        found = false;
    int         i;

    /*
     * We must advance the last array key most quickly, since it will
     * correspond to the lowest-order index column among the available
     * qualifications. This is necessary to ensure correct ordering of output
     * when there are multiple array keys.
     */
    for (i = so->numArrayKeys - 1; i >= 0; i--)
    {
        BTArrayKeyInfo *curArrayKey = &so->arrayKeys[i];
        ScanKey     skey = &so->arrayKeyData[curArrayKey->scan_key];
        int         cur_elem = curArrayKey->cur_elem;
        int         num_elems = curArrayKey->num_elems;

        if (ScanDirectionIsBackward(dir))
        {
            if (--cur_elem < 0)
            {
                cur_elem = num_elems - 1;
                found = false;  /* need to advance next array key */
            }
            else
                found = true;
        }
        else
        {
            if (++cur_elem >= num_elems)
            {
                cur_elem = 0;
                found = false;  /* need to advance next array key */
            }
            else
                found = true;
        }

        curArrayKey->cur_elem = cur_elem;
        skey->sk_argument = curArrayKey->elem_values[cur_elem];
        if (found)
            break;
    }

    /* advance parallel scan */
    if (scan->parallel_scan != NULL)
        _bt_parallel_advance_array_keys(scan);

    return found;
}

_bt_binsrch_insert()

OffsetNumber _bt_binsrch_insert	(	Relation	rel,
		BTInsertState	insertstate
	)

Definition at line 440 of file nbtsearch.c.

References _bt_compare(), Assert, BTInsertStateData::bounds_valid, BTInsertStateData::buf, BufferGetPage, InvalidOffsetNumber, BTInsertStateData::itup_key, sort-test::key, BTInsertStateData::low, BTScanInsertData::nextkey, P_FIRSTDATAKEY, P_ISLEAF, PageGetMaxOffsetNumber, PageGetSpecialPointer, BTInsertStateData::stricthigh, and unlikely.

Referenced by _bt_check_unique(), _bt_findinsertloc(), and bt_rootdescend().

{
    BTScanInsert key = insertstate->itup_key;
    Page        page;
    BTPageOpaque opaque;
    OffsetNumber low,
                high,
                stricthigh;
    int32       result,
                cmpval;

    page = BufferGetPage(insertstate->buf);
    opaque = (BTPageOpaque) PageGetSpecialPointer(page);

    Assert(P_ISLEAF(opaque));
    Assert(!key->nextkey);

    if (!insertstate->bounds_valid)
    {
        /* Start new binary search */
        low = P_FIRSTDATAKEY(opaque);
        high = PageGetMaxOffsetNumber(page);
    }
    else
    {
        /* Restore result of previous binary search against same page */
        low = insertstate->low;
        high = insertstate->stricthigh;
    }

    /* If there are no keys on the page, return the first available slot */
    if (unlikely(high < low))
    {
        /* Caller can't reuse bounds */
        insertstate->low = InvalidOffsetNumber;
        insertstate->stricthigh = InvalidOffsetNumber;
        insertstate->bounds_valid = false;
        return low;
    }

    /*
     * Binary search to find the first key on the page >= scan key. (nextkey
     * is always false when inserting).
     *
     * The loop invariant is: all slots before 'low' are < scan key, all slots
     * at or after 'high' are >= scan key.  'stricthigh' is > scan key, and is
     * maintained to save additional search effort for caller.
     *
     * We can fall out when high == low.
     */
    if (!insertstate->bounds_valid)
        high++;                 /* establish the loop invariant for high */
    stricthigh = high;          /* high initially strictly higher */

    cmpval = 1;                 /* !nextkey comparison value */

    while (high > low)
    {
        OffsetNumber mid = low + ((high - low) / 2);

        /* We have low <= mid < high, so mid points at a real slot */

        result = _bt_compare(rel, key, page, mid);

        if (result >= cmpval)
            low = mid + 1;
        else
        {
            high = mid;
            if (result != 0)
                stricthigh = high;
        }
    }

    /*
     * On a leaf page, a binary search always returns the first key >= scan
     * key (at least in !nextkey case), which could be the last slot + 1. This
     * is also the lower bound of cached search.
     *
     * stricthigh may also be the last slot + 1, which prevents caller from
     * using bounds directly, but is still useful to us if we're called a
     * second time with cached bounds (cached low will be < stricthigh when
     * that happens).
     */
    insertstate->low = low;
    insertstate->stricthigh = stricthigh;
    insertstate->bounds_valid = true;

    return low;
}

_bt_check_natts()

bool _bt_check_natts	(	Relation	rel,
		bool	heapkeyspace,
		Page	page,
		OffsetNumber	offnum
	)

Definition at line 2373 of file nbtutils.c.

References Assert, BT_N_KEYS_OFFSET_MASK, BTreeTupleGetHeapTID, BTreeTupleGetNAtts, FirstOffsetNumber, INDEX_ALT_TID_MASK, INDEX_MAX_KEYS, IndexRelationGetNumberOfAttributes, IndexRelationGetNumberOfKeyAttributes, ItemPointerGetOffsetNumber, P_FIRSTDATAKEY, P_HIKEY, P_IGNORE, P_ISLEAF, P_RIGHTMOST, PageGetItem, PageGetItemId, PageGetMaxOffsetNumber, PageGetSpecialPointer, StaticAssertStmt, IndexTupleData::t_info, and IndexTupleData::t_tid.

Referenced by _bt_compare(), and bt_target_page_check().

{
    int16       natts = IndexRelationGetNumberOfAttributes(rel);
    int16       nkeyatts = IndexRelationGetNumberOfKeyAttributes(rel);
    BTPageOpaque opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    IndexTuple  itup;
    int         tupnatts;

    /*
     * We cannot reliably test a deleted or half-dead page, since they have
     * dummy high keys
     */
    if (P_IGNORE(opaque))
        return true;

    Assert(offnum >= FirstOffsetNumber &&
           offnum <= PageGetMaxOffsetNumber(page));

    /*
     * Mask allocated for number of keys in index tuple must be able to fit
     * maximum possible number of index attributes
     */
    StaticAssertStmt(BT_N_KEYS_OFFSET_MASK >= INDEX_MAX_KEYS,
                     "BT_N_KEYS_OFFSET_MASK can't fit INDEX_MAX_KEYS");

    itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, offnum));
    tupnatts = BTreeTupleGetNAtts(itup, rel);

    if (P_ISLEAF(opaque))
    {
        if (offnum >= P_FIRSTDATAKEY(opaque))
        {
            /*
             * Non-pivot tuples currently never use alternative heap TID
             * representation -- even those within heapkeyspace indexes
             */
            if ((itup->t_info & INDEX_ALT_TID_MASK) != 0)
                return false;

            /*
             * Leaf tuples that are not the page high key (non-pivot tuples)
             * should never be truncated.  (Note that tupnatts must have been
             * inferred, rather than coming from an explicit on-disk
             * representation.)
             */
            return tupnatts == natts;
        }
        else
        {
            /*
             * Rightmost page doesn't contain a page high key, so tuple was
             * checked above as ordinary leaf tuple
             */
            Assert(!P_RIGHTMOST(opaque));

            /*
             * !heapkeyspace high key tuple contains only key attributes. Note
             * that tupnatts will only have been explicitly represented in
             * !heapkeyspace indexes that happen to have non-key attributes.
             */
            if (!heapkeyspace)
                return tupnatts == nkeyatts;

            /* Use generic heapkeyspace pivot tuple handling */
        }
    }
    else                        /* !P_ISLEAF(opaque) */
    {
        if (offnum == P_FIRSTDATAKEY(opaque))
        {
            /*
             * The first tuple on any internal page (possibly the first after
             * its high key) is its negative infinity tuple.  Negative
             * infinity tuples are always truncated to zero attributes.  They
             * are a particular kind of pivot tuple.
             */
            if (heapkeyspace)
                return tupnatts == 0;

            /*
             * The number of attributes won't be explicitly represented if the
             * negative infinity tuple was generated during a page split that
             * occurred with a version of Postgres before v11.  There must be
             * a problem when there is an explicit representation that is
             * non-zero, or when there is no explicit representation and the
             * tuple is evidently not a pre-pg_upgrade tuple.
             *
             * Prior to v11, downlinks always had P_HIKEY as their offset. Use
             * that to decide if the tuple is a pre-v11 tuple.
             */
            return tupnatts == 0 ||
                ((itup->t_info & INDEX_ALT_TID_MASK) == 0 &&
                 ItemPointerGetOffsetNumber(&(itup->t_tid)) == P_HIKEY);
        }
        else
        {
            /*
             * !heapkeyspace downlink tuple with separator key contains only
             * key attributes.  Note that tupnatts will only have been
             * explicitly represented in !heapkeyspace indexes that happen to
             * have non-key attributes.
             */
            if (!heapkeyspace)
                return tupnatts == nkeyatts;

            /* Use generic heapkeyspace pivot tuple handling */
        }

    }

    /* Handle heapkeyspace pivot tuples (excluding minus infinity items) */
    Assert(heapkeyspace);

    /*
     * Explicit representation of the number of attributes is mandatory with
     * heapkeyspace index pivot tuples, regardless of whether or not there are
     * non-key attributes.
     */
    if ((itup->t_info & INDEX_ALT_TID_MASK) == 0)
        return false;

    /*
     * Heap TID is a tiebreaker key attribute, so it cannot be untruncated
     * when any other key attribute is truncated
     */
    if (BTreeTupleGetHeapTID(itup) != NULL && tupnatts != nkeyatts)
        return false;

    /*
     * Pivot tuple must have at least one untruncated key attribute (minus
     * infinity pivot tuples are the only exception).  Pivot tuples can never
     * represent that there is a value present for a key attribute that
     * exceeds pg_index.indnkeyatts for the index.
     */
    return tupnatts > 0 && tupnatts <= nkeyatts;
}

_bt_check_third_page()

void _bt_check_third_page	(	Relation	rel,
		Relation	heap,
		bool	needheaptidspace,
		Page	page,
		IndexTuple	newtup
	)

Definition at line 2523 of file nbtutils.c.

References BTMaxItemSize, BTMaxItemSizeNoHeapTid, BTREE_NOVAC_VERSION, BTREE_VERSION, elog, ereport, errcode(), errdetail(), errhint(), errmsg(), ERROR, errtableconstraint(), IndexTupleSize, ItemPointerGetBlockNumber, ItemPointerGetOffsetNumber, MAXALIGN, P_ISLEAF, PageGetSpecialPointer, RelationGetRelationName, and IndexTupleData::t_tid.

Referenced by _bt_buildadd(), and _bt_findinsertloc().

{
    Size        itemsz;
    BTPageOpaque opaque;

    itemsz = MAXALIGN(IndexTupleSize(newtup));

    /* Double check item size against limit */
    if (itemsz <= BTMaxItemSize(page))
        return;

    /*
     * Tuple is probably too large to fit on page, but it's possible that the
     * index uses version 2 or version 3, or that page is an internal page, in
     * which case a slightly higher limit applies.
     */
    if (!needheaptidspace && itemsz <= BTMaxItemSizeNoHeapTid(page))
        return;

    /*
     * Internal page insertions cannot fail here, because that would mean that
     * an earlier leaf level insertion that should have failed didn't
     */
    opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    if (!P_ISLEAF(opaque))
        elog(ERROR, "cannot insert oversized tuple of size %zu on internal page of index \"%s\"",
             itemsz, RelationGetRelationName(rel));

    ereport(ERROR,
            (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
             errmsg("index row size %zu exceeds btree version %u maximum %zu for index \"%s\"",
                    itemsz,
                    needheaptidspace ? BTREE_VERSION : BTREE_NOVAC_VERSION,
                    needheaptidspace ? BTMaxItemSize(page) :
                    BTMaxItemSizeNoHeapTid(page),
                    RelationGetRelationName(rel)),
             errdetail("Index row references tuple (%u,%u) in relation \"%s\".",
                       ItemPointerGetBlockNumber(&newtup->t_tid),
                       ItemPointerGetOffsetNumber(&newtup->t_tid),
                       RelationGetRelationName(heap)),
             errhint("Values larger than 1/3 of a buffer page cannot be indexed.\n"
                     "Consider a function index of an MD5 hash of the value, "
                     "or use full text indexing."),
             errtableconstraint(heap, RelationGetRelationName(rel))));
}

_bt_checkkeys()

bool _bt_checkkeys	(	IndexScanDesc	scan,
		IndexTuple	tuple,
		int	tupnatts,
		ScanDirection	dir,
		bool *	continuescan
	)

Definition at line 1344 of file nbtutils.c.

References _bt_check_rowcompare(), Assert, BTreeTupleGetNAtts, DatumGetBool, FunctionCall2Coll(), index_getattr, IndexScanDescData::indexRelation, sort-test::key, BTScanOpaqueData::keyData, BTScanOpaqueData::numberOfKeys, IndexScanDescData::opaque, RelationGetDescr, ScanDirectionIsBackward, ScanDirectionIsForward, ScanKeyData::sk_argument, ScanKeyData::sk_attno, SK_BT_NULLS_FIRST, SK_BT_REQBKWD, SK_BT_REQFWD, ScanKeyData::sk_collation, ScanKeyData::sk_flags, ScanKeyData::sk_func, SK_ISNULL, SK_ROW_HEADER, SK_SEARCHNOTNULL, SK_SEARCHNULL, and test().

Referenced by _bt_readpage().

