vacuumlazy.c

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/*-------------------------------------------------------------------------
 *
 * vacuumlazy.c
 *    Concurrent ("lazy") vacuuming.
 *
 * The major space usage for vacuuming is storage for the array of dead TIDs
 * that are to be removed from indexes.  We want to ensure we can vacuum even
 * the very largest relations with finite memory space usage.  To do that, we
 * set upper bounds on the number of TIDs we can keep track of at once.
 *
 * We are willing to use at most maintenance_work_mem (or perhaps
 * autovacuum_work_mem) memory space to keep track of dead TIDs.  We initially
 * allocate an array of TIDs of that size, with an upper limit that depends on
 * table size (this limit ensures we don't allocate a huge area uselessly for
 * vacuuming small tables).  If the array threatens to overflow, we must call
 * lazy_vacuum to vacuum indexes (and to vacuum the pages that we've pruned).
 * This frees up the memory space dedicated to storing dead TIDs.
 *
 * In practice VACUUM will often complete its initial pass over the target
 * heap relation without ever running out of space to store TIDs.  This means
 * that there only needs to be one call to lazy_vacuum, after the initial pass
 * completes.
 *
 * Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *    src/backend/access/heap/vacuumlazy.c
 *
 *-------------------------------------------------------------------------
 */
#include "postgres.h"
 
#include <math.h>
 
#include "access/amapi.h"
#include "access/genam.h"
#include "access/heapam.h"
#include "access/heapam_xlog.h"
#include "access/htup_details.h"
#include "access/multixact.h"
#include "access/transam.h"
#include "access/visibilitymap.h"
#include "access/xact.h"
#include "access/xlog.h"
#include "access/xloginsert.h"
#include "catalog/index.h"
#include "catalog/storage.h"
#include "commands/dbcommands.h"
#include "commands/progress.h"
#include "commands/vacuum.h"
#include "executor/instrument.h"
#include "miscadmin.h"
#include "optimizer/paths.h"
#include "pgstat.h"
#include "portability/instr_time.h"
#include "postmaster/autovacuum.h"
#include "storage/bufmgr.h"
#include "storage/freespace.h"
#include "storage/lmgr.h"
#include "tcop/tcopprot.h"
#include "utils/lsyscache.h"
#include "utils/memutils.h"
#include "utils/pg_rusage.h"
#include "utils/timestamp.h"
 
 
/*
 * Space/time tradeoff parameters: do these need to be user-tunable?
 *
 * To consider truncating the relation, we want there to be at least
 * REL_TRUNCATE_MINIMUM or (relsize / REL_TRUNCATE_FRACTION) (whichever
 * is less) potentially-freeable pages.
 */
#define REL_TRUNCATE_MINIMUM    1000
#define REL_TRUNCATE_FRACTION   16
 
/*
 * Timing parameters for truncate locking heuristics.
 *
 * These were not exposed as user tunable GUC values because it didn't seem
 * that the potential for improvement was great enough to merit the cost of
 * supporting them.
 */
#define VACUUM_TRUNCATE_LOCK_CHECK_INTERVAL     20  /* ms */
#define VACUUM_TRUNCATE_LOCK_WAIT_INTERVAL      50  /* ms */
#define VACUUM_TRUNCATE_LOCK_TIMEOUT            5000    /* ms */
 
/*
 * Threshold that controls whether we bypass index vacuuming and heap
 * vacuuming as an optimization
 */
#define BYPASS_THRESHOLD_PAGES  0.02    /* i.e. 2% of rel_pages */
 
/*
 * Perform a failsafe check each time we scan another 4GB of pages.
 * (Note that this is deliberately kept to a power-of-two, usually 2^19.)
 */
#define FAILSAFE_EVERY_PAGES \
    ((BlockNumber) (((uint64) 4 * 1024 * 1024 * 1024) / BLCKSZ))
 
/*
 * When a table has no indexes, vacuum the FSM after every 8GB, approximately
 * (it won't be exact because we only vacuum FSM after processing a heap page
 * that has some removable tuples).  When there are indexes, this is ignored,
 * and we vacuum FSM after each index/heap cleaning pass.
 */
#define VACUUM_FSM_EVERY_PAGES \
    ((BlockNumber) (((uint64) 8 * 1024 * 1024 * 1024) / BLCKSZ))
 
/*
 * Before we consider skipping a page that's marked as clean in
 * visibility map, we must've seen at least this many clean pages.
 */
#define SKIP_PAGES_THRESHOLD    ((BlockNumber) 32)
 
/*
 * Size of the prefetch window for lazy vacuum backwards truncation scan.
 * Needs to be a power of 2.
 */
#define PREFETCH_SIZE           ((BlockNumber) 32)
 
/*
 * Macro to check if we are in a parallel vacuum.  If true, we are in the
 * parallel mode and the DSM segment is initialized.
 */
#define ParallelVacuumIsActive(vacrel) ((vacrel)->pvs != NULL)
 
/* Phases of vacuum during which we report error context. */
typedef enum
{
    VACUUM_ERRCB_PHASE_UNKNOWN,
    VACUUM_ERRCB_PHASE_SCAN_HEAP,
    VACUUM_ERRCB_PHASE_VACUUM_INDEX,
    VACUUM_ERRCB_PHASE_VACUUM_HEAP,
    VACUUM_ERRCB_PHASE_INDEX_CLEANUP,
    VACUUM_ERRCB_PHASE_TRUNCATE,
} VacErrPhase;
 
typedef struct LVRelState
{
    /* Target heap relation and its indexes */
    Relation    rel;
    Relation   *indrels;
    int         nindexes;
 
    /* Buffer access strategy and parallel vacuum state */
    BufferAccessStrategy bstrategy;
    ParallelVacuumState *pvs;
 
    /* Aggressive VACUUM? (must set relfrozenxid >= FreezeLimit) */
    bool        aggressive;
    /* Use visibility map to skip? (disabled by DISABLE_PAGE_SKIPPING) */
    bool        skipwithvm;
    /* Consider index vacuuming bypass optimization? */
    bool        consider_bypass_optimization;
 
    /* Doing index vacuuming, index cleanup, rel truncation? */
    bool        do_index_vacuuming;
    bool        do_index_cleanup;
    bool        do_rel_truncate;
 
    /* VACUUM operation's cutoffs for freezing and pruning */
    struct VacuumCutoffs cutoffs;
    GlobalVisState *vistest;
    /* Tracks oldest extant XID/MXID for setting relfrozenxid/relminmxid */
    TransactionId NewRelfrozenXid;
    MultiXactId NewRelminMxid;
    bool        skippedallvis;
 
    /* Error reporting state */
    char       *dbname;
    char       *relnamespace;
    char       *relname;
    char       *indname;        /* Current index name */
    BlockNumber blkno;          /* used only for heap operations */
    OffsetNumber offnum;        /* used only for heap operations */
    VacErrPhase phase;
    bool        verbose;        /* VACUUM VERBOSE? */
 
