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168d5805e4
The newly added ON CONFLICT clause allows to specify an alternative to
raising a unique or exclusion constraint violation error when inserting.
ON CONFLICT refers to constraints that can either be specified using a
inference clause (by specifying the columns of a unique constraint) or
by naming a unique or exclusion constraint. DO NOTHING avoids the
constraint violation, without touching the pre-existing row. DO UPDATE
SET ... [WHERE ...] updates the pre-existing tuple, and has access to
both the tuple proposed for insertion and the existing tuple; the
optional WHERE clause can be used to prevent an update from being
executed. The UPDATE SET and WHERE clauses have access to the tuple
proposed for insertion using the "magic" EXCLUDED alias, and to the
pre-existing tuple using the table name or its alias.
This feature is often referred to as upsert.
This is implemented using a new infrastructure called "speculative
insertion". It is an optimistic variant of regular insertion that first
does a pre-check for existing tuples and then attempts an insert. If a
violating tuple was inserted concurrently, the speculatively inserted
tuple is deleted and a new attempt is made. If the pre-check finds a
matching tuple the alternative DO NOTHING or DO UPDATE action is taken.
If the insertion succeeds without detecting a conflict, the tuple is
deemed inserted.
To handle the possible ambiguity between the excluded alias and a table
named excluded, and for convenience with long relation names, INSERT
INTO now can alias its target table.
Bumps catversion as stored rules change.
Author: Peter Geoghegan, with significant contributions from Heikki
Linnakangas and Andres Freund. Testing infrastructure by Jeff Janes.
Reviewed-By: Heikki Linnakangas, Andres Freund, Robert Haas, Simon Riggs,
Dean Rasheed, Stephen Frost and many others.
394 lines
12 KiB
C
394 lines
12 KiB
C
/*-------------------------------------------------------------------------
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*
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* heapam_xlog.h
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* POSTGRES heap access XLOG definitions.
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*
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*
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* Portions Copyright (c) 1996-2015, PostgreSQL Global Development Group
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* Portions Copyright (c) 1994, Regents of the University of California
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*
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* src/include/access/heapam_xlog.h
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*
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*-------------------------------------------------------------------------
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*/
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#ifndef HEAPAM_XLOG_H
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#define HEAPAM_XLOG_H
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#include "access/htup.h"
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#include "access/xlogreader.h"
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#include "lib/stringinfo.h"
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#include "storage/buf.h"
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#include "storage/bufpage.h"
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#include "storage/relfilenode.h"
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#include "utils/relcache.h"
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/*
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* WAL record definitions for heapam.c's WAL operations
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*
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* XLOG allows to store some information in high 4 bits of log
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* record xl_info field. We use 3 for opcode and one for init bit.
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*/
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#define XLOG_HEAP_INSERT 0x00
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#define XLOG_HEAP_DELETE 0x10
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#define XLOG_HEAP_UPDATE 0x20
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/* 0x030 is free, was XLOG_HEAP_MOVE */
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#define XLOG_HEAP_HOT_UPDATE 0x40
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#define XLOG_HEAP_CONFIRM 0x50
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#define XLOG_HEAP_LOCK 0x60
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#define XLOG_HEAP_INPLACE 0x70
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#define XLOG_HEAP_OPMASK 0x70
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/*
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* When we insert 1st item on new page in INSERT, UPDATE, HOT_UPDATE,
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* or MULTI_INSERT, we can (and we do) restore entire page in redo
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*/
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#define XLOG_HEAP_INIT_PAGE 0x80
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/*
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* We ran out of opcodes, so heapam.c now has a second RmgrId. These opcodes
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* are associated with RM_HEAP2_ID, but are not logically different from
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* the ones above associated with RM_HEAP_ID. XLOG_HEAP_OPMASK applies to
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* these, too.
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*/
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#define XLOG_HEAP2_REWRITE 0x00
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#define XLOG_HEAP2_CLEAN 0x10
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#define XLOG_HEAP2_FREEZE_PAGE 0x20
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#define XLOG_HEAP2_CLEANUP_INFO 0x30
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#define XLOG_HEAP2_VISIBLE 0x40
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#define XLOG_HEAP2_MULTI_INSERT 0x50
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#define XLOG_HEAP2_LOCK_UPDATED 0x60
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#define XLOG_HEAP2_NEW_CID 0x70
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/*
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* xl_heap_insert/xl_heap_multi_insert flag values, 8 bits are available.