{
    TupleDesc   tupdesc;
    BTScanOpaque so;
    int         keysz;
    int         ikey;
    ScanKey     key;

    Assert(BTreeTupleGetNAtts(tuple, scan->indexRelation) == tupnatts);

    *continuescan = true;       /* default assumption */

    tupdesc = RelationGetDescr(scan->indexRelation);
    so = (BTScanOpaque) scan->opaque;
    keysz = so->numberOfKeys;

    for (key = so->keyData, ikey = 0; ikey < keysz; key++, ikey++)
    {
        Datum       datum;
        bool        isNull;
        Datum       test;

        if (key->sk_attno > tupnatts)
        {
            /*
             * This attribute is truncated (must be high key).  The value for
             * this attribute in the first non-pivot tuple on the page to the
             * right could be any possible value.  Assume that truncated
             * attribute passes the qual.
             */
            Assert(ScanDirectionIsForward(dir));
            continue;
        }

        /* row-comparison keys need special processing */
        if (key->sk_flags & SK_ROW_HEADER)
        {
            if (_bt_check_rowcompare(key, tuple, tupnatts, tupdesc, dir,
                                     continuescan))
                continue;
            return false;
        }

        datum = index_getattr(tuple,
                              key->sk_attno,
                              tupdesc,
                              &isNull);

        if (key->sk_flags & SK_ISNULL)
        {
            /* Handle IS NULL/NOT NULL tests */
            if (key->sk_flags & SK_SEARCHNULL)
            {
                if (isNull)
                    continue;   /* tuple satisfies this qual */
            }
            else
            {
                Assert(key->sk_flags & SK_SEARCHNOTNULL);
                if (!isNull)
                    continue;   /* tuple satisfies this qual */
            }

            /*
             * Tuple fails this qual.  If it's a required qual for the current
             * scan direction, then we can conclude no further tuples will
             * pass, either.
             */
            if ((key->sk_flags & SK_BT_REQFWD) &&
                ScanDirectionIsForward(dir))
                *continuescan = false;
            else if ((key->sk_flags & SK_BT_REQBKWD) &&
                     ScanDirectionIsBackward(dir))
                *continuescan = false;

            /*
             * In any case, this indextuple doesn't match the qual.
             */
            return false;
        }

        if (isNull)
        {
            if (key->sk_flags & SK_BT_NULLS_FIRST)
            {
                /*
                 * Since NULLs are sorted before non-NULLs, we know we have
                 * reached the lower limit of the range of values for this
                 * index attr.  On a backward scan, we can stop if this qual
                 * is one of the "must match" subset.  We can stop regardless
                 * of whether the qual is > or <, so long as it's required,
                 * because it's not possible for any future tuples to pass. On
                 * a forward scan, however, we must keep going, because we may
                 * have initially positioned to the start of the index.
                 */
                if ((key->sk_flags & (SK_BT_REQFWD | SK_BT_REQBKWD)) &&
                    ScanDirectionIsBackward(dir))
                    *continuescan = false;
            }
            else
            {
                /*
                 * Since NULLs are sorted after non-NULLs, we know we have
                 * reached the upper limit of the range of values for this
                 * index attr.  On a forward scan, we can stop if this qual is
                 * one of the "must match" subset.  We can stop regardless of
                 * whether the qual is > or <, so long as it's required,
                 * because it's not possible for any future tuples to pass. On
                 * a backward scan, however, we must keep going, because we
                 * may have initially positioned to the end of the index.
                 */
                if ((key->sk_flags & (SK_BT_REQFWD | SK_BT_REQBKWD)) &&
                    ScanDirectionIsForward(dir))
                    *continuescan = false;
            }

            /*
             * In any case, this indextuple doesn't match the qual.
             */
            return false;
        }

        test = FunctionCall2Coll(&key->sk_func, key->sk_collation,
                                 datum, key->sk_argument);

        if (!DatumGetBool(test))
        {
            /*
             * Tuple fails this qual.  If it's a required qual for the current
             * scan direction, then we can conclude no further tuples will
             * pass, either.
             *
             * Note: because we stop the scan as soon as any required equality
             * qual fails, it is critical that equality quals be used for the
             * initial positioning in _bt_first() when they are available. See
             * comments in _bt_first().
             */
            if ((key->sk_flags & SK_BT_REQFWD) &&
                ScanDirectionIsForward(dir))
                *continuescan = false;
            else if ((key->sk_flags & SK_BT_REQBKWD) &&
                     ScanDirectionIsBackward(dir))
                *continuescan = false;

            /*
             * In any case, this indextuple doesn't match the qual.
             */
            return false;
        }
    }

    /* If we get here, the tuple passes all index quals. */
    return true;
}

_bt_checkpage()

void _bt_checkpage	(	Relation	rel,
		Buffer	buf
	)

Definition at line 690 of file nbtpage.c.

References BufferGetBlockNumber(), BufferGetPage, ereport, errcode(), errhint(), errmsg(), ERROR, MAXALIGN, PageGetSpecialSize, PageIsNew, and RelationGetRelationName.

Referenced by _bt_doinsert(), _bt_getbuf(), _bt_relandgetbuf(), btvacuumpage(), and palloc_btree_page().

{
    Page        page = BufferGetPage(buf);

    /*
     * ReadBuffer verifies that every newly-read page passes
     * PageHeaderIsValid, which means it either contains a reasonably sane
     * page header or is all-zero.  We have to defend against the all-zero
     * case, however.
     */
    if (PageIsNew(page))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("index \"%s\" contains unexpected zero page at block %u",
                        RelationGetRelationName(rel),
                        BufferGetBlockNumber(buf)),
                 errhint("Please REINDEX it.")));

    /*
     * Additionally check that the special area looks sane.
     */
    if (PageGetSpecialSize(page) != MAXALIGN(sizeof(BTPageOpaqueData)))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("index \"%s\" contains corrupted page at block %u",
                        RelationGetRelationName(rel),
                        BufferGetBlockNumber(buf)),
                 errhint("Please REINDEX it.")));
}

_bt_compare()

int32 _bt_compare	(	Relation	rel,
		BTScanInsert	key,
		Page	page,
		OffsetNumber	offnum
	)

Definition at line 554 of file nbtsearch.c.

References _bt_check_natts(), Assert, BTreeTupleGetHeapTID, BTreeTupleGetNAtts, DatumGetInt32, FunctionCall2Coll(), BTScanInsertData::heapkeyspace, i, index_getattr, IndexRelationGetNumberOfKeyAttributes, INVERT_COMPARE_RESULT, ItemPointerCompare(), BTScanInsertData::keysz, Min, P_FIRSTDATAKEY, P_ISLEAF, PageGetItem, PageGetItemId, PageGetSpecialPointer, BTScanInsertData::pivotsearch, RelationGetDescr, BTScanInsertData::scankeys, BTScanInsertData::scantid, ScanKeyData::sk_argument, ScanKeyData::sk_attno, SK_BT_DESC, SK_BT_NULLS_FIRST, ScanKeyData::sk_collation, ScanKeyData::sk_flags, ScanKeyData::sk_func, and SK_ISNULL.

Referenced by _bt_binsrch(), _bt_binsrch_insert(), _bt_check_unique(), _bt_doinsert(), _bt_findinsertloc(), _bt_moveright(), bt_rootdescend(), invariant_g_offset(), invariant_l_nontarget_offset(), invariant_l_offset(), and invariant_leq_offset().

{
    TupleDesc   itupdesc = RelationGetDescr(rel);
    BTPageOpaque opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    IndexTuple  itup;
    ItemPointer heapTid;
    ScanKey     scankey;
    int         ncmpkey;
    int         ntupatts;

    Assert(_bt_check_natts(rel, key->heapkeyspace, page, offnum));
    Assert(key->keysz <= IndexRelationGetNumberOfKeyAttributes(rel));
    Assert(key->heapkeyspace || key->scantid == NULL);

    /*
     * Force result ">" if target item is first data item on an internal page
     * --- see NOTE above.
     */
    if (!P_ISLEAF(opaque) && offnum == P_FIRSTDATAKEY(opaque))
        return 1;

    itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, offnum));
    ntupatts = BTreeTupleGetNAtts(itup, rel);

    /*
     * The scan key is set up with the attribute number associated with each
     * term in the key.  It is important that, if the index is multi-key, the
     * scan contain the first k key attributes, and that they be in order.  If
     * you think about how multi-key ordering works, you'll understand why
     * this is.
     *
     * We don't test for violation of this condition here, however.  The
     * initial setup for the index scan had better have gotten it right (see
     * _bt_first).
     */

    ncmpkey = Min(ntupatts, key->keysz);
    Assert(key->heapkeyspace || ncmpkey == key->keysz);
    scankey = key->scankeys;
    for (int i = 1; i <= ncmpkey; i++)
    {
        Datum       datum;
        bool        isNull;
        int32       result;

        datum = index_getattr(itup, scankey->sk_attno, itupdesc, &isNull);

        /* see comments about NULLs handling in btbuild */
        if (scankey->sk_flags & SK_ISNULL)  /* key is NULL */
        {
            if (isNull)
                result = 0;     /* NULL "=" NULL */
            else if (scankey->sk_flags & SK_BT_NULLS_FIRST)
                result = -1;    /* NULL "<" NOT_NULL */
            else
                result = 1;     /* NULL ">" NOT_NULL */
        }
        else if (isNull)        /* key is NOT_NULL and item is NULL */
        {
            if (scankey->sk_flags & SK_BT_NULLS_FIRST)
                result = 1;     /* NOT_NULL ">" NULL */
            else
                result = -1;    /* NOT_NULL "<" NULL */
        }
        else
        {
            /*
             * The sk_func needs to be passed the index value as left arg and
             * the sk_argument as right arg (they might be of different
             * types).  Since it is convenient for callers to think of
             * _bt_compare as comparing the scankey to the index item, we have
             * to flip the sign of the comparison result.  (Unless it's a DESC
             * column, in which case we *don't* flip the sign.)
             */
            result = DatumGetInt32(FunctionCall2Coll(&scankey->sk_func,
                                                     scankey->sk_collation,
                                                     datum,
                                                     scankey->sk_argument));

            if (!(scankey->sk_flags & SK_BT_DESC))
                INVERT_COMPARE_RESULT(result);
        }

        /* if the keys are unequal, return the difference */
        if (result != 0)
            return result;

        scankey++;
    }

    /*
     * All non-truncated attributes (other than heap TID) were found to be
     * equal.  Treat truncated attributes as minus infinity when scankey has a
     * key attribute value that would otherwise be compared directly.
     *
     * Note: it doesn't matter if ntupatts includes non-key attributes;
     * scankey won't, so explicitly excluding non-key attributes isn't
     * necessary.
     */
    if (key->keysz > ntupatts)
        return 1;

    /*
     * Use the heap TID attribute and scantid to try to break the tie.  The
     * rules are the same as any other key attribute -- only the
     * representation differs.
     */
    heapTid = BTreeTupleGetHeapTID(itup);
    if (key->scantid == NULL)
    {
        /*
         * Most searches have a scankey that is considered greater than a
         * truncated pivot tuple if and when the scankey has equal values for
         * attributes up to and including the least significant untruncated
         * attribute in tuple.
         *
         * For example, if an index has the minimum two attributes (single
         * user key attribute, plus heap TID attribute), and a page's high key
         * is ('foo', -inf), and scankey is ('foo', <omitted>), the search
         * will not descend to the page to the left.  The search will descend
         * right instead.  The truncated attribute in pivot tuple means that
         * all non-pivot tuples on the page to the left are strictly < 'foo',
         * so it isn't necessary to descend left.  In other words, search
         * doesn't have to descend left because it isn't interested in a match
         * that has a heap TID value of -inf.
         *
         * However, some searches (pivotsearch searches) actually require that
         * we descend left when this happens.  -inf is treated as a possible
         * match for omitted scankey attribute(s).  This is needed by page
         * deletion, which must re-find leaf pages that are targets for
         * deletion using their high keys.
         *
         * Note: the heap TID part of the test ensures that scankey is being
         * compared to a pivot tuple with one or more truncated key
         * attributes.
         *
         * Note: pg_upgrade'd !heapkeyspace indexes must always descend to the
         * left here, since they have no heap TID attribute (and cannot have
         * any -inf key values in any case, since truncation can only remove
         * non-key attributes).  !heapkeyspace searches must always be
         * prepared to deal with matches on both sides of the pivot once the
         * leaf level is reached.
         */
        if (key->heapkeyspace && !key->pivotsearch &&
            key->keysz == ntupatts && heapTid == NULL)
            return 1;

        /* All provided scankey arguments found to be equal */
        return 0;
    }

    /*
     * Treat truncated heap TID as minus infinity, since scankey has a key
     * attribute value (scantid) that would otherwise be compared directly
     */
    Assert(key->keysz == IndexRelationGetNumberOfKeyAttributes(rel));
    if (heapTid == NULL)
        return 1;

    Assert(ntupatts >= IndexRelationGetNumberOfKeyAttributes(rel));
    return ItemPointerCompare(key->scantid, heapTid);
}

_bt_delitems_delete()

void _bt_delitems_delete	(	Relation	rel,
		Buffer	buf,
		OffsetNumber *	deletable,
		int	ndeletable,
		Relation	heapRel
	)

Definition at line 1055 of file nbtpage.c.

References Assert, BTP_HAS_GARBAGE, BTPageOpaqueData::btpo_flags, BufferGetPage, END_CRIT_SECTION, index_compute_xid_horizon_for_tuples(), InvalidTransactionId, xl_btree_delete::latestRemovedXid, MarkBufferDirty(), xl_btree_delete::ndeleted, PageGetSpecialPointer, PageIndexMultiDelete(), PageSetLSN, REGBUF_STANDARD, RelationNeedsWAL, SizeOfBtreeDelete, START_CRIT_SECTION, XLOG_BTREE_DELETE, XLogBeginInsert(), XLogInsert(), XLogRegisterBufData(), XLogRegisterBuffer(), XLogRegisterData(), and XLogStandbyInfoActive.

Referenced by _bt_vacuum_one_page().