    /*
     * dead_items stores TIDs whose index tuples are deleted by index
     * vacuuming. Each TID points to an LP_DEAD line pointer from a heap page
     * that has been processed by lazy_scan_prune.  Also needed by
     * lazy_vacuum_heap_rel, which marks the same LP_DEAD line pointers as
     * LP_UNUSED during second heap pass.
     */
    VacDeadItems *dead_items;   /* TIDs whose index tuples we'll delete */
    BlockNumber rel_pages;      /* total number of pages */
    BlockNumber scanned_pages;  /* # pages examined (not skipped via VM) */
    BlockNumber removed_pages;  /* # pages removed by relation truncation */
    BlockNumber frozen_pages;   /* # pages with newly frozen tuples */
    BlockNumber lpdead_item_pages;  /* # pages with LP_DEAD items */
    BlockNumber missed_dead_pages;  /* # pages with missed dead tuples */
    BlockNumber nonempty_pages; /* actually, last nonempty page + 1 */
 
    /* Statistics output by us, for table */
    double      new_rel_tuples; /* new estimated total # of tuples */
    double      new_live_tuples;    /* new estimated total # of live tuples */
    /* Statistics output by index AMs */
    IndexBulkDeleteResult **indstats;
 
    /* Instrumentation counters */
    int         num_index_scans;
    /* Counters that follow are only for scanned_pages */
    int64       tuples_deleted; /* # deleted from table */
    int64       tuples_frozen;  /* # newly frozen */
    int64       lpdead_items;   /* # deleted from indexes */
    int64       live_tuples;    /* # live tuples remaining */
    int64       recently_dead_tuples;   /* # dead, but not yet removable */
    int64       missed_dead_tuples; /* # removable, but not removed */
} LVRelState;
 
/*
 * State returned by lazy_scan_prune()
 */
typedef struct LVPagePruneState
{
    bool        hastup;         /* Page prevents rel truncation? */
    bool        has_lpdead_items;   /* includes existing LP_DEAD items */
 
    /*
     * State describes the proper VM bit states to set for the page following
     * pruning and freezing.  all_visible implies !has_lpdead_items, but don't
     * trust all_frozen result unless all_visible is also set to true.
     */
    bool        all_visible;    /* Every item visible to all? */
    bool        all_frozen;     /* provided all_visible is also true */
    TransactionId visibility_cutoff_xid;    /* For recovery conflicts */
} LVPagePruneState;
 
/* Struct for saving and restoring vacuum error information. */
typedef struct LVSavedErrInfo
{
    BlockNumber blkno;
    OffsetNumber offnum;
    VacErrPhase phase;
} LVSavedErrInfo;
 
 
/* non-export function prototypes */
static void lazy_scan_heap(LVRelState *vacrel);
static BlockNumber lazy_scan_skip(LVRelState *vacrel, Buffer *vmbuffer,
                                  BlockNumber next_block,
                                  bool *next_unskippable_allvis,
                                  bool *skipping_current_range);
static bool lazy_scan_new_or_empty(LVRelState *vacrel, Buffer buf,
                                   BlockNumber blkno, Page page,
                                   bool sharelock, Buffer vmbuffer);
static void lazy_scan_prune(LVRelState *vacrel, Buffer buf,
                            BlockNumber blkno, Page page,
                            LVPagePruneState *prunestate);
static bool lazy_scan_noprune(LVRelState *vacrel, Buffer buf,
                              BlockNumber blkno, Page page,
                              bool *hastup, bool *recordfreespace);
static void lazy_vacuum(LVRelState *vacrel);
static bool lazy_vacuum_all_indexes(LVRelState *vacrel);
static void lazy_vacuum_heap_rel(LVRelState *vacrel);
static int  lazy_vacuum_heap_page(LVRelState *vacrel, BlockNumber blkno,
                                  Buffer buffer, int index, Buffer vmbuffer);
static bool lazy_check_wraparound_failsafe(LVRelState *vacrel);
static void lazy_cleanup_all_indexes(LVRelState *vacrel);
static IndexBulkDeleteResult *lazy_vacuum_one_index(Relation indrel,
                                                    IndexBulkDeleteResult *istat,
                                                    double reltuples,
                                                    LVRelState *vacrel);
static IndexBulkDeleteResult *lazy_cleanup_one_index(Relation indrel,
                                                     IndexBulkDeleteResult *istat,
                                                     double reltuples,
                                                     bool estimated_count,
                                                     LVRelState *vacrel);
static bool should_attempt_truncation(LVRelState *vacrel);
static void lazy_truncate_heap(LVRelState *vacrel);
static BlockNumber count_nondeletable_pages(LVRelState *vacrel,
                                            bool *lock_waiter_detected);
static void dead_items_alloc(LVRelState *vacrel, int nworkers);
static void dead_items_cleanup(LVRelState *vacrel);
static bool heap_page_is_all_visible(LVRelState *vacrel, Buffer buf,
                                     TransactionId *visibility_cutoff_xid, bool *all_frozen);
static void update_relstats_all_indexes(LVRelState *vacrel);
static void vacuum_error_callback(void *arg);
static void update_vacuum_error_info(LVRelState *vacrel,
                                     LVSavedErrInfo *saved_vacrel,
                                     int phase, BlockNumber blkno,
                                     OffsetNumber offnum);
static void restore_vacuum_error_info(LVRelState *vacrel,
                                      const LVSavedErrInfo *saved_vacrel);
 
 
/*
 *  heap_vacuum_rel() -- perform VACUUM for one heap relation
 *
 *      This routine sets things up for and then calls lazy_scan_heap, where
 *      almost all work actually takes place.  Finalizes everything after call
 *      returns by managing relation truncation and updating rel's pg_class
 *      entry. (Also updates pg_class entries for any indexes that need it.)
 *
 *      At entry, we have already established a transaction and opened
 *      and locked the relation.
 */
void
heap_vacuum_rel(Relation rel, VacuumParams *params,
                BufferAccessStrategy bstrategy)
{
    LVRelState *vacrel;
    bool        verbose,
                instrument,
                skipwithvm,
                frozenxid_updated,
                minmulti_updated;
    BlockNumber orig_rel_pages,
                new_rel_pages,
                new_rel_allvisible;
    PGRUsage    ru0;
    TimestampTz starttime = 0;
    PgStat_Counter startreadtime = 0,
                startwritetime = 0;
    WalUsage    startwalusage = pgWalUsage;
    int64       StartPageHit = VacuumPageHit,
                StartPageMiss = VacuumPageMiss,
                StartPageDirty = VacuumPageDirty;
    ErrorContextCallback errcallback;
    char      **indnames = NULL;
 
    verbose = (params->options & VACOPT_VERBOSE) != 0;
    instrument = (verbose || (IsAutoVacuumWorkerProcess() &&
                              params->log_min_duration >= 0));
    if (instrument)
    {
        pg_rusage_init(&ru0);
        starttime = GetCurrentTimestamp();
        if (track_io_timing)
        {
            startreadtime = pgStatBlockReadTime;
            startwritetime = pgStatBlockWriteTime;
        }
    }
 
    pgstat_progress_start_command(PROGRESS_COMMAND_VACUUM,
                                  RelationGetRelid(rel));
 