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*/
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/* PD_ALL_VISIBLE was cleared */
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#define XLH_INSERT_ALL_VISIBLE_CLEARED (1<<0)
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#define XLH_INSERT_LAST_IN_MULTI (1<<1)
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#define XLH_INSERT_IS_SPECULATIVE (1<<2)
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#define XLH_INSERT_CONTAINS_NEW_TUPLE (1<<3)
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/*
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* xl_heap_update flag values, 8 bits are available.
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*/
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/* PD_ALL_VISIBLE was cleared */
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#define XLH_UPDATE_OLD_ALL_VISIBLE_CLEARED (1<<0)
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/* PD_ALL_VISIBLE was cleared in the 2nd page */
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#define XLH_UPDATE_NEW_ALL_VISIBLE_CLEARED (1<<1)
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#define XLH_UPDATE_CONTAINS_OLD_TUPLE (1<<2)
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#define XLH_UPDATE_CONTAINS_OLD_KEY (1<<3)
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#define XLH_UPDATE_CONTAINS_NEW_TUPLE (1<<4)
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#define XLH_UPDATE_PREFIX_FROM_OLD (1<<5)
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#define XLH_UPDATE_SUFFIX_FROM_OLD (1<<6)
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/* convenience macro for checking whether any form of old tuple was logged */
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#define XLH_UPDATE_CONTAINS_OLD \
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(XLH_UPDATE_CONTAINS_OLD_TUPLE | XLH_UPDATE_CONTAINS_OLD_KEY)
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/*
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* xl_heap_delete flag values, 8 bits are available.
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*/
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/* PD_ALL_VISIBLE was cleared */
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#define XLH_DELETE_ALL_VISIBLE_CLEARED (1<<0)
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#define XLH_DELETE_CONTAINS_OLD_TUPLE (1<<1)
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#define XLH_DELETE_CONTAINS_OLD_KEY (1<<2)
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#define XLH_DELETE_IS_SUPER (1<<3)
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/* convenience macro for checking whether any form of old tuple was logged */
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#define XLH_DELETE_CONTAINS_OLD \
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(XLH_DELETE_CONTAINS_OLD_TUPLE | XLH_DELETE_CONTAINS_OLD_KEY)
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/* This is what we need to know about delete */
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typedef struct xl_heap_delete
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{
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TransactionId xmax; /* xmax of the deleted tuple */
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OffsetNumber offnum; /* deleted tuple's offset */
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uint8 infobits_set; /* infomask bits */
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uint8 flags;
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} xl_heap_delete;
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#define SizeOfHeapDelete (offsetof(xl_heap_delete, flags) + sizeof(uint8))
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/*
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* We don't store the whole fixed part (HeapTupleHeaderData) of an inserted
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* or updated tuple in WAL; we can save a few bytes by reconstructing the
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* fields that are available elsewhere in the WAL record, or perhaps just
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* plain needn't be reconstructed. These are the fields we must store.
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* NOTE: t_hoff could be recomputed, but we may as well store it because
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* it will come for free due to alignment considerations.
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*/
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typedef struct xl_heap_header
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{
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uint16 t_infomask2;
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uint16 t_infomask;
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uint8 t_hoff;
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} xl_heap_header;
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#define SizeOfHeapHeader (offsetof(xl_heap_header, t_hoff) + sizeof(uint8))
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/* This is what we need to know about insert */
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typedef struct xl_heap_insert
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{
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OffsetNumber offnum; /* inserted tuple's offset */
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uint8 flags;
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/* xl_heap_header & TUPLE DATA in backup block 0 */
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} xl_heap_insert;
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#define SizeOfHeapInsert (offsetof(xl_heap_insert, flags) + sizeof(uint8))
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/*
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* This is what we need to know about a multi-insert.
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*
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* The main data of the record consists of this xl_heap_multi_insert header.
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* 'offsets' array is omitted if the whole page is reinitialized
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* (XLOG_HEAP_INIT_PAGE).
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*
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* In block 0's data portion, there is an xl_multi_insert_tuple struct,
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* followed by the tuple data for each tuple. There is padding to align
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* each xl_multi_insert struct.
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*/
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typedef struct xl_heap_multi_insert
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{
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uint8 flags;
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uint16 ntuples;
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OffsetNumber offsets[FLEXIBLE_ARRAY_MEMBER];
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} xl_heap_multi_insert;
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#define SizeOfHeapMultiInsert offsetof(xl_heap_multi_insert, offsets)
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typedef struct xl_multi_insert_tuple
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{
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uint16 datalen; /* size of tuple data that follows */
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uint16 t_infomask2;
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uint16 t_infomask;
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uint8 t_hoff;
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/* TUPLE DATA FOLLOWS AT END OF STRUCT */
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} xl_multi_insert_tuple;
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#define SizeOfMultiInsertTuple (offsetof(xl_multi_insert_tuple, t_hoff) + sizeof(uint8))
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/*
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* This is what we need to know about update|hot_update
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*
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* Backup blk 0: new page
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*
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* If XLOG_HEAP_PREFIX_FROM_OLD or XLOG_HEAP_SUFFIX_FROM_OLD flags are set,
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* the prefix and/or suffix come first, as one or two uint16s.