{
    Page        page = BufferGetPage(buf);
    BTPageOpaque opaque;
    TransactionId latestRemovedXid = InvalidTransactionId;

    /* Shouldn't be called unless there's something to do */
    Assert(ndeletable > 0);

    if (XLogStandbyInfoActive() && RelationNeedsWAL(rel))
        latestRemovedXid =
            index_compute_xid_horizon_for_tuples(rel, heapRel, buf,
                                                 deletable, ndeletable);

    /* No ereport(ERROR) until changes are logged */
    START_CRIT_SECTION();

    /* Fix the page */
    PageIndexMultiDelete(page, deletable, ndeletable);

    /*
     * Unlike _bt_delitems_vacuum, we *must not* clear the vacuum cycle ID,
     * because this is not called by VACUUM.  Just clear the BTP_HAS_GARBAGE
     * page flag, since we deleted all items with their LP_DEAD bit set.
     */
    opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    opaque->btpo_flags &= ~BTP_HAS_GARBAGE;

    MarkBufferDirty(buf);

    /* XLOG stuff */
    if (RelationNeedsWAL(rel))
    {
        XLogRecPtr  recptr;
        xl_btree_delete xlrec_delete;

        xlrec_delete.latestRemovedXid = latestRemovedXid;
        xlrec_delete.ndeleted = ndeletable;

        XLogBeginInsert();
        XLogRegisterBuffer(0, buf, REGBUF_STANDARD);
        XLogRegisterData((char *) &xlrec_delete, SizeOfBtreeDelete);

        /*
         * The deletable array is not in the buffer, but pretend that it is.
         * When XLogInsert stores the whole buffer, the array need not be
         * stored too.
         */
        XLogRegisterBufData(0, (char *) deletable,
                            ndeletable * sizeof(OffsetNumber));

        recptr = XLogInsert(RM_BTREE_ID, XLOG_BTREE_DELETE);

        PageSetLSN(page, recptr);
    }

    END_CRIT_SECTION();
}

_bt_delitems_vacuum()

void _bt_delitems_vacuum	(	Relation	rel,
		Buffer	buf,
		OffsetNumber *	deletable,
		int	ndeletable
	)

Definition at line 975 of file nbtpage.c.

References Assert, BTP_HAS_GARBAGE, BTPageOpaqueData::btpo_cycleid, BTPageOpaqueData::btpo_flags, BufferGetPage, END_CRIT_SECTION, MarkBufferDirty(), xl_btree_vacuum::ndeleted, PageGetSpecialPointer, PageIndexMultiDelete(), PageSetLSN, REGBUF_STANDARD, RelationNeedsWAL, SizeOfBtreeVacuum, START_CRIT_SECTION, XLOG_BTREE_VACUUM, XLogBeginInsert(), XLogInsert(), XLogRegisterBufData(), XLogRegisterBuffer(), and XLogRegisterData().

Referenced by btvacuumpage().

{
    Page        page = BufferGetPage(buf);
    BTPageOpaque opaque;

    /* Shouldn't be called unless there's something to do */
    Assert(ndeletable > 0);

    /* No ereport(ERROR) until changes are logged */
    START_CRIT_SECTION();

    /* Fix the page */
    PageIndexMultiDelete(page, deletable, ndeletable);

    /*
     * We can clear the vacuum cycle ID since this page has certainly been
     * processed by the current vacuum scan.
     */
    opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    opaque->btpo_cycleid = 0;

    /*
     * Mark the page as not containing any LP_DEAD items.  This is not
     * certainly true (there might be some that have recently been marked, but
     * weren't targeted by VACUUM's heap scan), but it will be true often
     * enough.  VACUUM does not delete items purely because they have their
     * LP_DEAD bit set, since doing so would necessitate explicitly logging a
     * latestRemovedXid cutoff (this is how _bt_delitems_delete works).
     *
     * The consequences of falsely unsetting BTP_HAS_GARBAGE should be fairly
     * limited, since we never falsely unset an LP_DEAD bit.  Workloads that
     * are particularly dependent on LP_DEAD bits being set quickly will
     * usually manage to set the BTP_HAS_GARBAGE flag before the page fills up
     * again anyway.
     */
    opaque->btpo_flags &= ~BTP_HAS_GARBAGE;

    MarkBufferDirty(buf);

    /* XLOG stuff */
    if (RelationNeedsWAL(rel))
    {
        XLogRecPtr  recptr;
        xl_btree_vacuum xlrec_vacuum;

        xlrec_vacuum.ndeleted = ndeletable;

        XLogBeginInsert();
        XLogRegisterBuffer(0, buf, REGBUF_STANDARD);
        XLogRegisterData((char *) &xlrec_vacuum, SizeOfBtreeVacuum);

        /*
         * The deletable array is not in the buffer, but pretend that it is.
         * When XLogInsert stores the whole buffer, the array need not be
         * stored too.
         */
        XLogRegisterBufData(0, (char *) deletable,
                            ndeletable * sizeof(OffsetNumber));

        recptr = XLogInsert(RM_BTREE_ID, XLOG_BTREE_VACUUM);

        PageSetLSN(page, recptr);
    }

    END_CRIT_SECTION();
}

_bt_doinsert()

bool _bt_doinsert	(	Relation	rel,
		IndexTuple	itup,
		IndexUniqueCheck	checkUnique,
		Relation	heapRel
	)

Definition at line 79 of file nbtinsert.c.

References _bt_check_unique(), _bt_checkpage(), _bt_compare(), _bt_findinsertloc(), _bt_freestack(), _bt_insertonpg(), _bt_mkscankey(), _bt_relbuf(), _bt_search(), BTScanInsertData::anynullkeys, Assert, BTInsertStateData::bounds_valid, BT_WRITE, buf, BTInsertStateData::buf, BufferGetPage, CheckForSerializableConflictIn(), ConditionalLockBuffer(), BTScanInsertData::heapkeyspace, IndexTupleSize, InvalidBlockNumber, InvalidBuffer, BTInsertStateData::itemsz, BTInsertStateData::itup, BTInsertStateData::itup_key, MAXALIGN, P_FIRSTDATAKEY, P_IGNORE, P_ISLEAF, P_RIGHTMOST, PageGetFreeSpace(), PageGetMaxOffsetNumber, PageGetSpecialPointer, pfree(), ReadBuffer(), RelationGetTargetBlock, RelationSetTargetBlock, ReleaseBuffer(), BTScanInsertData::scantid, SpeculativeInsertionWait(), IndexTupleData::t_tid, TransactionIdIsValid, UNIQUE_CHECK_EXISTING, UNIQUE_CHECK_NO, XactLockTableWait(), and XLTW_InsertIndex.

Referenced by btinsert().

{
    bool        is_unique = false;
    BTInsertStateData insertstate;
    BTScanInsert itup_key;
    BTStack     stack = NULL;
    Buffer      buf;
    bool        fastpath;
    bool        checkingunique = (checkUnique != UNIQUE_CHECK_NO);

    /* we need an insertion scan key to do our search, so build one */
    itup_key = _bt_mkscankey(rel, itup);

    if (checkingunique)
    {
        if (!itup_key->anynullkeys)
        {
            /* No (heapkeyspace) scantid until uniqueness established */
            itup_key->scantid = NULL;
        }
        else
        {
            /*
             * Scan key for new tuple contains NULL key values.  Bypass
             * checkingunique steps.  They are unnecessary because core code
             * considers NULL unequal to every value, including NULL.
             *
             * This optimization avoids O(N^2) behavior within the
             * _bt_findinsertloc() heapkeyspace path when a unique index has a
             * large number of "duplicates" with NULL key values.
             */
            checkingunique = false;
            /* Tuple is unique in the sense that core code cares about */
            Assert(checkUnique != UNIQUE_CHECK_EXISTING);
            is_unique = true;
        }
    }

    /*
     * Fill in the BTInsertState working area, to track the current page and
     * position within the page to insert on
     */
    insertstate.itup = itup;
    /* PageAddItem will MAXALIGN(), but be consistent */
    insertstate.itemsz = MAXALIGN(IndexTupleSize(itup));
    insertstate.itup_key = itup_key;
    insertstate.bounds_valid = false;
    insertstate.buf = InvalidBuffer;

    /*
     * It's very common to have an index on an auto-incremented or
     * monotonically increasing value. In such cases, every insertion happens
     * towards the end of the index. We try to optimize that case by caching
     * the right-most leaf of the index. If our cached block is still the
     * rightmost leaf, has enough free space to accommodate a new entry and
     * the insertion key is strictly greater than the first key in this page,
     * then we can safely conclude that the new key will be inserted in the
     * cached block. So we simply search within the cached block and insert
     * the key at the appropriate location. We call it a fastpath.
     *
     * Testing has revealed, though, that the fastpath can result in increased
     * contention on the exclusive-lock on the rightmost leaf page. So we
     * conditionally check if the lock is available. If it's not available
     * then we simply abandon the fastpath and take the regular path. This
     * makes sense because unavailability of the lock also signals that some
     * other backend might be concurrently inserting into the page, thus
     * reducing our chances to finding an insertion place in this page.
     */
top:
    fastpath = false;
    if (RelationGetTargetBlock(rel) != InvalidBlockNumber)
    {
        Page        page;
        BTPageOpaque lpageop;

        /*
         * Conditionally acquire exclusive lock on the buffer before doing any
         * checks. If we don't get the lock, we simply follow slowpath. If we
         * do get the lock, this ensures that the index state cannot change,
         * as far as the rightmost part of the index is concerned.
         */
        buf = ReadBuffer(rel, RelationGetTargetBlock(rel));

        if (ConditionalLockBuffer(buf))
        {
            _bt_checkpage(rel, buf);

            page = BufferGetPage(buf);

            lpageop = (BTPageOpaque) PageGetSpecialPointer(page);

            /*
             * Check if the page is still the rightmost leaf page, has enough
             * free space to accommodate the new tuple, and the insertion scan
             * key is strictly greater than the first key on the page.
             */
            if (P_ISLEAF(lpageop) && P_RIGHTMOST(lpageop) &&
                !P_IGNORE(lpageop) &&
                (PageGetFreeSpace(page) > insertstate.itemsz) &&
                PageGetMaxOffsetNumber(page) >= P_FIRSTDATAKEY(lpageop) &&
                _bt_compare(rel, itup_key, page, P_FIRSTDATAKEY(lpageop)) > 0)
            {
                fastpath = true;
            }
            else
            {
                _bt_relbuf(rel, buf);

                /*
                 * Something did not work out. Just forget about the cached
                 * block and follow the normal path. It might be set again if
                 * the conditions are favourable.
                 */
                RelationSetTargetBlock(rel, InvalidBlockNumber);
            }
        }
        else
        {
            ReleaseBuffer(buf);

            /*
             * If someone's holding a lock, it's likely to change anyway, so
             * don't try again until we get an updated rightmost leaf.
             */
            RelationSetTargetBlock(rel, InvalidBlockNumber);
        }
    }

    if (!fastpath)
    {
        /*
         * Find the first page containing this key.  Buffer returned by
         * _bt_search() is locked in exclusive mode.
         */
        stack = _bt_search(rel, itup_key, &buf, BT_WRITE, NULL);
    }

    insertstate.buf = buf;
    buf = InvalidBuffer;        /* insertstate.buf now owns the buffer */

    /*
     * If we're not allowing duplicates, make sure the key isn't already in
     * the index.
     *
     * NOTE: obviously, _bt_check_unique can only detect keys that are already
     * in the index; so it cannot defend against concurrent insertions of the
     * same key.  We protect against that by means of holding a write lock on
     * the first page the value could be on, with omitted/-inf value for the
     * implicit heap TID tiebreaker attribute.  Any other would-be inserter of
     * the same key must acquire a write lock on the same page, so only one
     * would-be inserter can be making the check at one time.  Furthermore,
     * once we are past the check we hold write locks continuously until we
     * have performed our insertion, so no later inserter can fail to see our
     * insertion.  (This requires some care in _bt_findinsertloc.)
     *
     * If we must wait for another xact, we release the lock while waiting,
     * and then must start over completely.
     *
     * For a partial uniqueness check, we don't wait for the other xact. Just
     * let the tuple in and return false for possibly non-unique, or true for
     * definitely unique.
     */
    if (checkingunique)
    {
        TransactionId xwait;
        uint32      speculativeToken;

        xwait = _bt_check_unique(rel, &insertstate, heapRel, checkUnique,
                                 &is_unique, &speculativeToken);

        if (TransactionIdIsValid(xwait))
        {
            /* Have to wait for the other guy ... */
            _bt_relbuf(rel, insertstate.buf);
            insertstate.buf = InvalidBuffer;

            /*
             * If it's a speculative insertion, wait for it to finish (ie. to
             * go ahead with the insertion, or kill the tuple).  Otherwise
             * wait for the transaction to finish as usual.
             */
            if (speculativeToken)
                SpeculativeInsertionWait(xwait, speculativeToken);
            else
                XactLockTableWait(xwait, rel, &itup->t_tid, XLTW_InsertIndex);

            /* start over... */
            if (stack)
                _bt_freestack(stack);
            goto top;
        }

        /* Uniqueness is established -- restore heap tid as scantid */
        if (itup_key->heapkeyspace)
            itup_key->scantid = &itup->t_tid;
    }

    if (checkUnique != UNIQUE_CHECK_EXISTING)
    {
        OffsetNumber newitemoff;

        /*
         * The only conflict predicate locking cares about for indexes is when
         * an index tuple insert conflicts with an existing lock.  We don't
         * know the actual page we're going to insert on for sure just yet in
         * checkingunique and !heapkeyspace cases, but it's okay to use the
         * first page the value could be on (with scantid omitted) instead.
         */
        CheckForSerializableConflictIn(rel, NULL, insertstate.buf);

        /*
         * Do the insertion.  Note that insertstate contains cached binary
         * search bounds established within _bt_check_unique when insertion is
         * checkingunique.
         */
        newitemoff = _bt_findinsertloc(rel, &insertstate, checkingunique,
                                       stack, heapRel);
        _bt_insertonpg(rel, itup_key, insertstate.buf, InvalidBuffer, stack,
                       itup, newitemoff, false);
    }
    else
    {
        /* just release the buffer */
        _bt_relbuf(rel, insertstate.buf);
    }

    /* be tidy */
    if (stack)
        _bt_freestack(stack);
    pfree(itup_key);

    return is_unique;
}

_bt_end_vacuum()

void _bt_end_vacuum

(

Relation

rel

)

Definition at line 1937 of file nbtutils.c.

References LockRelId::dbId, i, LockInfoData::lockRelId, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), BTVacInfo::num_vacuums, RelationData::rd_lockInfo, LockRelId::relId, BTOneVacInfo::relid, and BTVacInfo::vacuums.

Referenced by _bt_end_vacuum_callback(), and btbulkdelete().