    /*
     * Setup error traceback support for ereport() first.  The idea is to set
     * up an error context callback to display additional information on any
     * error during a vacuum.  During different phases of vacuum, we update
     * the state so that the error context callback always display current
     * information.
     *
     * Copy the names of heap rel into local memory for error reporting
     * purposes, too.  It isn't always safe to assume that we can get the name
     * of each rel.  It's convenient for code in lazy_scan_heap to always use
     * these temp copies.
     */
    vacrel = (LVRelState *) palloc0(sizeof(LVRelState));
    vacrel->dbname = get_database_name(MyDatabaseId);
    vacrel->relnamespace = get_namespace_name(RelationGetNamespace(rel));
    vacrel->relname = pstrdup(RelationGetRelationName(rel));
    vacrel->indname = NULL;
    vacrel->phase = VACUUM_ERRCB_PHASE_UNKNOWN;
    vacrel->verbose = verbose;
    errcallback.callback = vacuum_error_callback;
    errcallback.arg = vacrel;
    errcallback.previous = error_context_stack;
    error_context_stack = &errcallback;
 
    /* Set up high level stuff about rel and its indexes */
    vacrel->rel = rel;
    vac_open_indexes(vacrel->rel, RowExclusiveLock, &vacrel->nindexes,
                     &vacrel->indrels);
    vacrel->bstrategy = bstrategy;
    if (instrument && vacrel->nindexes > 0)
    {
        /* Copy index names used by instrumentation (not error reporting) */
        indnames = palloc(sizeof(char *) * vacrel->nindexes);
        for (int i = 0; i < vacrel->nindexes; i++)
            indnames[i] = pstrdup(RelationGetRelationName(vacrel->indrels[i]));
    }
 
    /*
     * The index_cleanup param either disables index vacuuming and cleanup or
     * forces it to go ahead when we would otherwise apply the index bypass
     * optimization.  The default is 'auto', which leaves the final decision
     * up to lazy_vacuum().
     *
     * The truncate param allows user to avoid attempting relation truncation,
     * though it can't force truncation to happen.
     */
    Assert(params->index_cleanup != VACOPTVALUE_UNSPECIFIED);
    Assert(params->truncate != VACOPTVALUE_UNSPECIFIED &&
           params->truncate != VACOPTVALUE_AUTO);
 
    /*
     * While VacuumFailSafeActive is reset to false before calling this, we
     * still need to reset it here due to recursive calls.
     */
    VacuumFailsafeActive = false;
    vacrel->consider_bypass_optimization = true;
    vacrel->do_index_vacuuming = true;
    vacrel->do_index_cleanup = true;
    vacrel->do_rel_truncate = (params->truncate != VACOPTVALUE_DISABLED);
    if (params->index_cleanup == VACOPTVALUE_DISABLED)
    {
        /* Force disable index vacuuming up-front */
        vacrel->do_index_vacuuming = false;
        vacrel->do_index_cleanup = false;
    }
    else if (params->index_cleanup == VACOPTVALUE_ENABLED)
    {
        /* Force index vacuuming.  Note that failsafe can still bypass. */
        vacrel->consider_bypass_optimization = false;
    }
    else
    {
        /* Default/auto, make all decisions dynamically */
        Assert(params->index_cleanup == VACOPTVALUE_AUTO);
    }
 
    /* Initialize page counters explicitly (be tidy) */
    vacrel->scanned_pages = 0;
    vacrel->removed_pages = 0;
    vacrel->frozen_pages = 0;
    vacrel->lpdead_item_pages = 0;
    vacrel->missed_dead_pages = 0;
    vacrel->nonempty_pages = 0;
    /* dead_items_alloc allocates vacrel->dead_items later on */
 
    /* Allocate/initialize output statistics state */
    vacrel->new_rel_tuples = 0;
    vacrel->new_live_tuples = 0;
    vacrel->indstats = (IndexBulkDeleteResult **)
        palloc0(vacrel->nindexes * sizeof(IndexBulkDeleteResult *));
 
    /* Initialize remaining counters (be tidy) */
    vacrel->num_index_scans = 0;
    vacrel->tuples_deleted = 0;
    vacrel->tuples_frozen = 0;
    vacrel->lpdead_items = 0;
    vacrel->live_tuples = 0;
    vacrel->recently_dead_tuples = 0;
    vacrel->missed_dead_tuples = 0;
 
    /*
     * Get cutoffs that determine which deleted tuples are considered DEAD,
     * not just RECENTLY_DEAD, and which XIDs/MXIDs to freeze.  Then determine
     * the extent of the blocks that we'll scan in lazy_scan_heap.  It has to
     * happen in this order to ensure that the OldestXmin cutoff field works
     * as an upper bound on the XIDs stored in the pages we'll actually scan
     * (NewRelfrozenXid tracking must never be allowed to miss unfrozen XIDs).
     *
     * Next acquire vistest, a related cutoff that's used in heap_page_prune.
     * We expect vistest will always make heap_page_prune remove any deleted
     * tuple whose xmax is < OldestXmin.  lazy_scan_prune must never become
     * confused about whether a tuple should be frozen or removed.  (In the
     * future we might want to teach lazy_scan_prune to recompute vistest from
     * time to time, to increase the number of dead tuples it can prune away.)
     */
    vacrel->aggressive = vacuum_get_cutoffs(rel, params, &vacrel->cutoffs);
    vacrel->rel_pages = orig_rel_pages = RelationGetNumberOfBlocks(rel);
    vacrel->vistest = GlobalVisTestFor(rel);
    /* Initialize state used to track oldest extant XID/MXID */
    vacrel->NewRelfrozenXid = vacrel->cutoffs.OldestXmin;
    vacrel->NewRelminMxid = vacrel->cutoffs.OldestMxact;
    vacrel->skippedallvis = false;
    skipwithvm = true;
    if (params->options & VACOPT_DISABLE_PAGE_SKIPPING)
    {
        /*
         * Force aggressive mode, and disable skipping blocks using the
         * visibility map (even those set all-frozen)
         */
        vacrel->aggressive = true;
        skipwithvm = false;
    }
 
    vacrel->skipwithvm = skipwithvm;
 
    if (verbose)
    {
        if (vacrel->aggressive)
            ereport(INFO,
                    (errmsg("aggressively vacuuming \"%s.%s.%s\"",
                            vacrel->dbname, vacrel->relnamespace,
                            vacrel->relname)));
        else
            ereport(INFO,
                    (errmsg("vacuuming \"%s.%s.%s\"",
                            vacrel->dbname, vacrel->relnamespace,
                            vacrel->relname)));
    }
 
    /*
     * Allocate dead_items array memory using dead_items_alloc.  This handles
     * parallel VACUUM initialization as part of allocating shared memory
     * space used for dead_items.  (But do a failsafe precheck first, to
     * ensure that parallel VACUUM won't be attempted at all when relfrozenxid
     * is already dangerously old.)
     */
    lazy_check_wraparound_failsafe(vacrel);
    dead_items_alloc(vacrel, params->nworkers);
 
    /*
     * Call lazy_scan_heap to perform all required heap pruning, index
     * vacuuming, and heap vacuuming (plus related processing)
     */
    lazy_scan_heap(vacrel);
 