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*
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* After that, xl_heap_header and new tuple data follow. The new tuple
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* data doesn't include the prefix and suffix, which are copied from the
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* old tuple on replay.
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*
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* If HEAP_CONTAINS_NEW_TUPLE_DATA flag is given, the tuple data is
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* included even if a full-page image was taken.
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*
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* Backup blk 1: old page, if different. (no data, just a reference to the blk)
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*/
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typedef struct xl_heap_update
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{
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TransactionId old_xmax; /* xmax of the old tuple */
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OffsetNumber old_offnum; /* old tuple's offset */
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uint8 old_infobits_set; /* infomask bits to set on old tuple */
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uint8 flags;
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TransactionId new_xmax; /* xmax of the new tuple */
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OffsetNumber new_offnum; /* new tuple's offset */
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/*
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* If XLOG_HEAP_CONTAINS_OLD_TUPLE or XLOG_HEAP_CONTAINS_OLD_KEY flags are
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* set, a xl_heap_header struct and tuple data for the old tuple follows.
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*/
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} xl_heap_update;
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#define SizeOfHeapUpdate (offsetof(xl_heap_update, new_offnum) + sizeof(OffsetNumber))
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/*
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* This is what we need to know about vacuum page cleanup/redirect
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*
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* The array of OffsetNumbers following the fixed part of the record contains:
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* * for each redirected item: the item offset, then the offset redirected to
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* * for each now-dead item: the item offset
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* * for each now-unused item: the item offset
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* The total number of OffsetNumbers is therefore 2*nredirected+ndead+nunused.
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* Note that nunused is not explicitly stored, but may be found by reference
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* to the total record length.
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*/
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typedef struct xl_heap_clean
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{
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TransactionId latestRemovedXid;
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uint16 nredirected;
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uint16 ndead;
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/* OFFSET NUMBERS are in the block reference 0 */
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} xl_heap_clean;
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#define SizeOfHeapClean (offsetof(xl_heap_clean, ndead) + sizeof(uint16))
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/*
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* Cleanup_info is required in some cases during a lazy VACUUM.
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* Used for reporting the results of HeapTupleHeaderAdvanceLatestRemovedXid()
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* see vacuumlazy.c for full explanation
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*/
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typedef struct xl_heap_cleanup_info
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{
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RelFileNode node;
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TransactionId latestRemovedXid;
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} xl_heap_cleanup_info;
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#define SizeOfHeapCleanupInfo (sizeof(xl_heap_cleanup_info))
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/* flags for infobits_set */
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#define XLHL_XMAX_IS_MULTI 0x01
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#define XLHL_XMAX_LOCK_ONLY 0x02
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#define XLHL_XMAX_EXCL_LOCK 0x04
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#define XLHL_XMAX_KEYSHR_LOCK 0x08
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#define XLHL_KEYS_UPDATED 0x10
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/* This is what we need to know about lock */
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typedef struct xl_heap_lock
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{
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TransactionId locking_xid; /* might be a MultiXactId not xid */
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OffsetNumber offnum; /* locked tuple's offset on page */
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int8 infobits_set; /* infomask and infomask2 bits to set */
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} xl_heap_lock;
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#define SizeOfHeapLock (offsetof(xl_heap_lock, infobits_set) + sizeof(int8))
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/* This is what we need to know about locking an updated version of a row */
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typedef struct xl_heap_lock_updated
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{
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TransactionId xmax;
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OffsetNumber offnum;
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uint8 infobits_set;
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} xl_heap_lock_updated;
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#define SizeOfHeapLockUpdated (offsetof(xl_heap_lock_updated, infobits_set) + sizeof(uint8))
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/* This is what we need to know about confirmation of speculative insertion */
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typedef struct xl_heap_confirm
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{
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OffsetNumber offnum; /* confirmed tuple's offset on page */
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} xl_heap_confirm;
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#define SizeOfHeapConfirm (offsetof(xl_heap_confirm, offnum) + sizeof(OffsetNumber))
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/* This is what we need to know about in-place update */
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typedef struct xl_heap_inplace
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{
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OffsetNumber offnum; /* updated tuple's offset on page */
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/* TUPLE DATA FOLLOWS AT END OF STRUCT */
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} xl_heap_inplace;
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#define SizeOfHeapInplace (offsetof(xl_heap_inplace, offnum) + sizeof(OffsetNumber))
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/*
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* This struct represents a 'freeze plan', which is what we need to know about
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* a single tuple being frozen during vacuum.