{
    int         i;

    LWLockAcquire(BtreeVacuumLock, LW_EXCLUSIVE);

    /* Find the array entry */
    for (i = 0; i < btvacinfo->num_vacuums; i++)
    {
        BTOneVacInfo *vac = &btvacinfo->vacuums[i];

        if (vac->relid.relId == rel->rd_lockInfo.lockRelId.relId &&
            vac->relid.dbId == rel->rd_lockInfo.lockRelId.dbId)
        {
            /* Remove it by shifting down the last entry */
            *vac = btvacinfo->vacuums[btvacinfo->num_vacuums - 1];
            btvacinfo->num_vacuums--;
            break;
        }
    }

    LWLockRelease(BtreeVacuumLock);
}

_bt_end_vacuum_callback()

void _bt_end_vacuum_callback	(	int	code,
		Datum	arg
	)

Definition at line 1965 of file nbtutils.c.

References _bt_end_vacuum(), and DatumGetPointer.

Referenced by btbulkdelete().

{
    _bt_end_vacuum((Relation) DatumGetPointer(arg));
}

_bt_findsplitloc()

OffsetNumber _bt_findsplitloc	(	Relation	rel,
		Page	page,
		OffsetNumber	newitemoff,
		Size	newitemsz,
		IndexTuple	newitem,
		bool *	newitemonleft
	)

Definition at line 127 of file nbtsplitloc.c.

References _bt_afternewitemoff(), _bt_bestsplitloc(), _bt_deltasortsplits(), _bt_recsplitloc(), _bt_strategy(), Assert, BTGetFillFactor, BTREE_NONLEAF_FILLFACTOR, BTREE_SINGLEVAL_FILLFACTOR, elog, ERROR, SplitPoint::firstoldonright, i, IndexRelationGetNumberOfKeyAttributes, FindSplitData::interval, FindSplitData::is_leaf, FindSplitData::is_rightmost, ItemIdGetLength, FindSplitData::leftspace, Max, MAX_INTERNAL_INTERVAL, MAX_LEAF_INTERVAL, MAXALIGN, FindSplitData::maxsplits, Min, FindSplitData::minfirstrightsz, FindSplitData::newitem, FindSplitData::newitemoff, SplitPoint::newitemonleft, FindSplitData::newitemsz, FindSplitData::nsplits, OffsetNumberNext, FindSplitData::olddataitemstotal, P_FIRSTDATAKEY, P_HIKEY, P_ISLEAF, P_RIGHTMOST, FindSplitData::page, PageGetExactFreeSpace(), PageGetItemId, PageGetMaxOffsetNumber, PageGetPageSize, PageGetSpecialPointer, palloc(), pfree(), FindSplitData::rel, RelationGetRelationName, FindSplitData::rightspace, SIZE_MAX, SizeOfPageHeaderData, SPLIT_DEFAULT, SPLIT_MANY_DUPLICATES, SPLIT_SINGLE_VALUE, and FindSplitData::splits.

Referenced by _bt_split().

{
    BTPageOpaque opaque;
    int         leftspace,
                rightspace,
                olddataitemstotal,
                olddataitemstoleft,
                perfectpenalty,
                leaffillfactor;
    FindSplitData state;
    FindSplitStrat strategy;
    ItemId      itemid;
    OffsetNumber offnum,
                maxoff,
                foundfirstright;
    double      fillfactormult;
    bool        usemult;
    SplitPoint  leftpage,
                rightpage;

    opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    maxoff = PageGetMaxOffsetNumber(page);

    /* Total free space available on a btree page, after fixed overhead */
    leftspace = rightspace =
        PageGetPageSize(page) - SizeOfPageHeaderData -
        MAXALIGN(sizeof(BTPageOpaqueData));

    /* The right page will have the same high key as the old page */
    if (!P_RIGHTMOST(opaque))
    {
        itemid = PageGetItemId(page, P_HIKEY);
        rightspace -= (int) (MAXALIGN(ItemIdGetLength(itemid)) +
                             sizeof(ItemIdData));
    }

    /* Count up total space in data items before actually scanning 'em */
    olddataitemstotal = rightspace - (int) PageGetExactFreeSpace(page);
    leaffillfactor = BTGetFillFactor(rel);

    /* Passed-in newitemsz is MAXALIGNED but does not include line pointer */
    newitemsz += sizeof(ItemIdData);
    state.rel = rel;
    state.page = page;
    state.newitem = newitem;
    state.newitemsz = newitemsz;
    state.is_leaf = P_ISLEAF(opaque);
    state.is_rightmost = P_RIGHTMOST(opaque);
    state.leftspace = leftspace;
    state.rightspace = rightspace;
    state.olddataitemstotal = olddataitemstotal;
    state.minfirstrightsz = SIZE_MAX;
    state.newitemoff = newitemoff;

    /*
     * maxsplits should never exceed maxoff because there will be at most as
     * many candidate split points as there are points _between_ tuples, once
     * you imagine that the new item is already on the original page (the
     * final number of splits may be slightly lower because not all points
     * between tuples will be legal).
     */
    state.maxsplits = maxoff;
    state.splits = palloc(sizeof(SplitPoint) * state.maxsplits);
    state.nsplits = 0;

    /*
     * Scan through the data items and calculate space usage for a split at
     * each possible position
     */
    olddataitemstoleft = 0;

    for (offnum = P_FIRSTDATAKEY(opaque);
         offnum <= maxoff;
         offnum = OffsetNumberNext(offnum))
    {
        Size        itemsz;

        itemid = PageGetItemId(page, offnum);
        itemsz = MAXALIGN(ItemIdGetLength(itemid)) + sizeof(ItemIdData);

        /*
         * When item offset number is not newitemoff, neither side of the
         * split can be newitem.  Record a split after the previous data item
         * from original page, but before the current data item from original
         * page. (_bt_recsplitloc() will reject the split when there are no
         * previous items, which we rely on.)
         */
        if (offnum < newitemoff)
            _bt_recsplitloc(&state, offnum, false, olddataitemstoleft, itemsz);
        else if (offnum > newitemoff)
            _bt_recsplitloc(&state, offnum, true, olddataitemstoleft, itemsz);
        else
        {
            /*
             * Record a split after all "offnum < newitemoff" original page
             * data items, but before newitem
             */
            _bt_recsplitloc(&state, offnum, false, olddataitemstoleft, itemsz);

            /*
             * Record a split after newitem, but before data item from
             * original page at offset newitemoff/current offset
             */
            _bt_recsplitloc(&state, offnum, true, olddataitemstoleft, itemsz);
        }

        olddataitemstoleft += itemsz;
    }

    /*
     * Record a split after all original page data items, but before newitem.
     * (Though only when it's possible that newitem will end up alone on new
     * right page.)
     */
    Assert(olddataitemstoleft == olddataitemstotal);
    if (newitemoff > maxoff)
        _bt_recsplitloc(&state, newitemoff, false, olddataitemstotal, 0);

    /*
     * I believe it is not possible to fail to find a feasible split, but just
     * in case ...
     */
    if (state.nsplits == 0)
        elog(ERROR, "could not find a feasible split point for index \"%s\"",
             RelationGetRelationName(rel));

    /*
     * Start search for a split point among list of legal split points.  Give
     * primary consideration to equalizing available free space in each half
     * of the split initially (start with default strategy), while applying
     * rightmost and split-after-new-item optimizations where appropriate.
     * Either of the two other fallback strategies may be required for cases
     * with a large number of duplicates around the original/space-optimal
     * split point.
     *
     * Default strategy gives some weight to suffix truncation in deciding a
     * split point on leaf pages.  It attempts to select a split point where a
     * distinguishing attribute appears earlier in the new high key for the
     * left side of the split, in order to maximize the number of trailing
     * attributes that can be truncated away.  Only candidate split points
     * that imply an acceptable balance of free space on each side are
     * considered.
     */
    if (!state.is_leaf)
    {
        /* fillfactormult only used on rightmost page */
        usemult = state.is_rightmost;
        fillfactormult = BTREE_NONLEAF_FILLFACTOR / 100.0;
    }
    else if (state.is_rightmost)
    {
        /* Rightmost leaf page --  fillfactormult always used */
        usemult = true;
        fillfactormult = leaffillfactor / 100.0;
    }
    else if (_bt_afternewitemoff(&state, maxoff, leaffillfactor, &usemult))
    {
        /*
         * New item inserted at rightmost point among a localized grouping on
         * a leaf page -- apply "split after new item" optimization, either by
         * applying leaf fillfactor multiplier, or by choosing the exact split
         * point that leaves the new item as last on the left. (usemult is set
         * for us.)
         */
        if (usemult)
        {
            /* fillfactormult should be set based on leaf fillfactor */
            fillfactormult = leaffillfactor / 100.0;
        }
        else
        {
            /* find precise split point after newitemoff */
            for (int i = 0; i < state.nsplits; i++)
            {
                SplitPoint *split = state.splits + i;

                if (split->newitemonleft &&
                    newitemoff == split->firstoldonright)
                {
                    pfree(state.splits);
                    *newitemonleft = true;
                    return newitemoff;
                }
            }

            /*
             * Cannot legally split after newitemoff; proceed with split
             * without using fillfactor multiplier.  This is defensive, and
             * should never be needed in practice.
             */
            fillfactormult = 0.50;
        }
    }
    else
    {
        /* Other leaf page.  50:50 page split. */
        usemult = false;
        /* fillfactormult not used, but be tidy */
        fillfactormult = 0.50;
    }

    /*
     * Set an initial limit on the split interval/number of candidate split
     * points as appropriate.  The "Prefix B-Trees" paper refers to this as
     * sigma l for leaf splits and sigma b for internal ("branch") splits.
     * It's hard to provide a theoretical justification for the initial size
     * of the split interval, though it's clear that a small split interval
     * makes suffix truncation much more effective without noticeably
     * affecting space utilization over time.
     */
    state.interval = Min(Max(1, state.nsplits * 0.05),
                         state.is_leaf ? MAX_LEAF_INTERVAL :
                         MAX_INTERNAL_INTERVAL);

    /*
     * Save leftmost and rightmost splits for page before original ordinal
     * sort order is lost by delta/fillfactormult sort
     */
    leftpage = state.splits[0];
    rightpage = state.splits[state.nsplits - 1];

    /* Give split points a fillfactormult-wise delta, and sort on deltas */
    _bt_deltasortsplits(&state, fillfactormult, usemult);

    /*
     * Determine if default strategy/split interval will produce a
     * sufficiently distinguishing split, or if we should change strategies.
     * Alternative strategies change the range of split points that are
     * considered acceptable (split interval), and possibly change
     * fillfactormult, in order to deal with pages with a large number of
     * duplicates gracefully.
     *
     * Pass low and high splits for the entire page (actually, they're for an
     * imaginary version of the page that includes newitem).  These are used
     * when the initial split interval encloses split points that are full of
     * duplicates, and we need to consider if it's even possible to avoid
     * appending a heap TID.
     */
    perfectpenalty = _bt_strategy(&state, &leftpage, &rightpage, &strategy);

    if (strategy == SPLIT_DEFAULT)
    {
        /*
         * Default strategy worked out (always works out with internal page).
         * Original split interval still stands.
         */
    }

    /*
     * Many duplicates strategy is used when a heap TID would otherwise be
     * appended, but the page isn't completely full of logical duplicates.
     *
     * The split interval is widened to include all legal candidate split
     * points.  There might be a few as two distinct values in the whole-page
     * split interval, though it's also possible that most of the values on
     * the page are unique.  The final split point will either be to the
     * immediate left or to the immediate right of the group of duplicate
     * tuples that enclose the first/delta-optimal split point (perfect
     * penalty was set so that the lowest delta split point that avoids
     * appending a heap TID will be chosen).  Maximizing the number of
     * attributes that can be truncated away is not a goal of the many
     * duplicates strategy.
     *
     * Single value strategy is used when it is impossible to avoid appending
     * a heap TID.  It arranges to leave the left page very full.  This
     * maximizes space utilization in cases where tuples with the same
     * attribute values span many pages.  Newly inserted duplicates will tend
     * to have higher heap TID values, so we'll end up splitting to the right
     * consistently.  (Single value strategy is harmless though not
     * particularly useful with !heapkeyspace indexes.)
     */
    else if (strategy == SPLIT_MANY_DUPLICATES)
    {
        Assert(state.is_leaf);
        /* Shouldn't try to truncate away extra user attributes */
        Assert(perfectpenalty ==
               IndexRelationGetNumberOfKeyAttributes(state.rel));
        /* No need to resort splits -- no change in fillfactormult/deltas */
        state.interval = state.nsplits;
    }
    else if (strategy == SPLIT_SINGLE_VALUE)
    {
        Assert(state.is_leaf);
        /* Split near the end of the page */
        usemult = true;
        fillfactormult = BTREE_SINGLEVAL_FILLFACTOR / 100.0;
        /* Resort split points with new delta */
        _bt_deltasortsplits(&state, fillfactormult, usemult);
        /* Appending a heap TID is unavoidable, so interval of 1 is fine */
        state.interval = 1;
    }

    /*
     * Search among acceptable split points (using final split interval) for
     * the entry that has the lowest penalty, and is therefore expected to
     * maximize fan-out.  Sets *newitemonleft for us.
     */
    foundfirstright = _bt_bestsplitloc(&state, perfectpenalty, newitemonleft,
                                       strategy);
    pfree(state.splits);

    return foundfirstright;
}

_bt_finish_split()

void _bt_finish_split	(	Relation	rel,
		Buffer	lbuf,
		BTStack	stack
	)

Definition at line 1851 of file nbtinsert.c.

References _bt_getbuf(), _bt_insert_parent(), _bt_relbuf(), Assert, BT_WRITE, BTMetaPageData::btm_root, BTPageGetMeta, BTPageOpaqueData::btpo_next, BTREE_METAPAGE, BufferGetBlockNumber(), BufferGetPage, DEBUG1, elog, P_INCOMPLETE_SPLIT, P_LEFTMOST, P_RIGHTMOST, and PageGetSpecialPointer.