    /*
     * Free resources managed by dead_items_alloc.  This ends parallel mode in
     * passing when necessary.
     */
    dead_items_cleanup(vacrel);
    Assert(!IsInParallelMode());
 
    /*
     * Update pg_class entries for each of rel's indexes where appropriate.
     *
     * Unlike the later update to rel's pg_class entry, this is not critical.
     * Maintains relpages/reltuples statistics used by the planner only.
     */
    if (vacrel->do_index_cleanup)
        update_relstats_all_indexes(vacrel);
 
    /* Done with rel's indexes */
    vac_close_indexes(vacrel->nindexes, vacrel->indrels, NoLock);
 
    /* Optionally truncate rel */
    if (should_attempt_truncation(vacrel))
        lazy_truncate_heap(vacrel);
 
    /* Pop the error context stack */
    error_context_stack = errcallback.previous;
 
    /* Report that we are now doing final cleanup */
    pgstat_progress_update_param(PROGRESS_VACUUM_PHASE,
                                 PROGRESS_VACUUM_PHASE_FINAL_CLEANUP);
 
    /*
     * Prepare to update rel's pg_class entry.
     *
     * Aggressive VACUUMs must always be able to advance relfrozenxid to a
     * value >= FreezeLimit, and relminmxid to a value >= MultiXactCutoff.
     * Non-aggressive VACUUMs may advance them by any amount, or not at all.
     */
    Assert(vacrel->NewRelfrozenXid == vacrel->cutoffs.OldestXmin ||
           TransactionIdPrecedesOrEquals(vacrel->aggressive ? vacrel->cutoffs.FreezeLimit :
                                         vacrel->cutoffs.relfrozenxid,
                                         vacrel->NewRelfrozenXid));
    Assert(vacrel->NewRelminMxid == vacrel->cutoffs.OldestMxact ||
           MultiXactIdPrecedesOrEquals(vacrel->aggressive ? vacrel->cutoffs.MultiXactCutoff :
                                       vacrel->cutoffs.relminmxid,
                                       vacrel->NewRelminMxid));
    if (vacrel->skippedallvis)
    {
        /*
         * Must keep original relfrozenxid in a non-aggressive VACUUM that
         * chose to skip an all-visible page range.  The state that tracks new
         * values will have missed unfrozen XIDs from the pages we skipped.
         */
        Assert(!vacrel->aggressive);
        vacrel->NewRelfrozenXid = InvalidTransactionId;
        vacrel->NewRelminMxid = InvalidMultiXactId;
    }
 
    /*
     * For safety, clamp relallvisible to be not more than what we're setting
     * pg_class.relpages to
     */
    new_rel_pages = vacrel->rel_pages;  /* After possible rel truncation */
    visibilitymap_count(rel, &new_rel_allvisible, NULL);
    if (new_rel_allvisible > new_rel_pages)
        new_rel_allvisible = new_rel_pages;
 
    /*
     * Now actually update rel's pg_class entry.
     *
     * In principle new_live_tuples could be -1 indicating that we (still)
     * don't know the tuple count.  In practice that can't happen, since we
     * scan every page that isn't skipped using the visibility map.
     */
    vac_update_relstats(rel, new_rel_pages, vacrel->new_live_tuples,
                        new_rel_allvisible, vacrel->nindexes > 0,
                        vacrel->NewRelfrozenXid, vacrel->NewRelminMxid,
                        &frozenxid_updated, &minmulti_updated, false);
 
    /*
     * Report results to the cumulative stats system, too.
     *
     * Deliberately avoid telling the stats system about LP_DEAD items that
     * remain in the table due to VACUUM bypassing index and heap vacuuming.
     * ANALYZE will consider the remaining LP_DEAD items to be dead "tuples".
     * It seems like a good idea to err on the side of not vacuuming again too
     * soon in cases where the failsafe prevented significant amounts of heap
     * vacuuming.
     */
    pgstat_report_vacuum(RelationGetRelid(rel),
                         rel->rd_rel->relisshared,
                         Max(vacrel->new_live_tuples, 0),
                         vacrel->recently_dead_tuples +
                         vacrel->missed_dead_tuples);
    pgstat_progress_end_command();
 
    if (instrument)
    {
        TimestampTz endtime = GetCurrentTimestamp();
 
        if (verbose || params->log_min_duration == 0 ||
            TimestampDifferenceExceeds(starttime, endtime,
                                       params->log_min_duration))
        {
            long        secs_dur;
            int         usecs_dur;
            WalUsage    walusage;
            StringInfoData buf;
            char       *msgfmt;
            int32       diff;
            int64       PageHitOp = VacuumPageHit - StartPageHit,
                        PageMissOp = VacuumPageMiss - StartPageMiss,
                        PageDirtyOp = VacuumPageDirty - StartPageDirty;
            double      read_rate = 0,
                        write_rate = 0;
 
            TimestampDifference(starttime, endtime, &secs_dur, &usecs_dur);
            memset(&walusage, 0, sizeof(WalUsage));
            WalUsageAccumDiff(&walusage, &pgWalUsage, &startwalusage);
 
            initStringInfo(&buf);
            if (verbose)
            {
                /*
                 * Aggressiveness already reported earlier, in dedicated
                 * VACUUM VERBOSE ereport
                 */
                Assert(!params->is_wraparound);
                msgfmt = _("finished vacuuming \"%s.%s.%s\": index scans: %d\n");
            }
            else if (params->is_wraparound)
            {
                /*
                 * While it's possible for a VACUUM to be both is_wraparound
                 * and !aggressive, that's just a corner-case -- is_wraparound
                 * implies aggressive.  Produce distinct output for the corner
                 * case all the same, just in case.
                 */
                if (vacrel->aggressive)
                    msgfmt = _("automatic aggressive vacuum to prevent wraparound of table \"%s.%s.%s\": index scans: %d\n");
                else
                    msgfmt = _("automatic vacuum to prevent wraparound of table \"%s.%s.%s\": index scans: %d\n");
            }
            else
            {
                if (vacrel->aggressive)
                    msgfmt = _("automatic aggressive vacuum of table \"%s.%s.%s\": index scans: %d\n");
                else
                    msgfmt = _("automatic vacuum of table \"%s.%s.%s\": index scans: %d\n");
            }
            appendStringInfo(&buf, msgfmt,
                             vacrel->dbname,
                             vacrel->relnamespace,
                             vacrel->relname,
                             vacrel->num_index_scans);
            appendStringInfo(&buf, _("pages: %u removed, %u remain, %u scanned (%.2f%% of total)\n"),
                             vacrel->removed_pages,
                             new_rel_pages,
                             vacrel->scanned_pages,
                             orig_rel_pages == 0 ? 100.0 :
                             100.0 * vacrel->scanned_pages / orig_rel_pages);
            appendStringInfo(&buf,
                             _("tuples: %lld removed, %lld remain, %lld are dead but not yet removable\n"),
                             (long long) vacrel->tuples_deleted,
                             (long long) vacrel->new_rel_tuples,
                             (long long) vacrel->recently_dead_tuples);
            if (vacrel->missed_dead_tuples > 0)
                appendStringInfo(&buf,
                                 _("tuples missed: %lld dead from %u pages not removed due to cleanup lock contention\n"),
                                 (long long) vacrel->missed_dead_tuples,
                                 vacrel->missed_dead_pages);
            diff = (int32) (ReadNextTransactionId() -
                            vacrel->cutoffs.OldestXmin);
            appendStringInfo(&buf,
                             _("removable cutoff: %u, which was %d XIDs old when operation ended\n"),
                             vacrel->cutoffs.OldestXmin, diff);
            if (frozenxid_updated)
            {
                diff = (int32) (vacrel->NewRelfrozenXid -
                                vacrel->cutoffs.relfrozenxid);
                appendStringInfo(&buf,
                                 _("new relfrozenxid: %u, which is %d XIDs ahead of previous value\n"),
                                 vacrel->NewRelfrozenXid, diff);
            }
            if (minmulti_updated)
            {
                diff = (int32) (vacrel->NewRelminMxid -
                                vacrel->cutoffs.relminmxid);
                appendStringInfo(&buf,
                                 _("new relminmxid: %u, which is %d MXIDs ahead of previous value\n"),
                                 vacrel->NewRelminMxid, diff);
            }
            appendStringInfo(&buf, _("frozen: %u pages from table (%.2f%% of total) had %lld tuples frozen\n"),
                             vacrel->frozen_pages,
                             orig_rel_pages == 0 ? 100.0 :
                             100.0 * vacrel->frozen_pages / orig_rel_pages,
                             (long long) vacrel->tuples_frozen);
            if (vacrel->do_index_vacuuming)
            {
                if (vacrel->nindexes == 0 || vacrel->num_index_scans == 0)
                    appendStringInfoString(&buf, _("index scan not needed: "));
                else
                    appendStringInfoString(&buf, _("index scan needed: "));
 