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*/
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/* 0x01 was XLH_FREEZE_XMIN */
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#define XLH_FREEZE_XVAC 0x02
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#define XLH_INVALID_XVAC 0x04
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typedef struct xl_heap_freeze_tuple
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{
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TransactionId xmax;
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OffsetNumber offset;
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uint16 t_infomask2;
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uint16 t_infomask;
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uint8 frzflags;
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} xl_heap_freeze_tuple;
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/*
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* This is what we need to know about a block being frozen during vacuum
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*
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* Backup block 0's data contains an array of xl_heap_freeze_tuple structs,
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* one for each tuple.
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*/
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typedef struct xl_heap_freeze_page
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{
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TransactionId cutoff_xid;
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uint16 ntuples;
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} xl_heap_freeze_page;
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#define SizeOfHeapFreezePage (offsetof(xl_heap_freeze_page, ntuples) + sizeof(uint16))
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/*
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* This is what we need to know about setting a visibility map bit
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*
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* Backup blk 0: visibility map buffer
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* Backup blk 1: heap buffer
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*/
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typedef struct xl_heap_visible
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{
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TransactionId cutoff_xid;
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} xl_heap_visible;
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#define SizeOfHeapVisible (offsetof(xl_heap_visible, cutoff_xid) + sizeof(TransactionId))
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typedef struct xl_heap_new_cid
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{
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/*
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* store toplevel xid so we don't have to merge cids from different
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* transactions
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*/
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TransactionId top_xid;
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CommandId cmin;
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CommandId cmax;
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/*
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* don't really need the combocid since we have the actual values right in
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* this struct, but the padding makes it free and its useful for
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* debugging.
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*/
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CommandId combocid;
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/*
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* Store the relfilenode/ctid pair to facilitate lookups.
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*/
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RelFileNode target_node;
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ItemPointerData target_tid;
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} xl_heap_new_cid;
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#define SizeOfHeapNewCid (offsetof(xl_heap_new_cid, target_tid) + sizeof(ItemPointerData))
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/* logical rewrite xlog record header */
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typedef struct xl_heap_rewrite_mapping
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{
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TransactionId mapped_xid; /* xid that might need to see the row */
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Oid mapped_db; /* DbOid or InvalidOid for shared rels */
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Oid mapped_rel; /* Oid of the mapped relation */
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off_t offset; /* How far have we written so far */
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uint32 num_mappings; /* Number of in-memory mappings */
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XLogRecPtr start_lsn; /* Insert LSN at begin of rewrite */
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} xl_heap_rewrite_mapping;
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extern void HeapTupleHeaderAdvanceLatestRemovedXid(HeapTupleHeader tuple,
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TransactionId *latestRemovedXid);
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extern void heap_redo(XLogReaderState *record);
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extern void heap_desc(StringInfo buf, XLogReaderState *record);
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extern const char *heap_identify(uint8 info);
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extern void heap2_redo(XLogReaderState *record);
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extern void heap2_desc(StringInfo buf, XLogReaderState *record);
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extern const char *heap2_identify(uint8 info);
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extern void heap_xlog_logical_rewrite(XLogReaderState *r);
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extern XLogRecPtr log_heap_cleanup_info(RelFileNode rnode,
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TransactionId latestRemovedXid);
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extern XLogRecPtr log_heap_clean(Relation reln, Buffer buffer,
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OffsetNumber *redirected, int nredirected,
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OffsetNumber *nowdead, int ndead,
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OffsetNumber *nowunused, int nunused,
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TransactionId latestRemovedXid);
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extern XLogRecPtr log_heap_freeze(Relation reln, Buffer buffer,
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TransactionId cutoff_xid, xl_heap_freeze_tuple *tuples,
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int ntuples);
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extern bool heap_prepare_freeze_tuple(HeapTupleHeader tuple,
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TransactionId cutoff_xid,
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TransactionId cutoff_multi,
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xl_heap_freeze_tuple *frz);
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extern void heap_execute_freeze_tuple(HeapTupleHeader tuple,
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xl_heap_freeze_tuple *xlrec_tp);
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extern XLogRecPtr log_heap_visible(RelFileNode rnode, Buffer heap_buffer,
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Buffer vm_buffer, TransactionId cutoff_xid);
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#endif /* HEAPAM_XLOG_H */
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