Referenced by _bt_getstackbuf(), _bt_moveright(), and _bt_stepright().

{
    Page        lpage = BufferGetPage(lbuf);
    BTPageOpaque lpageop = (BTPageOpaque) PageGetSpecialPointer(lpage);
    Buffer      rbuf;
    Page        rpage;
    BTPageOpaque rpageop;
    bool        was_root;
    bool        was_only;

    Assert(P_INCOMPLETE_SPLIT(lpageop));

    /* Lock right sibling, the one missing the downlink */
    rbuf = _bt_getbuf(rel, lpageop->btpo_next, BT_WRITE);
    rpage = BufferGetPage(rbuf);
    rpageop = (BTPageOpaque) PageGetSpecialPointer(rpage);

    /* Could this be a root split? */
    if (!stack)
    {
        Buffer      metabuf;
        Page        metapg;
        BTMetaPageData *metad;

        /* acquire lock on the metapage */
        metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_WRITE);
        metapg = BufferGetPage(metabuf);
        metad = BTPageGetMeta(metapg);

        was_root = (metad->btm_root == BufferGetBlockNumber(lbuf));

        _bt_relbuf(rel, metabuf);
    }
    else
        was_root = false;

    /* Was this the only page on the level before split? */
    was_only = (P_LEFTMOST(lpageop) && P_RIGHTMOST(rpageop));

    elog(DEBUG1, "finishing incomplete split of %u/%u",
         BufferGetBlockNumber(lbuf), BufferGetBlockNumber(rbuf));

    _bt_insert_parent(rel, lbuf, rbuf, stack, was_root, was_only);
}

_bt_first()

bool _bt_first	(	IndexScanDesc	scan,
		ScanDirection	dir
	)

Definition at line 741 of file nbtsearch.c.

References _bt_binsrch(), _bt_drop_lock_and_maybe_pin(), _bt_endpoint(), _bt_freestack(), _bt_heapkeyspace(), _bt_initialize_more_data(), _bt_parallel_done(), _bt_parallel_readpage(), _bt_parallel_seize(), _bt_preprocess_keys(), _bt_readpage(), _bt_search(), _bt_steppage(), Assert, BT_READ, BTEqualStrategyNumber, BTGreaterEqualStrategyNumber, BTGreaterStrategyNumber, BTLessEqualStrategyNumber, BTLessStrategyNumber, BTORDER_PROC, BTScanPosInvalidate, BTScanPosIsValid, buf, BTScanPosData::buf, BUFFER_LOCK_UNLOCK, BufferGetBlockNumber(), BufferIsValid, cur, BTScanOpaqueData::currPos, BTScanOpaqueData::currTuples, DatumGetPointer, elog, ERROR, get_opfamily_proc(), i, index_getprocinfo(), INDEX_MAX_KEYS, IndexScanDescData::indexRelation, InvalidBlockNumber, InvalidOid, InvalidStrategy, BTScanPosData::itemIndex, BTScanPosData::items, BTScanOpaqueData::keyData, LockBuffer(), BTScanOpaqueData::numberOfKeys, OffsetNumberPrev, IndexScanDescData::opaque, P_NONE, IndexScanDescData::parallel_scan, pgstat_count_index_scan, PredicateLockPage(), PredicateLockRelation(), BTScanOpaqueData::qual_ok, RelationData::rd_opcintype, RelationData::rd_opfamily, RegProcedureIsValid, RelationGetRelationName, ScanDirectionIsBackward, ScanDirectionIsForward, ScanKeyEntryInitialize(), ScanKeyEntryInitializeWithInfo(), ScanKeyData::sk_argument, ScanKeyData::sk_attno, SK_BT_DESC, SK_BT_NULLS_FIRST, ScanKeyData::sk_collation, ScanKeyData::sk_flags, SK_ISNULL, SK_ROW_END, SK_ROW_HEADER, SK_ROW_MEMBER, SK_SEARCHNOTNULL, ScanKeyData::sk_strategy, ScanKeyData::sk_subtype, status(), IndexScanDescData::xs_heaptid, IndexScanDescData::xs_itup, IndexScanDescData::xs_snapshot, and IndexScanDescData::xs_want_itup.

Referenced by btgetbitmap(), and btgettuple().

{
    Relation    rel = scan->indexRelation;
    BTScanOpaque so = (BTScanOpaque) scan->opaque;
    Buffer      buf;
    BTStack     stack;
    OffsetNumber offnum;
    StrategyNumber strat;
    bool        nextkey;
    bool        goback;
    BTScanInsertData inskey;
    ScanKey     startKeys[INDEX_MAX_KEYS];
    ScanKeyData notnullkeys[INDEX_MAX_KEYS];
    int         keysCount = 0;
    int         i;
    bool        status = true;
    StrategyNumber strat_total;
    BTScanPosItem *currItem;
    BlockNumber blkno;

    Assert(!BTScanPosIsValid(so->currPos));

    pgstat_count_index_scan(rel);

    /*
     * Examine the scan keys and eliminate any redundant keys; also mark the
     * keys that must be matched to continue the scan.
     */
    _bt_preprocess_keys(scan);

    /*
     * Quit now if _bt_preprocess_keys() discovered that the scan keys can
     * never be satisfied (eg, x == 1 AND x > 2).
     */
    if (!so->qual_ok)
        return false;

    /*
     * For parallel scans, get the starting page from shared state. If the
     * scan has not started, proceed to find out first leaf page in the usual
     * way while keeping other participating processes waiting.  If the scan
     * has already begun, use the page number from the shared structure.
     */
    if (scan->parallel_scan != NULL)
    {
        status = _bt_parallel_seize(scan, &blkno);
        if (!status)
            return false;
        else if (blkno == P_NONE)
        {
            _bt_parallel_done(scan);
            return false;
        }
        else if (blkno != InvalidBlockNumber)
        {
            if (!_bt_parallel_readpage(scan, blkno, dir))
                return false;
            goto readcomplete;
        }
    }

    /*----------
     * Examine the scan keys to discover where we need to start the scan.
     *
     * We want to identify the keys that can be used as starting boundaries;
     * these are =, >, or >= keys for a forward scan or =, <, <= keys for
     * a backwards scan.  We can use keys for multiple attributes so long as
     * the prior attributes had only =, >= (resp. =, <=) keys.  Once we accept
     * a > or < boundary or find an attribute with no boundary (which can be
     * thought of as the same as "> -infinity"), we can't use keys for any
     * attributes to its right, because it would break our simplistic notion
     * of what initial positioning strategy to use.
     *
     * When the scan keys include cross-type operators, _bt_preprocess_keys
     * may not be able to eliminate redundant keys; in such cases we will
     * arbitrarily pick a usable one for each attribute.  This is correct
     * but possibly not optimal behavior.  (For example, with keys like
     * "x >= 4 AND x >= 5" we would elect to scan starting at x=4 when
     * x=5 would be more efficient.)  Since the situation only arises given
     * a poorly-worded query plus an incomplete opfamily, live with it.
     *
     * When both equality and inequality keys appear for a single attribute
     * (again, only possible when cross-type operators appear), we *must*
     * select one of the equality keys for the starting point, because
     * _bt_checkkeys() will stop the scan as soon as an equality qual fails.
     * For example, if we have keys like "x >= 4 AND x = 10" and we elect to
     * start at x=4, we will fail and stop before reaching x=10.  If multiple
     * equality quals survive preprocessing, however, it doesn't matter which
     * one we use --- by definition, they are either redundant or
     * contradictory.
     *
     * Any regular (not SK_SEARCHNULL) key implies a NOT NULL qualifier.
     * If the index stores nulls at the end of the index we'll be starting
     * from, and we have no boundary key for the column (which means the key
     * we deduced NOT NULL from is an inequality key that constrains the other
     * end of the index), then we cons up an explicit SK_SEARCHNOTNULL key to
     * use as a boundary key.  If we didn't do this, we might find ourselves
     * traversing a lot of null entries at the start of the scan.
     *
     * In this loop, row-comparison keys are treated the same as keys on their
     * first (leftmost) columns.  We'll add on lower-order columns of the row
     * comparison below, if possible.
     *
     * The selected scan keys (at most one per index column) are remembered by
     * storing their addresses into the local startKeys[] array.
     *----------
     */
    strat_total = BTEqualStrategyNumber;
    if (so->numberOfKeys > 0)
    {
        AttrNumber  curattr;
        ScanKey     chosen;
        ScanKey     impliesNN;
        ScanKey     cur;

        /*
         * chosen is the so-far-chosen key for the current attribute, if any.
         * We don't cast the decision in stone until we reach keys for the
         * next attribute.
         */
        curattr = 1;
        chosen = NULL;
        /* Also remember any scankey that implies a NOT NULL constraint */
        impliesNN = NULL;

        /*
         * Loop iterates from 0 to numberOfKeys inclusive; we use the last
         * pass to handle after-last-key processing.  Actual exit from the
         * loop is at one of the "break" statements below.
         */
        for (cur = so->keyData, i = 0;; cur++, i++)
        {
            if (i >= so->numberOfKeys || cur->sk_attno != curattr)
            {
                /*
                 * Done looking at keys for curattr.  If we didn't find a
                 * usable boundary key, see if we can deduce a NOT NULL key.
                 */
                if (chosen == NULL && impliesNN != NULL &&
                    ((impliesNN->sk_flags & SK_BT_NULLS_FIRST) ?
                     ScanDirectionIsForward(dir) :
                     ScanDirectionIsBackward(dir)))
                {
                    /* Yes, so build the key in notnullkeys[keysCount] */
                    chosen = &notnullkeys[keysCount];
                    ScanKeyEntryInitialize(chosen,
                                           (SK_SEARCHNOTNULL | SK_ISNULL |
                                            (impliesNN->sk_flags &
                                             (SK_BT_DESC | SK_BT_NULLS_FIRST))),
                                           curattr,
                                           ((impliesNN->sk_flags & SK_BT_NULLS_FIRST) ?
                                            BTGreaterStrategyNumber :
                                            BTLessStrategyNumber),
                                           InvalidOid,
                                           InvalidOid,
                                           InvalidOid,
                                           (Datum) 0);
                }

                /*
                 * If we still didn't find a usable boundary key, quit; else
                 * save the boundary key pointer in startKeys.
                 */
                if (chosen == NULL)
                    break;
                startKeys[keysCount++] = chosen;

                /*
                 * Adjust strat_total, and quit if we have stored a > or <
                 * key.
                 */
                strat = chosen->sk_strategy;
                if (strat != BTEqualStrategyNumber)
                {
                    strat_total = strat;
                    if (strat == BTGreaterStrategyNumber ||
                        strat == BTLessStrategyNumber)
                        break;
                }

                /*
                 * Done if that was the last attribute, or if next key is not
                 * in sequence (implying no boundary key is available for the
                 * next attribute).
                 */
                if (i >= so->numberOfKeys ||
                    cur->sk_attno != curattr + 1)
                    break;

                /*
                 * Reset for next attr.
                 */
                curattr = cur->sk_attno;
                chosen = NULL;
                impliesNN = NULL;
            }

            /*
             * Can we use this key as a starting boundary for this attr?
             *
             * If not, does it imply a NOT NULL constraint?  (Because
             * SK_SEARCHNULL keys are always assigned BTEqualStrategyNumber,
             * *any* inequality key works for that; we need not test.)
             */
            switch (cur->sk_strategy)
            {
                case BTLessStrategyNumber:
                case BTLessEqualStrategyNumber:
                    if (chosen == NULL)
                    {
                        if (ScanDirectionIsBackward(dir))
                            chosen = cur;
                        else
                            impliesNN = cur;
                    }
                    break;
                case BTEqualStrategyNumber:
                    /* override any non-equality choice */
                    chosen = cur;
                    break;
                case BTGreaterEqualStrategyNumber:
                case BTGreaterStrategyNumber:
                    if (chosen == NULL)
                    {
                        if (ScanDirectionIsForward(dir))
                            chosen = cur;
                        else
                            impliesNN = cur;
                    }
                    break;
            }
        }
    }

    /*
     * If we found no usable boundary keys, we have to start from one end of
     * the tree.  Walk down that edge to the first or last key, and scan from
     * there.
     */
    if (keysCount == 0)
    {
        bool        match;

        match = _bt_endpoint(scan, dir);

        if (!match)
        {
            /* No match, so mark (parallel) scan finished */
            _bt_parallel_done(scan);
        }

        return match;
    }

    /*
     * We want to start the scan somewhere within the index.  Set up an
     * insertion scankey we can use to search for the boundary point we
     * identified above.  The insertion scankey is built using the keys
     * identified by startKeys[].  (Remaining insertion scankey fields are
     * initialized after initial-positioning strategy is finalized.)
     */
    Assert(keysCount <= INDEX_MAX_KEYS);
    for (i = 0; i < keysCount; i++)
    {
        ScanKey     cur = startKeys[i];

        Assert(cur->sk_attno == i + 1);

        if (cur->sk_flags & SK_ROW_HEADER)
        {
            /*
             * Row comparison header: look to the first row member instead.
             *
             * The member scankeys are already in insertion format (ie, they
             * have sk_func = 3-way-comparison function), but we have to watch
             * out for nulls, which _bt_preprocess_keys didn't check. A null
             * in the first row member makes the condition unmatchable, just
             * like qual_ok = false.
             */
            ScanKey     subkey = (ScanKey) DatumGetPointer(cur->sk_argument);

            Assert(subkey->sk_flags & SK_ROW_MEMBER);
            if (subkey->sk_flags & SK_ISNULL)
            {
                _bt_parallel_done(scan);
                return false;
            }
            memcpy(inskey.scankeys + i, subkey, sizeof(ScanKeyData));

            /*
             * If the row comparison is the last positioning key we accepted,
             * try to add additional keys from the lower-order row members.
             * (If we accepted independent conditions on additional index
             * columns, we use those instead --- doesn't seem worth trying to
             * determine which is more restrictive.)  Note that this is OK
             * even if the row comparison is of ">" or "<" type, because the
             * condition applied to all but the last row member is effectively
             * ">=" or "<=", and so the extra keys don't break the positioning
             * scheme.  But, by the same token, if we aren't able to use all
             * the row members, then the part of the row comparison that we
             * did use has to be treated as just a ">=" or "<=" condition, and
             * so we'd better adjust strat_total accordingly.
             */
            if (i == keysCount - 1)
            {
                bool        used_all_subkeys = false;