                msgfmt = _("%u pages from table (%.2f%% of total) had %lld dead item identifiers removed\n");
            }
            else
            {
                if (!VacuumFailsafeActive)
                    appendStringInfoString(&buf, _("index scan bypassed: "));
                else
                    appendStringInfoString(&buf, _("index scan bypassed by failsafe: "));
 
                msgfmt = _("%u pages from table (%.2f%% of total) have %lld dead item identifiers\n");
            }
            appendStringInfo(&buf, msgfmt,
                             vacrel->lpdead_item_pages,
                             orig_rel_pages == 0 ? 100.0 :
                             100.0 * vacrel->lpdead_item_pages / orig_rel_pages,
                             (long long) vacrel->lpdead_items);
            for (int i = 0; i < vacrel->nindexes; i++)
            {
                IndexBulkDeleteResult *istat = vacrel->indstats[i];
 
                if (!istat)
                    continue;
 
                appendStringInfo(&buf,
                                 _("index \"%s\": pages: %u in total, %u newly deleted, %u currently deleted, %u reusable\n"),
                                 indnames[i],
                                 istat->num_pages,
                                 istat->pages_newly_deleted,
                                 istat->pages_deleted,
                                 istat->pages_free);
            }
            if (track_io_timing)
            {
                double      read_ms = (double) (pgStatBlockReadTime - startreadtime) / 1000;
                double      write_ms = (double) (pgStatBlockWriteTime - startwritetime) / 1000;
 
                appendStringInfo(&buf, _("I/O timings: read: %.3f ms, write: %.3f ms\n"),
                                 read_ms, write_ms);
            }
            if (secs_dur > 0 || usecs_dur > 0)
            {
                read_rate = (double) BLCKSZ * PageMissOp / (1024 * 1024) /
                    (secs_dur + usecs_dur / 1000000.0);
                write_rate = (double) BLCKSZ * PageDirtyOp / (1024 * 1024) /
                    (secs_dur + usecs_dur / 1000000.0);
            }
            appendStringInfo(&buf, _("avg read rate: %.3f MB/s, avg write rate: %.3f MB/s\n"),
                             read_rate, write_rate);
            appendStringInfo(&buf,
                             _("buffer usage: %lld hits, %lld misses, %lld dirtied\n"),
                             (long long) PageHitOp,
                             (long long) PageMissOp,
                             (long long) PageDirtyOp);
            appendStringInfo(&buf,
                             _("WAL usage: %lld records, %lld full page images, %llu bytes\n"),
                             (long long) walusage.wal_records,
                             (long long) walusage.wal_fpi,
                             (unsigned long long) walusage.wal_bytes);
            appendStringInfo(&buf, _("system usage: %s"), pg_rusage_show(&ru0));
 
            ereport(verbose ? INFO : LOG,
                    (errmsg_internal("%s", buf.data)));
            pfree(buf.data);
        }
    }
 
    /* Cleanup index statistics and index names */
    for (int i = 0; i < vacrel->nindexes; i++)
    {
        if (vacrel->indstats[i])
            pfree(vacrel->indstats[i]);
 
        if (instrument)
            pfree(indnames[i]);
    }
}
 
/*
 *  lazy_scan_heap() -- workhorse function for VACUUM
 *
 *      This routine prunes each page in the heap, and considers the need to
 *      freeze remaining tuples with storage (not including pages that can be
 *      skipped using the visibility map).  Also performs related maintenance
 *      of the FSM and visibility map.  These steps all take place during an
 *      initial pass over the target heap relation.
 *
 *      Also invokes lazy_vacuum_all_indexes to vacuum indexes, which largely
 *      consists of deleting index tuples that point to LP_DEAD items left in
 *      heap pages following pruning.  Earlier initial pass over the heap will
 *      have collected the TIDs whose index tuples need to be removed.
 *
 *      Finally, invokes lazy_vacuum_heap_rel to vacuum heap pages, which
 *      largely consists of marking LP_DEAD items (from collected TID array)
 *      as LP_UNUSED.  This has to happen in a second, final pass over the
 *      heap, to preserve a basic invariant that all index AMs rely on: no
 *      extant index tuple can ever be allowed to contain a TID that points to
 *      an LP_UNUSED line pointer in the heap.  We must disallow premature
 *      recycling of line pointers to avoid index scans that get confused
 *      about which TID points to which tuple immediately after recycling.
 *      (Actually, this isn't a concern when target heap relation happens to
 *      have no indexes, which allows us to safely apply the one-pass strategy
 *      as an optimization).
 *
 *      In practice we often have enough space to fit all TIDs, and so won't
 *      need to call lazy_vacuum more than once, after our initial pass over
 *      the heap has totally finished.  Otherwise things are slightly more
 *      complicated: our "initial pass" over the heap applies only to those
 *      pages that were pruned before we needed to call lazy_vacuum, and our
 *      "final pass" over the heap only vacuums these same heap pages.
 *      However, we process indexes in full every time lazy_vacuum is called,
 *      which makes index processing very inefficient when memory is in short
 *      supply.
 */
static void
lazy_scan_heap(LVRelState *vacrel)
{
    BlockNumber rel_pages = vacrel->rel_pages,
                blkno,
                next_unskippable_block,
                next_fsm_block_to_vacuum = 0;
    VacDeadItems *dead_items = vacrel->dead_items;
    Buffer      vmbuffer = InvalidBuffer;
    bool        next_unskippable_allvis,
                skipping_current_range;
    const int   initprog_index[] = {
        PROGRESS_VACUUM_PHASE,
        PROGRESS_VACUUM_TOTAL_HEAP_BLKS,
        PROGRESS_VACUUM_MAX_DEAD_TUPLES
    };
    int64       initprog_val[3];
 