                Assert(!(subkey->sk_flags & SK_ROW_END));
                for (;;)
                {
                    subkey++;
                    Assert(subkey->sk_flags & SK_ROW_MEMBER);
                    if (subkey->sk_attno != keysCount + 1)
                        break;  /* out-of-sequence, can't use it */
                    if (subkey->sk_strategy != cur->sk_strategy)
                        break;  /* wrong direction, can't use it */
                    if (subkey->sk_flags & SK_ISNULL)
                        break;  /* can't use null keys */
                    Assert(keysCount < INDEX_MAX_KEYS);
                    memcpy(inskey.scankeys + keysCount, subkey,
                           sizeof(ScanKeyData));
                    keysCount++;
                    if (subkey->sk_flags & SK_ROW_END)
                    {
                        used_all_subkeys = true;
                        break;
                    }
                }
                if (!used_all_subkeys)
                {
                    switch (strat_total)
                    {
                        case BTLessStrategyNumber:
                            strat_total = BTLessEqualStrategyNumber;
                            break;
                        case BTGreaterStrategyNumber:
                            strat_total = BTGreaterEqualStrategyNumber;
                            break;
                    }
                }
                break;          /* done with outer loop */
            }
        }
        else
        {
            /*
             * Ordinary comparison key.  Transform the search-style scan key
             * to an insertion scan key by replacing the sk_func with the
             * appropriate btree comparison function.
             *
             * If scankey operator is not a cross-type comparison, we can use
             * the cached comparison function; otherwise gotta look it up in
             * the catalogs.  (That can't lead to infinite recursion, since no
             * indexscan initiated by syscache lookup will use cross-data-type
             * operators.)
             *
             * We support the convention that sk_subtype == InvalidOid means
             * the opclass input type; this is a hack to simplify life for
             * ScanKeyInit().
             */
            if (cur->sk_subtype == rel->rd_opcintype[i] ||
                cur->sk_subtype == InvalidOid)
            {
                FmgrInfo   *procinfo;

                procinfo = index_getprocinfo(rel, cur->sk_attno, BTORDER_PROC);
                ScanKeyEntryInitializeWithInfo(inskey.scankeys + i,
                                               cur->sk_flags,
                                               cur->sk_attno,
                                               InvalidStrategy,
                                               cur->sk_subtype,
                                               cur->sk_collation,
                                               procinfo,
                                               cur->sk_argument);
            }
            else
            {
                RegProcedure cmp_proc;

                cmp_proc = get_opfamily_proc(rel->rd_opfamily[i],
                                             rel->rd_opcintype[i],
                                             cur->sk_subtype,
                                             BTORDER_PROC);
                if (!RegProcedureIsValid(cmp_proc))
                    elog(ERROR, "missing support function %d(%u,%u) for attribute %d of index \"%s\"",
                         BTORDER_PROC, rel->rd_opcintype[i], cur->sk_subtype,
                         cur->sk_attno, RelationGetRelationName(rel));
                ScanKeyEntryInitialize(inskey.scankeys + i,
                                       cur->sk_flags,
                                       cur->sk_attno,
                                       InvalidStrategy,
                                       cur->sk_subtype,
                                       cur->sk_collation,
                                       cmp_proc,
                                       cur->sk_argument);
            }
        }
    }

    /*----------
     * Examine the selected initial-positioning strategy to determine exactly
     * where we need to start the scan, and set flag variables to control the
     * code below.
     *
     * If nextkey = false, _bt_search and _bt_binsrch will locate the first
     * item >= scan key.  If nextkey = true, they will locate the first
     * item > scan key.
     *
     * If goback = true, we will then step back one item, while if
     * goback = false, we will start the scan on the located item.
     *----------
     */
    switch (strat_total)
    {
        case BTLessStrategyNumber:

            /*
             * Find first item >= scankey, then back up one to arrive at last
             * item < scankey.  (Note: this positioning strategy is only used
             * for a backward scan, so that is always the correct starting
             * position.)
             */
            nextkey = false;
            goback = true;
            break;

        case BTLessEqualStrategyNumber:

            /*
             * Find first item > scankey, then back up one to arrive at last
             * item <= scankey.  (Note: this positioning strategy is only used
             * for a backward scan, so that is always the correct starting
             * position.)
             */
            nextkey = true;
            goback = true;
            break;

        case BTEqualStrategyNumber:

            /*
             * If a backward scan was specified, need to start with last equal
             * item not first one.
             */
            if (ScanDirectionIsBackward(dir))
            {
                /*
                 * This is the same as the <= strategy.  We will check at the
                 * end whether the found item is actually =.
                 */
                nextkey = true;
                goback = true;
            }
            else
            {
                /*
                 * This is the same as the >= strategy.  We will check at the
                 * end whether the found item is actually =.
                 */
                nextkey = false;
                goback = false;
            }
            break;

        case BTGreaterEqualStrategyNumber:

            /*
             * Find first item >= scankey.  (This is only used for forward
             * scans.)
             */
            nextkey = false;
            goback = false;
            break;

        case BTGreaterStrategyNumber:

            /*
             * Find first item > scankey.  (This is only used for forward
             * scans.)
             */
            nextkey = true;
            goback = false;
            break;

        default:
            /* can't get here, but keep compiler quiet */
            elog(ERROR, "unrecognized strat_total: %d", (int) strat_total);
            return false;
    }

    /* Initialize remaining insertion scan key fields */
    inskey.heapkeyspace = _bt_heapkeyspace(rel);
    inskey.anynullkeys = false; /* unused */
    inskey.nextkey = nextkey;
    inskey.pivotsearch = false;
    inskey.scantid = NULL;
    inskey.keysz = keysCount;

    /*
     * Use the manufactured insertion scan key to descend the tree and
     * position ourselves on the target leaf page.
     */
    stack = _bt_search(rel, &inskey, &buf, BT_READ, scan->xs_snapshot);

    /* don't need to keep the stack around... */
    _bt_freestack(stack);

    if (!BufferIsValid(buf))
    {
        /*
         * We only get here if the index is completely empty. Lock relation
         * because nothing finer to lock exists.
         */
        PredicateLockRelation(rel, scan->xs_snapshot);

        /*
         * mark parallel scan as done, so that all the workers can finish
         * their scan
         */
        _bt_parallel_done(scan);
        BTScanPosInvalidate(so->currPos);

        return false;
    }
    else
        PredicateLockPage(rel, BufferGetBlockNumber(buf),
                          scan->xs_snapshot);

    _bt_initialize_more_data(so, dir);

    /* position to the precise item on the page */
    offnum = _bt_binsrch(rel, &inskey, buf);

    /*
     * If nextkey = false, we are positioned at the first item >= scan key, or
     * possibly at the end of a page on which all the existing items are less
     * than the scan key and we know that everything on later pages is greater
     * than or equal to scan key.
     *
     * If nextkey = true, we are positioned at the first item > scan key, or
     * possibly at the end of a page on which all the existing items are less
     * than or equal to the scan key and we know that everything on later
     * pages is greater than scan key.
     *
     * The actually desired starting point is either this item or the prior
     * one, or in the end-of-page case it's the first item on the next page or
     * the last item on this page.  Adjust the starting offset if needed. (If
     * this results in an offset before the first item or after the last one,
     * _bt_readpage will report no items found, and then we'll step to the
     * next page as needed.)
     */
    if (goback)
        offnum = OffsetNumberPrev(offnum);

    /* remember which buffer we have pinned, if any */
    Assert(!BTScanPosIsValid(so->currPos));
    so->currPos.buf = buf;

    /*
     * Now load data from the first page of the scan.
     */
    if (!_bt_readpage(scan, dir, offnum))
    {
        /*
         * There's no actually-matching data on this page.  Try to advance to
         * the next page.  Return false if there's no matching data at all.
         */
        LockBuffer(so->currPos.buf, BUFFER_LOCK_UNLOCK);
        if (!_bt_steppage(scan, dir))
            return false;
    }
    else
    {
        /* Drop the lock, and maybe the pin, on the current page */
        _bt_drop_lock_and_maybe_pin(scan, &so->currPos);
    }

readcomplete:
    /* OK, itemIndex says what to return */
    currItem = &so->currPos.items[so->currPos.itemIndex];
    scan->xs_heaptid = currItem->heapTid;
    if (scan->xs_want_itup)
        scan->xs_itup = (IndexTuple) (so->currTuples + currItem->tupleOffset);

    return true;
}

_bt_freestack()

void _bt_freestack

(

BTStack

stack

)

Definition at line 164 of file nbtutils.c.

References BTStackData::bts_parent, and pfree().

Referenced by _bt_doinsert(), _bt_first(), and bt_rootdescend().

{
    BTStack     ostack;

    while (stack != NULL)
    {
        ostack = stack;
        stack = stack->bts_parent;
        pfree(ostack);
    }
}

_bt_get_endpoint()

Buffer _bt_get_endpoint	(	Relation	rel,
		uint32	level,
		bool	rightmost,
		Snapshot	snapshot
	)

Definition at line 2059 of file nbtsearch.c.

References _bt_getroot(), _bt_gettrueroot(), _bt_relandgetbuf(), BT_READ, BTPageOpaqueData::btpo, BTPageOpaqueData::btpo_next, BTreeTupleGetDownLink, buf, BufferGetPage, BufferIsValid, elog, ereport, errcode(), errmsg_internal(), ERROR, InvalidBuffer, BTPageOpaqueData::level, P_FIRSTDATAKEY, P_IGNORE, P_NONE, P_RIGHTMOST, PageGetItem, PageGetItemId, PageGetMaxOffsetNumber, PageGetSpecialPointer, RelationGetRelationName, and TestForOldSnapshot().

Referenced by _bt_endpoint(), and _bt_insert_parent().

{
    Buffer      buf;
    Page        page;
    BTPageOpaque opaque;
    OffsetNumber offnum;
    BlockNumber blkno;
    IndexTuple  itup;

    /*
     * If we are looking for a leaf page, okay to descend from fast root;
     * otherwise better descend from true root.  (There is no point in being
     * smarter about intermediate levels.)
     */
    if (level == 0)
        buf = _bt_getroot(rel, BT_READ);
    else
        buf = _bt_gettrueroot(rel);

    if (!BufferIsValid(buf))
        return InvalidBuffer;

    page = BufferGetPage(buf);
    TestForOldSnapshot(snapshot, rel, page);
    opaque = (BTPageOpaque) PageGetSpecialPointer(page);

    for (;;)
    {
        /*
         * If we landed on a deleted page, step right to find a live page
         * (there must be one).  Also, if we want the rightmost page, step
         * right if needed to get to it (this could happen if the page split
         * since we obtained a pointer to it).
         */
        while (P_IGNORE(opaque) ||
               (rightmost && !P_RIGHTMOST(opaque)))
        {
            blkno = opaque->btpo_next;
            if (blkno == P_NONE)
                elog(ERROR, "fell off the end of index \"%s\"",
                     RelationGetRelationName(rel));
            buf = _bt_relandgetbuf(rel, buf, blkno, BT_READ);
            page = BufferGetPage(buf);
            TestForOldSnapshot(snapshot, rel, page);
            opaque = (BTPageOpaque) PageGetSpecialPointer(page);
        }

        /* Done? */
        if (opaque->btpo.level == level)
            break;
        if (opaque->btpo.level < level)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg_internal("btree level %u not found in index \"%s\"",
                                     level, RelationGetRelationName(rel))));

        /* Descend to leftmost or rightmost child page */
        if (rightmost)
            offnum = PageGetMaxOffsetNumber(page);
        else
            offnum = P_FIRSTDATAKEY(opaque);

        itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, offnum));
        blkno = BTreeTupleGetDownLink(itup);

        buf = _bt_relandgetbuf(rel, buf, blkno, BT_READ);
        page = BufferGetPage(buf);
        opaque = (BTPageOpaque) PageGetSpecialPointer(page);
    }

    return buf;
}

_bt_getbuf()

Buffer _bt_getbuf	(	Relation	rel,
		BlockNumber	blkno,
		int	access
	)

Definition at line 757 of file nbtpage.c.

References _bt_checkpage(), _bt_log_reuse_page(), _bt_page_recyclable(), _bt_pageinit(), _bt_relbuf(), Assert, BT_WRITE, BTPageOpaqueData::btpo, buf, BufferGetPage, BufferGetPageSize, ConditionalLockBuffer(), DEBUG2, elog, ExclusiveLock, GetFreeIndexPage(), InvalidBlockNumber, LockBuffer(), LockRelationForExtension(), P_NEW, PageGetSpecialPointer, PageIsNew, ReadBuffer(), RELATION_IS_LOCAL, RelationNeedsWAL, ReleaseBuffer(), UnlockRelationForExtension(), BTPageOpaqueData::xact, and XLogStandbyInfoActive.

Referenced by _bt_finish_split(), _bt_getroot(), _bt_getrootheight(), _bt_getstackbuf(), _bt_gettrueroot(), _bt_heapkeyspace(), _bt_insertonpg(), _bt_is_page_halfdead(), _bt_killitems(), _bt_lock_branch_parent(), _bt_moveright(), _bt_newroot(), _bt_pagedel(), _bt_readnextpage(), _bt_split(), _bt_unlink_halfdead_page(), _bt_update_meta_cleanup_info(), _bt_vacuum_needs_cleanup(), and _bt_walk_left().