    /* Report that we're scanning the heap, advertising total # of blocks */
    initprog_val[0] = PROGRESS_VACUUM_PHASE_SCAN_HEAP;
    initprog_val[1] = rel_pages;
    initprog_val[2] = dead_items->max_items;
    pgstat_progress_update_multi_param(3, initprog_index, initprog_val);
 
    /* Set up an initial range of skippable blocks using the visibility map */
    next_unskippable_block = lazy_scan_skip(vacrel, &vmbuffer, 0,
                                            &next_unskippable_allvis,
                                            &skipping_current_range);
    for (blkno = 0; blkno < rel_pages; blkno++)
    {
        Buffer      buf;
        Page        page;
        bool        all_visible_according_to_vm;
        LVPagePruneState prunestate;
 
        if (blkno == next_unskippable_block)
        {
            /*
             * Can't skip this page safely.  Must scan the page.  But
             * determine the next skippable range after the page first.
             */
            all_visible_according_to_vm = next_unskippable_allvis;
            next_unskippable_block = lazy_scan_skip(vacrel, &vmbuffer,
                                                    blkno + 1,
                                                    &next_unskippable_allvis,
                                                    &skipping_current_range);
 
            Assert(next_unskippable_block >= blkno + 1);
        }
        else
        {
            /* Last page always scanned (may need to set nonempty_pages) */
            Assert(blkno < rel_pages - 1);
 
            if (skipping_current_range)
                continue;
 
            /* Current range is too small to skip -- just scan the page */
            all_visible_according_to_vm = true;
        }
 
        vacrel->scanned_pages++;
 
        /* Report as block scanned, update error traceback information */
        pgstat_progress_update_param(PROGRESS_VACUUM_HEAP_BLKS_SCANNED, blkno);
        update_vacuum_error_info(vacrel, NULL, VACUUM_ERRCB_PHASE_SCAN_HEAP,
                                 blkno, InvalidOffsetNumber);
 
        vacuum_delay_point();
 
        /*
         * Regularly check if wraparound failsafe should trigger.
         *
         * There is a similar check inside lazy_vacuum_all_indexes(), but
         * relfrozenxid might start to look dangerously old before we reach
         * that point.  This check also provides failsafe coverage for the
         * one-pass strategy, and the two-pass strategy with the index_cleanup
         * param set to 'off'.
         */
        if (vacrel->scanned_pages % FAILSAFE_EVERY_PAGES == 0)
            lazy_check_wraparound_failsafe(vacrel);
 
        /*
         * Consider if we definitely have enough space to process TIDs on page
         * already.  If we are close to overrunning the available space for
         * dead_items TIDs, pause and do a cycle of vacuuming before we tackle
         * this page.
         */
        Assert(dead_items->max_items >= MaxHeapTuplesPerPage);
        if (dead_items->max_items - dead_items->num_items < MaxHeapTuplesPerPage)
        {
            /*
             * Before beginning index vacuuming, we release any pin we may
             * hold on the visibility map page.  This isn't necessary for
             * correctness, but we do it anyway to avoid holding the pin
             * across a lengthy, unrelated operation.
             */
            if (BufferIsValid(vmbuffer))
            {
                ReleaseBuffer(vmbuffer);
                vmbuffer = InvalidBuffer;
            }
 
            /* Perform a round of index and heap vacuuming */
            vacrel->consider_bypass_optimization = false;
            lazy_vacuum(vacrel);
 
            /*
             * Vacuum the Free Space Map to make newly-freed space visible on
             * upper-level FSM pages.  Note we have not yet processed blkno.
             */
            FreeSpaceMapVacuumRange(vacrel->rel, next_fsm_block_to_vacuum,
                                    blkno);
            next_fsm_block_to_vacuum = blkno;
 
            /* Report that we are once again scanning the heap */
            pgstat_progress_update_param(PROGRESS_VACUUM_PHASE,
                                         PROGRESS_VACUUM_PHASE_SCAN_HEAP);
        }
 
        /*
         * Pin the visibility map page in case we need to mark the page
         * all-visible.  In most cases this will be very cheap, because we'll
         * already have the correct page pinned anyway.
         */
        visibilitymap_pin(vacrel->rel, blkno, &vmbuffer);
 
        /*
         * We need a buffer cleanup lock to prune HOT chains and defragment
         * the page in lazy_scan_prune.  But when it's not possible to acquire
         * a cleanup lock right away, we may be able to settle for reduced
         * processing using lazy_scan_noprune.
         */
        buf = ReadBufferExtended(vacrel->rel, MAIN_FORKNUM, blkno, RBM_NORMAL,
                                 vacrel->bstrategy);
        page = BufferGetPage(buf);
        if (!ConditionalLockBufferForCleanup(buf))
        {
            bool        hastup,
                        recordfreespace;
 
            LockBuffer(buf, BUFFER_LOCK_SHARE);
 
            /* Check for new or empty pages before lazy_scan_noprune call */
            if (lazy_scan_new_or_empty(vacrel, buf, blkno, page, true,
                                       vmbuffer))
            {
                /* Processed as new/empty page (lock and pin released) */
                continue;
            }
 
            /* Collect LP_DEAD items in dead_items array, count tuples */
            if (lazy_scan_noprune(vacrel, buf, blkno, page, &hastup,
                                  &recordfreespace))
            {
                Size        freespace = 0;
 
                /*
                 * Processed page successfully (without cleanup lock) -- just
                 * need to perform rel truncation and FSM steps, much like the
                 * lazy_scan_prune case.  Don't bother trying to match its
                 * visibility map setting steps, though.
                 */
                if (hastup)
                    vacrel->nonempty_pages = blkno + 1;
                if (recordfreespace)
                    freespace = PageGetHeapFreeSpace(page);
                UnlockReleaseBuffer(buf);
                if (recordfreespace)
                    RecordPageWithFreeSpace(vacrel->rel, blkno, freespace);
                continue;
            }
 
            /*
             * lazy_scan_noprune could not do all required processing.  Wait
             * for a cleanup lock, and call lazy_scan_prune in the usual way.
             */
            Assert(vacrel->aggressive);
            LockBuffer(buf, BUFFER_LOCK_UNLOCK);
            LockBufferForCleanup(buf);
        }
 
        /* Check for new or empty pages before lazy_scan_prune call */
        if (lazy_scan_new_or_empty(vacrel, buf, blkno, page, false, vmbuffer))
        {
            /* Processed as new/empty page (lock and pin released) */
            continue;
        }
 
        /*
         * Prune, freeze, and count tuples.
         *
         * Accumulates details of remaining LP_DEAD line pointers on page in
         * dead_items array.  This includes LP_DEAD line pointers that we
         * pruned ourselves, as well as existing LP_DEAD line pointers that
         * were pruned some time earlier.  Also considers freezing XIDs in the
         * tuple headers of remaining items with storage.
         */
        lazy_scan_prune(vacrel, buf, blkno, page, &prunestate);
 
        Assert(!prunestate.all_visible || !prunestate.has_lpdead_items);
 
        /* Remember the location of the last page with nonremovable tuples */
        if (prunestate.hastup)
            vacrel->nonempty_pages = blkno + 1;
 
        if (vacrel->nindexes == 0)
        {
            /*
             * Consider the need to do page-at-a-time heap vacuuming when
             * using the one-pass strategy now.
             *
             * The one-pass strategy will never call lazy_vacuum().  The steps
             * performed here can be thought of as the one-pass equivalent of
             * a call to lazy_vacuum().
             */
            if (prunestate.has_lpdead_items)
            {
                Size        freespace;
 
                lazy_vacuum_heap_page(vacrel, blkno, buf, 0, vmbuffer);
 
                /* Forget the LP_DEAD items that we just vacuumed */
                dead_items->num_items = 0;
 
                /*
                 * Now perform FSM processing for blkno, and move on to next
                 * page.
                 *
                 * Our call to lazy_vacuum_heap_page() will have considered if
                 * it's possible to set all_visible/all_frozen independently
                 * of lazy_scan_prune().  Note that prunestate was invalidated
                 * by lazy_vacuum_heap_page() call.
                 */
                freespace = PageGetHeapFreeSpace(page);
 
                UnlockReleaseBuffer(buf);
                RecordPageWithFreeSpace(vacrel->rel, blkno, freespace);
 
                /*
                 * Periodically perform FSM vacuuming to make newly-freed
                 * space visible on upper FSM pages. FreeSpaceMapVacuumRange()
                 * vacuums the portion of the freespace map covering heap
                 * pages from start to end - 1. Include the block we just
                 * vacuumed by passing it blkno + 1. Overflow isn't an issue
                 * because MaxBlockNumber + 1 is InvalidBlockNumber which
                 * causes FreeSpaceMapVacuumRange() to vacuum freespace map
                 * pages covering the remainder of the relation.
                 */
                if (blkno - next_fsm_block_to_vacuum >= VACUUM_FSM_EVERY_PAGES)
                {
                    FreeSpaceMapVacuumRange(vacrel->rel, next_fsm_block_to_vacuum,
                                            blkno + 1);
                    next_fsm_block_to_vacuum = blkno + 1;
                }
 
                continue;
            }
 
            /*
             * There was no call to lazy_vacuum_heap_page() because pruning
             * didn't encounter/create any LP_DEAD items that needed to be
             * vacuumed.  Prune state has not been invalidated, so proceed
             * with prunestate-driven visibility map and FSM steps (just like
             * the two-pass strategy).
             */
            Assert(dead_items->num_items == 0);
        }
 
        /*
         * Handle setting visibility map bit based on information from the VM
         * (as of last lazy_scan_skip() call), and from prunestate
         */
        if (!all_visible_according_to_vm && prunestate.all_visible)
        {
            uint8       flags = VISIBILITYMAP_ALL_VISIBLE;
 
            if (prunestate.all_frozen)
            {
                Assert(!TransactionIdIsValid(prunestate.visibility_cutoff_xid));
                flags |= VISIBILITYMAP_ALL_FROZEN;
            }
 
            /*
             * It should never be the case that the visibility map page is set
             * while the page-level bit is clear, but the reverse is allowed
             * (if checksums are not enabled).  Regardless, set both bits so
             * that we get back in sync.
             *
             * NB: If the heap page is all-visible but the VM bit is not set,
             * we don't need to dirty the heap page.  However, if checksums
             * are enabled, we do need to make sure that the heap page is
             * dirtied before passing it to visibilitymap_set(), because it
             * may be logged.  Given that this situation should only happen in
             * rare cases after a crash, it is not worth optimizing.
             */
            PageSetAllVisible(page);
            MarkBufferDirty(buf);
            visibilitymap_set(vacrel->rel, blkno, buf, InvalidXLogRecPtr,
                              vmbuffer, prunestate.visibility_cutoff_xid,
                              flags);
        }
 
        /*
         * As of PostgreSQL 9.2, the visibility map bit should never be set if
         * the page-level bit is clear.  However, it's possible that the bit
         * got cleared after lazy_scan_skip() was called, so we must recheck
         * with buffer lock before concluding that the VM is corrupt.
         */
        else if (all_visible_according_to_vm && !PageIsAllVisible(page) &&
                 visibilitymap_get_status(vacrel->rel, blkno, &vmbuffer) != 0)
        {
            elog(WARNING, "page is not marked all-visible but visibility map bit is set in relation \"%s\" page %u",
                 vacrel->relname, blkno);
            visibilitymap_clear(vacrel->rel, blkno, vmbuffer,
                                VISIBILITYMAP_VALID_BITS);
        }
 
        /*
         * It's possible for the value returned by
         * GetOldestNonRemovableTransactionId() to move backwards, so it's not
         * wrong for us to see tuples that appear to not be visible to
         * everyone yet, while PD_ALL_VISIBLE is already set. The real safe
         * xmin value never moves backwards, but
         * GetOldestNonRemovableTransactionId() is conservative and sometimes
         * returns a value that's unnecessarily small, so if we see that
         * contradiction it just means that the tuples that we think are not
         * visible to everyone yet actually are, and the PD_ALL_VISIBLE flag
         * is correct.
         *
         * There should never be LP_DEAD items on a page with PD_ALL_VISIBLE
         * set, however.
         */
        else if (prunestate.has_lpdead_items && PageIsAllVisible(page))
        {
            elog(WARNING, "page containing LP_DEAD items is marked as all-visible in relation \"%s\" page %u",
                 vacrel->relname, blkno);
            PageClearAllVisible(page);
            MarkBufferDirty(buf);
            visibilitymap_clear(vacrel->rel, blkno, vmbuffer,
                                VISIBILITYMAP_VALID_BITS);
        }
 
        /*
         * If the all-visible page is all-frozen but not marked as such yet,
         * mark it as all-frozen.  Note that all_frozen is only valid if
         * all_visible is true, so we must check both prunestate fields.
         */
        else if (all_visible_according_to_vm && prunestate.all_visible &&
                 prunestate.all_frozen &&
                 !VM_ALL_FROZEN(vacrel->rel, blkno, &vmbuffer))
        {
            /*
             * Avoid relying on all_visible_according_to_vm as a proxy for the
             * page-level PD_ALL_VISIBLE bit being set, since it might have
             * become stale -- even when all_visible is set in prunestate
             */
            if (!PageIsAllVisible(page))
            {
                PageSetAllVisible(page);
                MarkBufferDirty(buf);
            }
 
            /*
             * Set the page all-frozen (and all-visible) in the VM.
             *
             * We can pass InvalidTransactionId as our visibility_cutoff_xid,
             * since a snapshotConflictHorizon sufficient to make everything
             * safe for REDO was logged when the page's tuples were frozen.
             */
            Assert(!TransactionIdIsValid(prunestate.visibility_cutoff_xid));
            visibilitymap_set(vacrel->rel, blkno, buf, InvalidXLogRecPtr,
                              vmbuffer, InvalidTransactionId,
                              VISIBILITYMAP_ALL_VISIBLE |
                              VISIBILITYMAP_ALL_FROZEN);
        }
 