{
    Buffer      buf;

    if (blkno != P_NEW)
    {
        /* Read an existing block of the relation */
        buf = ReadBuffer(rel, blkno);
        LockBuffer(buf, access);
        _bt_checkpage(rel, buf);
    }
    else
    {
        bool        needLock;
        Page        page;

        Assert(access == BT_WRITE);

        /*
         * First see if the FSM knows of any free pages.
         *
         * We can't trust the FSM's report unreservedly; we have to check that
         * the page is still free.  (For example, an already-free page could
         * have been re-used between the time the last VACUUM scanned it and
         * the time the VACUUM made its FSM updates.)
         *
         * In fact, it's worse than that: we can't even assume that it's safe
         * to take a lock on the reported page.  If somebody else has a lock
         * on it, or even worse our own caller does, we could deadlock.  (The
         * own-caller scenario is actually not improbable. Consider an index
         * on a serial or timestamp column.  Nearly all splits will be at the
         * rightmost page, so it's entirely likely that _bt_split will call us
         * while holding a lock on the page most recently acquired from FSM. A
         * VACUUM running concurrently with the previous split could well have
         * placed that page back in FSM.)
         *
         * To get around that, we ask for only a conditional lock on the
         * reported page.  If we fail, then someone else is using the page,
         * and we may reasonably assume it's not free.  (If we happen to be
         * wrong, the worst consequence is the page will be lost to use till
         * the next VACUUM, which is no big problem.)
         */
        for (;;)
        {
            blkno = GetFreeIndexPage(rel);
            if (blkno == InvalidBlockNumber)
                break;
            buf = ReadBuffer(rel, blkno);
            if (ConditionalLockBuffer(buf))
            {
                page = BufferGetPage(buf);
                if (_bt_page_recyclable(page))
                {
                    /*
                     * If we are generating WAL for Hot Standby then create a
                     * WAL record that will allow us to conflict with queries
                     * running on standby, in case they have snapshots older
                     * than btpo.xact.  This can only apply if the page does
                     * have a valid btpo.xact value, ie not if it's new.  (We
                     * must check that because an all-zero page has no special
                     * space.)
                     */
                    if (XLogStandbyInfoActive() && RelationNeedsWAL(rel) &&
                        !PageIsNew(page))
                    {
                        BTPageOpaque opaque = (BTPageOpaque) PageGetSpecialPointer(page);

                        _bt_log_reuse_page(rel, blkno, opaque->btpo.xact);
                    }

                    /* Okay to use page.  Re-initialize and return it */
                    _bt_pageinit(page, BufferGetPageSize(buf));
                    return buf;
                }
                elog(DEBUG2, "FSM returned nonrecyclable page");
                _bt_relbuf(rel, buf);
            }
            else
            {
                elog(DEBUG2, "FSM returned nonlockable page");
                /* couldn't get lock, so just drop pin */
                ReleaseBuffer(buf);
            }
        }

        /*
         * Extend the relation by one page.
         *
         * We have to use a lock to ensure no one else is extending the rel at
         * the same time, else we will both try to initialize the same new
         * page.  We can skip locking for new or temp relations, however,
         * since no one else could be accessing them.
         */
        needLock = !RELATION_IS_LOCAL(rel);

        if (needLock)
            LockRelationForExtension(rel, ExclusiveLock);

        buf = ReadBuffer(rel, P_NEW);

        /* Acquire buffer lock on new page */
        LockBuffer(buf, BT_WRITE);

        /*
         * Release the file-extension lock; it's now OK for someone else to
         * extend the relation some more.  Note that we cannot release this
         * lock before we have buffer lock on the new page, or we risk a race
         * condition against btvacuumscan --- see comments therein.
         */
        if (needLock)
            UnlockRelationForExtension(rel, ExclusiveLock);

        /* Initialize the new page before returning it */
        page = BufferGetPage(buf);
        Assert(PageIsNew(page));
        _bt_pageinit(page, BufferGetPageSize(buf));
    }

    /* ref count and lock type are correct */
    return buf;
}

_bt_getroot()

Buffer _bt_getroot	(	Relation	rel,
		int	access
	)

Definition at line 255 of file nbtpage.c.

References _bt_getbuf(), _bt_getmeta(), _bt_getroot(), _bt_relandgetbuf(), _bt_relbuf(), _bt_upgrademetapage(), Assert, BT_READ, BT_WRITE, BTMetaPageData::btm_fastlevel, BTMetaPageData::btm_fastroot, BTMetaPageData::btm_last_cleanup_num_heap_tuples, BTMetaPageData::btm_level, BTMetaPageData::btm_magic, BTMetaPageData::btm_oldest_btpo_xact, BTMetaPageData::btm_root, BTMetaPageData::btm_version, BTP_LEAF, BTP_ROOT, BTPageOpaqueData::btpo, BTPageOpaqueData::btpo_cycleid, BTPageOpaqueData::btpo_flags, BTPageOpaqueData::btpo_next, BTPageOpaqueData::btpo_prev, BTREE_MAGIC, BTREE_METAPAGE, BTREE_MIN_VERSION, BTREE_NOVAC_VERSION, BTREE_VERSION, BUFFER_LOCK_UNLOCK, BufferGetBlockNumber(), BufferGetPage, elog, END_CRIT_SECTION, ERROR, xl_btree_metadata::fastlevel, xl_btree_metadata::fastroot, InvalidBuffer, InvalidTransactionId, xl_btree_metadata::last_cleanup_num_heap_tuples, xl_btree_metadata::level, BTPageOpaqueData::level, xl_btree_newroot::level, LockBuffer(), MarkBufferDirty(), MemoryContextAlloc(), xl_btree_metadata::oldest_btpo_xact, P_IGNORE, P_LEFTMOST, P_NEW, P_NONE, P_RIGHTMOST, PageGetSpecialPointer, PageSetLSN, pfree(), RelationData::rd_amcache, RelationData::rd_indexcxt, REGBUF_STANDARD, REGBUF_WILL_INIT, RelationGetRelationName, RelationNeedsWAL, xl_btree_metadata::root, xl_btree_newroot::rootblk, SizeOfBtreeNewroot, START_CRIT_SECTION, xl_btree_metadata::version, XLOG_BTREE_NEWROOT, XLogBeginInsert(), XLogInsert(), XLogRegisterBufData(), XLogRegisterBuffer(), and XLogRegisterData().

Referenced by _bt_get_endpoint(), _bt_getroot(), and _bt_search().

{
    Buffer      metabuf;
    Buffer      rootbuf;
    Page        rootpage;
    BTPageOpaque rootopaque;
    BlockNumber rootblkno;
    uint32      rootlevel;
    BTMetaPageData *metad;

    /*
     * Try to use previously-cached metapage data to find the root.  This
     * normally saves one buffer access per index search, which is a very
     * helpful savings in bufmgr traffic and hence contention.
     */
    if (rel->rd_amcache != NULL)
    {
        metad = (BTMetaPageData *) rel->rd_amcache;
        /* We shouldn't have cached it if any of these fail */
        Assert(metad->btm_magic == BTREE_MAGIC);
        Assert(metad->btm_version >= BTREE_MIN_VERSION);
        Assert(metad->btm_version <= BTREE_VERSION);
        Assert(metad->btm_root != P_NONE);

        rootblkno = metad->btm_fastroot;
        Assert(rootblkno != P_NONE);
        rootlevel = metad->btm_fastlevel;

        rootbuf = _bt_getbuf(rel, rootblkno, BT_READ);
        rootpage = BufferGetPage(rootbuf);
        rootopaque = (BTPageOpaque) PageGetSpecialPointer(rootpage);

        /*
         * Since the cache might be stale, we check the page more carefully
         * here than normal.  We *must* check that it's not deleted. If it's
         * not alone on its level, then we reject too --- this may be overly
         * paranoid but better safe than sorry.  Note we don't check P_ISROOT,
         * because that's not set in a "fast root".
         */
        if (!P_IGNORE(rootopaque) &&
            rootopaque->btpo.level == rootlevel &&
            P_LEFTMOST(rootopaque) &&
            P_RIGHTMOST(rootopaque))
        {
            /* OK, accept cached page as the root */
            return rootbuf;
        }
        _bt_relbuf(rel, rootbuf);
        /* Cache is stale, throw it away */
        if (rel->rd_amcache)
            pfree(rel->rd_amcache);
        rel->rd_amcache = NULL;
    }

    metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_READ);
    metad = _bt_getmeta(rel, metabuf);

    /* if no root page initialized yet, do it */
    if (metad->btm_root == P_NONE)
    {
        Page        metapg;

        /* If access = BT_READ, caller doesn't want us to create root yet */
        if (access == BT_READ)
        {
            _bt_relbuf(rel, metabuf);
            return InvalidBuffer;
        }

        /* trade in our read lock for a write lock */
        LockBuffer(metabuf, BUFFER_LOCK_UNLOCK);
        LockBuffer(metabuf, BT_WRITE);

        /*
         * Race condition:  if someone else initialized the metadata between
         * the time we released the read lock and acquired the write lock, we
         * must avoid doing it again.
         */
        if (metad->btm_root != P_NONE)
        {
            /*
             * Metadata initialized by someone else.  In order to guarantee no
             * deadlocks, we have to release the metadata page and start all
             * over again.  (Is that really true? But it's hardly worth trying
             * to optimize this case.)
             */
            _bt_relbuf(rel, metabuf);
            return _bt_getroot(rel, access);
        }

        /*
         * Get, initialize, write, and leave a lock of the appropriate type on
         * the new root page.  Since this is the first page in the tree, it's
         * a leaf as well as the root.
         */
        rootbuf = _bt_getbuf(rel, P_NEW, BT_WRITE);
        rootblkno = BufferGetBlockNumber(rootbuf);
        rootpage = BufferGetPage(rootbuf);
        rootopaque = (BTPageOpaque) PageGetSpecialPointer(rootpage);
        rootopaque->btpo_prev = rootopaque->btpo_next = P_NONE;
        rootopaque->btpo_flags = (BTP_LEAF | BTP_ROOT);
        rootopaque->btpo.level = 0;
        rootopaque->btpo_cycleid = 0;
        /* Get raw page pointer for metapage */
        metapg = BufferGetPage(metabuf);

        /* NO ELOG(ERROR) till meta is updated */
        START_CRIT_SECTION();

        /* upgrade metapage if needed */
        if (metad->btm_version < BTREE_NOVAC_VERSION)
            _bt_upgrademetapage(metapg);

        metad->btm_root = rootblkno;
        metad->btm_level = 0;
        metad->btm_fastroot = rootblkno;
        metad->btm_fastlevel = 0;
        metad->btm_oldest_btpo_xact = InvalidTransactionId;
        metad->btm_last_cleanup_num_heap_tuples = -1.0;

        MarkBufferDirty(rootbuf);
        MarkBufferDirty(metabuf);

        /* XLOG stuff */
        if (RelationNeedsWAL(rel))
        {
            xl_btree_newroot xlrec;
            XLogRecPtr  recptr;
            xl_btree_metadata md;

            XLogBeginInsert();
            XLogRegisterBuffer(0, rootbuf, REGBUF_WILL_INIT);
            XLogRegisterBuffer(2, metabuf, REGBUF_WILL_INIT | REGBUF_STANDARD);

            Assert(metad->btm_version >= BTREE_NOVAC_VERSION);
            md.version = metad->btm_version;
            md.root = rootblkno;
            md.level = 0;
            md.fastroot = rootblkno;
            md.fastlevel = 0;
            md.oldest_btpo_xact = InvalidTransactionId;
            md.last_cleanup_num_heap_tuples = -1.0;

            XLogRegisterBufData(2, (char *) &md, sizeof(xl_btree_metadata));

            xlrec.rootblk = rootblkno;
            xlrec.level = 0;

            XLogRegisterData((char *) &xlrec, SizeOfBtreeNewroot);

            recptr = XLogInsert(RM_BTREE_ID, XLOG_BTREE_NEWROOT);

            PageSetLSN(rootpage, recptr);
            PageSetLSN(metapg, recptr);
        }

        END_CRIT_SECTION();

        /*
         * swap root write lock for read lock.  There is no danger of anyone
         * else accessing the new root page while it's unlocked, since no one
         * else knows where it is yet.
         */
        LockBuffer(rootbuf, BUFFER_LOCK_UNLOCK);
        LockBuffer(rootbuf, BT_READ);

        /* okay, metadata is correct, release lock on it without caching */
        _bt_relbuf(rel, metabuf);
    }
    else
    {
        rootblkno = metad->btm_fastroot;
        Assert(rootblkno != P_NONE);
        rootlevel = metad->btm_fastlevel;

        /*
         * Cache the metapage data for next time
         */
        rel->rd_amcache = MemoryContextAlloc(rel->rd_indexcxt,
                                             sizeof(BTMetaPageData));
        memcpy(rel->rd_amcache, metad, sizeof(BTMetaPageData));

        /*
         * We are done with the metapage; arrange to release it via first
         * _bt_relandgetbuf call
         */
        rootbuf = metabuf;

        for (;;)
        {
            rootbuf = _bt_relandgetbuf(rel, rootbuf, rootblkno, BT_READ);
            rootpage = BufferGetPage(rootbuf);
            rootopaque = (BTPageOpaque) PageGetSpecialPointer(rootpage);

            if (!P_IGNORE(rootopaque))
                break;

            /* it's dead, Jim.  step right one page */
            if (P_RIGHTMOST(rootopaque))
                elog(ERROR, "no live root page found in index \"%s\"",
                     RelationGetRelationName(rel));
            rootblkno = rootopaque->btpo_next;
        }

        /* Note: can't check btpo.level on deleted pages */
        if (rootopaque->btpo.level != rootlevel)
            elog(ERROR, "root page %u of index \"%s\" has level %u, expected %u",
                 rootblkno, RelationGetRelationName(rel),
                 rootopaque->btpo.level, rootlevel);
    }

    /*
     * By here, we have a pin and read lock on the root page, and no lock set
     * on the metadata page.  Return the root page's buffer.
     */
    return rootbuf;
}

_bt_getrootheight()

int _bt_getrootheight

(

Relation

rel

)

Definition at line 584 of file nbtpage.c.

References _bt_getbuf(), _bt_getmeta(), _bt_relbuf(), Assert, BT_READ, BTMetaPageData::btm_fastlevel, BTMetaPageData::btm_fastroot, BTMetaPageData::btm_magic, BTMetaPageData::btm_root, BTMetaPageData::btm_version, BTREE_MAGIC, BTREE_METAPAGE, BTREE_MIN_VERSION, BTREE_VERSION, MemoryContextAlloc(), P_NONE, RelationData::rd_amcache, and RelationData::rd_indexcxt.

Referenced by _bt_insertonpg(), and get_relation_info().

{
    BTMetaPageData *metad;

    if (rel->rd_amcache == NULL)
    {
        Buffer      metabuf;

        metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_READ);
        metad = _bt_getmeta(rel, metabuf);

        /*
         * If there's no root page yet, _bt_getroot() doesn't expect a cache
         * to be made, so just stop here and report the index height is zero.
         * (XXX perhaps _bt_getroot() should be changed to allow this case.)
         */
        if (metad->btm_root == P_NONE)
        {
            _bt_relbuf(rel, metabuf);
            return 0;
        }

        /*
         * Cache the metapage data for next time
         */
        rel->rd_amcache = MemoryContextAlloc(rel->rd_indexcxt,
                                             sizeof(BTMetaPageData));
        memcpy(rel->rd_amcache, metad, sizeof(BTMetaPageData));
        _bt_relbuf(rel, metabuf);
    }

    /* Get cached page */
    metad = (BTMetaPageData *) rel->rd_amcache;
    /* We shouldn't have cached it if any of these fail */
    Assert(metad->btm_magic == BTREE_MAGIC);
    Assert(metad->btm_version >= BTREE_MIN_VERSION);
    Assert(metad->btm_version <= BTREE_VERSION);
    Assert(metad->btm_fastroot != P_NONE);

    return metad->btm_fastlevel;
}

_bt_getstackbuf()

Buffer _bt_getstackbuf	(	Relation	rel,
		BTStack	stack,
		BlockNumber	child
	)

Definition at line 1927 of file nbtinsert.c.

References _bt_finish_split(), _bt_getbuf(), _bt_relbuf(), BT_WRITE, BTPageOpaqueData::btpo_next, BTreeTupleGetDownLink, BTStackData::bts_blkno, BTStackData::bts_offset, BTStackData::bts_parent, buf, BufferGetPage, InvalidBuffer, InvalidOffsetNumber, OffsetNumberNext, OffsetNumberPrev, P_FIRSTDATAKEY, P_IGNORE, P_INCOMPLETE_SPLIT, P_RIGHTMOST, PageGetItem, PageGetItemId, PageGetMaxOffsetNumber, and PageGetSpecialPointer.

Referenced by _bt_insert_parent(), and _bt_lock_branch_parent().

{
    BlockNumber blkno;
    OffsetNumber start;

    blkno = stack->bts_blkno;
    start = stack->bts_offset;

    for (;;)
    {
        Buffer      buf;
        Page        page;
        BTPageOpaque opaque;

        buf = _bt_getbuf(rel, blkno, BT_WRITE);
        page = BufferGetPage(buf);
        opaque = (BTPageOpaque) PageGetSpecialPointer(page);

        if (P_INCOMPLETE_SPLIT(opaque))
        {
            _bt_finish_split(rel, buf, stack->bts_parent);
            continue;
        }

        if (!P_IGNORE(opaque))
        {
            OffsetNumber offnum,
                        minoff,
                        maxoff;
            ItemId      itemid;
            IndexTuple  item;

            minoff = P_FIRSTDATAKEY(opaque);
            maxoff = PageGetMaxOffsetNumber(page);

            /*
             * start = InvalidOffsetNumber means "search the whole page". We
             * need this test anyway due to possibility that page has a high
             * key now when it didn't before.
             */
            if (start < minoff)
                start = minoff;

            /*
             * Need this check too, to guard against possibility that page
             * split since we visited it originally.
             */
            if (start > maxoff)
                start = OffsetNumberNext(maxoff);

            /*
             * These loops will check every item on the page --- but in an
             * order that's attuned to the probability of where it actually
             * is.  Scan to the right first, then to the left.
             */
            for (offnum = start;
                 offnum <= maxoff;
                 offnum = OffsetNumberNext(offnum))
            {
                itemid = PageGetItemId(page, offnum);
                item = (IndexTuple) PageGetItem(page, itemid);

                if (BTreeTupleGetDownLink(item) == child)
                {
                    /* Return accurate pointer to where link is now */
                    stack->bts_blkno = blkno;
                    stack->bts_offset = offnum;
                    return buf;
                }
            }

            for (offnum = OffsetNumberPrev(start);
                 offnum >= minoff;
                 offnum = OffsetNumberPrev(offnum))
            {
                itemid = PageGetItemId(page, offnum);
                item = (IndexTuple) PageGetItem(page, itemid);

                if (BTreeTupleGetDownLink(item) == child)
                {
                    /* Return accurate pointer to where link is now */
                    stack->bts_blkno = blkno;
                    stack->bts_offset = offnum;
                    return buf;
                }
            }
        }

        /*
         * The item we're looking for moved right at least one page.
         *
         * Lehman and Yao couple/chain locks when moving right here, which we
         * can avoid.  See nbtree/README.
         */
        if (P_RIGHTMOST(opaque))
        {
            _bt_relbuf(rel, buf);
            return InvalidBuffer;
        }
        blkno = opaque->btpo_next;
        start = InvalidOffsetNumber;
        _bt_relbuf(rel, buf);
    }
}

_bt_gettrueroot()

Buffer _bt_gettrueroot

(

Relation

rel

)

Definition at line 488 of file nbtpage.c.

References _bt_getbuf(), _bt_relandgetbuf(), _bt_relbuf(), BT_READ, BTMetaPageData::btm_level, BTMetaPageData::btm_magic, BTMetaPageData::btm_root, BTMetaPageData::btm_version, BTPageGetMeta, BTPageOpaqueData::btpo, BTPageOpaqueData::btpo_next, BTREE_MAGIC, BTREE_METAPAGE, BTREE_MIN_VERSION, BTREE_VERSION, BufferGetPage, elog, ereport, errcode(), errmsg(), ERROR, InvalidBuffer, BTPageOpaqueData::level, P_IGNORE, P_ISMETA, P_NONE, P_RIGHTMOST, PageGetSpecialPointer, pfree(), RelationData::rd_amcache, and RelationGetRelationName.

Referenced by _bt_get_endpoint().

{
    Buffer      metabuf;
    Page        metapg;
    BTPageOpaque metaopaque;
    Buffer      rootbuf;
    Page        rootpage;
    BTPageOpaque rootopaque;
    BlockNumber rootblkno;
    uint32      rootlevel;
    BTMetaPageData *metad;

    /*
     * We don't try to use cached metapage data here, since (a) this path is
     * not performance-critical, and (b) if we are here it suggests our cache
     * is out-of-date anyway.  In light of point (b), it's probably safest to
     * actively flush any cached metapage info.
     */
    if (rel->rd_amcache)
        pfree(rel->rd_amcache);
    rel->rd_amcache = NULL;

    metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_READ);
    metapg = BufferGetPage(metabuf);
    metaopaque = (BTPageOpaque) PageGetSpecialPointer(metapg);
    metad = BTPageGetMeta(metapg);

    if (!P_ISMETA(metaopaque) ||
        metad->btm_magic != BTREE_MAGIC)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("index \"%s\" is not a btree",
                        RelationGetRelationName(rel))));

    if (metad->btm_version < BTREE_MIN_VERSION ||
        metad->btm_version > BTREE_VERSION)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("version mismatch in index \"%s\": file version %d, "
                        "current version %d, minimal supported version %d",
                        RelationGetRelationName(rel),
                        metad->btm_version, BTREE_VERSION, BTREE_MIN_VERSION)));

    /* if no root page initialized yet, fail */
    if (metad->btm_root == P_NONE)
    {
        _bt_relbuf(rel, metabuf);
        return InvalidBuffer;
    }

    rootblkno = metad->btm_root;
    rootlevel = metad->btm_level;

    /*
     * We are done with the metapage; arrange to release it via first
     * _bt_relandgetbuf call
     */
    rootbuf = metabuf;

    for (;;)
    {
        rootbuf = _bt_relandgetbuf(rel, rootbuf, rootblkno, BT_READ);
        rootpage = BufferGetPage(rootbuf);
        rootopaque = (BTPageOpaque) PageGetSpecialPointer(rootpage);

        if (!P_IGNORE(rootopaque))
            break;

        /* it's dead, Jim.  step right one page */
        if (P_RIGHTMOST(rootopaque))
            elog(ERROR, "no live root page found in index \"%s\"",
                 RelationGetRelationName(rel));
        rootblkno = rootopaque->btpo_next;
    }

    /* Note: can't check btpo.level on deleted pages */
    if (rootopaque->btpo.level != rootlevel)
        elog(ERROR, "root page %u of index \"%s\" has level %u, expected %u",
             rootblkno, RelationGetRelationName(rel),
             rootopaque->btpo.level, rootlevel);

    return rootbuf;
}

_bt_heapkeyspace()

bool _bt_heapkeyspace

(

Relation

rel

)

Definition at line 636 of file nbtpage.c.

References _bt_getbuf(), _bt_getmeta(), _bt_relbuf(), Assert, BT_READ, BTMetaPageData::btm_fastroot, BTMetaPageData::btm_magic, BTMetaPageData::btm_root, BTMetaPageData::btm_version, BTREE_MAGIC, BTREE_METAPAGE, BTREE_MIN_VERSION, BTREE_NOVAC_VERSION, BTREE_VERSION, MemoryContextAlloc(), P_NONE, RelationData::rd_amcache, and RelationData::rd_indexcxt.

Referenced by _bt_first(), _bt_mkscankey(), and bt_index_check_internal().

{
    BTMetaPageData *metad;

    if (rel->rd_amcache == NULL)
    {
        Buffer      metabuf;

        metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_READ);
        metad = _bt_getmeta(rel, metabuf);

        /*
         * If there's no root page yet, _bt_getroot() doesn't expect a cache
         * to be made, so just stop here.  (XXX perhaps _bt_getroot() should
         * be changed to allow this case.)
         */
        if (metad->btm_root == P_NONE)
        {
            uint32      btm_version = metad->btm_version;

            _bt_relbuf(rel, metabuf);
            return btm_version > BTREE_NOVAC_VERSION;
        }

        /*
         * Cache the metapage data for next time
         *
         * An on-the-fly version upgrade performed by _bt_upgrademetapage()
         * can change the nbtree version for an index without invalidating any
         * local cache.  This is okay because it can only happen when moving
         * from version 2 to version 3, both of which are !heapkeyspace
         * versions.
         */
        rel->rd_amcache = MemoryContextAlloc(rel->rd_indexcxt,
                                             sizeof(BTMetaPageData));
        memcpy(rel->rd_amcache, metad, sizeof(BTMetaPageData));
        _bt_relbuf(rel, metabuf);
    }

    /* Get cached page */
    metad = (BTMetaPageData *) rel->rd_amcache;
    /* We shouldn't have cached it if any of these fail */
    Assert(metad->btm_magic == BTREE_MAGIC);
    Assert(metad->btm_version >= BTREE_MIN_VERSION);
    Assert(metad->btm_version <= BTREE_VERSION);
    Assert(metad->btm_fastroot != P_NONE);

    return metad->btm_version > BTREE_NOVAC_VERSION;
}

_bt_initmetapage()

void _bt_initmetapage	(	Page	page,
		BlockNumber	rootbknum,
		uint32	level
	)

Definition at line 50 of file nbtpage.c.

References _bt_pageinit(), BTMetaPageData::btm_fastlevel, BTMetaPageData::btm_fastroot, BTMetaPageData::btm_last_cleanup_num_heap_tuples, BTMetaPageData::btm_level, BTMetaPageData::btm_magic, BTMetaPageData::btm_oldest_btpo_xact, BTMetaPageData::btm_root, BTMetaPageData::btm_version, BTP_META, BTPageGetMeta, BTPageOpaqueData::btpo_flags, BTREE_MAGIC, BTREE_VERSION, InvalidTransactionId, and PageGetSpecialPointer.

Referenced by _bt_uppershutdown(), and btbuildempty().

{
    BTMetaPageData *metad;
    BTPageOpaque metaopaque;

    _bt_pageinit(page, BLCKSZ);

    metad = BTPageGetMeta(page);
    metad->btm_magic = BTREE_MAGIC;
    metad->btm_version = BTREE_VERSION;
    metad->btm_root = rootbknum;
    metad->btm_level = level;
    metad->btm_fastroot = rootbknum;
    metad->btm_fastlevel = level;
    metad->btm_oldest_btpo_xact = InvalidTransactionId;
    metad->btm_last_cleanup_num_heap_tuples = -1.0;

    metaopaque = (BTPageOpaque) PageGetSpecialPointer(page);
    metaopaque->btpo_flags = BTP_META;

    /*
     * Set pd_lower just past the end of the metadata.  This is essential,
     * because without doing so, metadata will be lost if xlog.c compresses
     * the page.
     */
    ((PageHeader) page)->pd_lower =
        ((char *) metad + sizeof(BTMetaPageData)) - (char *) page;
}

_bt_keep_natts_fast()

int _bt_keep_natts_fast	(	Relation	rel,
		IndexTuple	lastleft,
		IndexTuple	firstright
	)

Definition at line 2326 of file nbtutils.c.

References attnum, datum_image_eq(), index_getattr, IndexRelationGetNumberOfKeyAttributes, RelationGetDescr, and TupleDescAttr.

Referenced by _bt_afternewitemoff(), _bt_split_penalty(), and _bt_strategy().

{
    TupleDesc   itupdesc = RelationGetDescr(rel);
    int         keysz = IndexRelationGetNumberOfKeyAttributes(rel);
    int         keepnatts;

    keepnatts = 1;
    for (int attnum = 1; attnum <= keysz; attnum++)
    {
        Datum       datum1,
                    datum2;
        bool        isNull1,
                    isNull2;
        Form_pg_attribute att;

        datum1 = index_getattr(lastleft, attnum, itupdesc, &isNull1);
        datum2 = index_getattr(firstright, attnum, itupdesc, &isNull2);
        att = TupleDescAttr(itupdesc, attnum - 1);

        if (isNull1 != isNull2)
            break;

        if (!isNull1 &&
            !datum_image_eq(datum1, datum2, att->attbyval, att->attlen))
            break