        /*
         * Final steps for block: drop cleanup lock, record free space in the
         * FSM
         */
        if (prunestate.has_lpdead_items && vacrel->do_index_vacuuming)
        {
            /*
             * Wait until lazy_vacuum_heap_rel() to save free space.  This
             * doesn't just save us some cycles; it also allows us to record
             * any additional free space that lazy_vacuum_heap_page() will
             * make available in cases where it's possible to truncate the
             * page's line pointer array.
             *
             * Note: It's not in fact 100% certain that we really will call
             * lazy_vacuum_heap_rel() -- lazy_vacuum() might yet opt to skip
             * index vacuuming (and so must skip heap vacuuming).  This is
             * deemed okay because it only happens in emergencies, or when
             * there is very little free space anyway. (Besides, we start
             * recording free space in the FSM once index vacuuming has been
             * abandoned.)
             *
             * Note: The one-pass (no indexes) case is only supposed to make
             * it this far when there were no LP_DEAD items during pruning.
             */
            Assert(vacrel->nindexes > 0);
            UnlockReleaseBuffer(buf);
        }
        else
        {
            Size        freespace = PageGetHeapFreeSpace(page);
 
            UnlockReleaseBuffer(buf);
            RecordPageWithFreeSpace(vacrel->rel, blkno, freespace);
        }
    }
 
    vacrel->blkno = InvalidBlockNumber;
    if (BufferIsValid(vmbuffer))
        ReleaseBuffer(vmbuffer);
 
    /* report that everything is now scanned */
    pgstat_progress_update_param(PROGRESS_VACUUM_HEAP_BLKS_SCANNED, blkno);
 
    /* now we can compute the new value for pg_class.reltuples */
    vacrel->new_live_tuples = vac_estimate_reltuples(vacrel->rel, rel_pages,
                                                     vacrel->scanned_pages,
                                                     vacrel->live_tuples);
 
    /*
     * Also compute the total number of surviving heap entries.  In the
     * (unlikely) scenario that new_live_tuples is -1, take it as zero.
     */
    vacrel->new_rel_tuples =
        Max(vacrel->new_live_tuples, 0) + vacrel->recently_dead_tuples +
        vacrel->missed_dead_tuples;
 
    /*
     * Do index vacuuming (call each index's ambulkdelete routine), then do
     * related heap vacuuming
     */
    if (dead_items->num_items > 0)
        lazy_vacuum(vacrel);
 
    /*
     * Vacuum the remainder of the Free Space Map.  We must do this whether or
     * not there were indexes, and whether or not we bypassed index vacuuming.
     */
    if (blkno > next_fsm_block_to_vacuum)
        FreeSpaceMapVacuumRange(vacrel->rel, next_fsm_block_to_vacuum, blkno);
 
    /* report all blocks vacuumed */
    pgstat_progress_update_param(PROGRESS_VACUUM_HEAP_BLKS_VACUUMED, blkno);
 
    /* Do final index cleanup (call each index's amvacuumcleanup routine) */
    if (vacrel->nindexes > 0 && vacrel->do_index_cleanup)
        lazy_cleanup_all_indexes(vacrel);
}
 
/*
 *  lazy_scan_skip() -- set up range of skippable blocks using visibility map.
 *
 * lazy_scan_heap() calls here every time it needs to set up a new range of
 * blocks to skip via the visibility map.  Caller passes the next block in
 * line.  We return a next_unskippable_block for this range.  When there are
 * no skippable blocks we just return caller's next_block.  The all-visible
 * status of the returned block is set in *next_unskippable_allvis for caller,
 * too.  Block usually won't be all-visible (since it's unskippable), but it
 * can be during aggressive VACUUMs (as well as in certain edge cases).
 *
 * Sets *skipping_current_range to indicate if caller should skip this range.
 * Costs and benefits drive our decision.  Very small ranges won't be skipped.
 *
 * Note: our opinion of which blocks can be skipped can go stale immediately.
 * It's okay if caller "misses" a page whose all-visible or all-frozen marking
 * was concurrently cleared, though.  All that matters is that caller scan all
 * pages whose tuples might contain XIDs < OldestXmin, or MXIDs < OldestMxact.
 * (Actually, non-aggressive VACUUMs can choose to skip all-visible pages with
 * older XIDs/MXIDs.  The vacrel->skippedallvis flag will be set here when the
 * choice to skip such a range is actually made, making everything safe.)
 */
static BlockNumber
lazy_scan_skip(LVRelState *vacrel, Buffer *vmbuffer, BlockNumber next_block,
               bool *next_unskippable_allvis, bool *skipping_current_range)
{
    BlockNumber rel_pages = vacrel->rel_pages,
                next_unskippable_block = next_block,
                nskippable_blocks = 0;
    bool        skipsallvis = false;
 
    *next_unskippable_allvis = true;
    while (next_unskippable_block < rel_pages)
    {
        uint8       mapbits = visibilitymap_get_status(vacrel->rel,
                                                       next_unskippable_block,
                                                       vmbuffer);
 
        if ((mapbits & VISIBILITYMAP_ALL_VISIBLE) == 0)
        {
            Assert((mapbits & VISIBILITYMAP_ALL_FROZEN) == 0);
            *next_unskippable_allvis = false;
            break;
        }
 
        /*
         * Caller must scan the last page to determine whether it has tuples
         * (caller must have the opportunity to set vacrel->nonempty_pages).
         * This rule avoids having lazy_truncate_heap() take access-exclusive
         * lock on rel to attempt a truncation that fails anyway, just because
         * there are tuples on the last page (it is likely that there will be
         * tuples on other nearby pages as well, but those can be skipped).
         *
         * Implement this by always treating the last block as unsafe to skip.
         */
        if (next_unskippable_block == rel_pages - 1)
            break;
 
        /* DISABLE_PAGE_SKIPPING makes all skipping unsafe */
        if (!vacrel->skipwithvm)
        {
            /* Caller shouldn't rely on all_visible_according_to_vm */
            *next_unskippable_allvis = false;
            break;
        }
 
        /*
         * Aggressive VACUUM caller can't skip pages just because they are
         * all-visible.  They may still skip all-frozen pages, which can't
         * contain XIDs < OldestXmin (XIDs that aren't already frozen by now).
         */
        if ((mapbits & VISIBILITYMAP_ALL_FROZEN) == 0)
        {
            if (vacrel->aggressive)
                break;
 
            /*
             * All-visible block is safe to skip in non-aggressive case.  But
             * remember that the final range contains such a block for later.
             */
            skipsallvis = true;
        }
 
        vacuum_delay_point();
        next_unskippable_block++;
        nskippable_blocks++;
    }
 
    /*
     * We only skip a range with at least SKIP_PAGES_THRESHOLD consecutive
     * pages.  Since we're reading sequentially, the OS should be doing
     * readahead for us, so there's no gain in skipping a page now and then.
     * Skipping such a range might even discourage sequential detection.
     *
     * This test also enables more frequent relfrozenxid advancement during
     * non-aggressive VACUUMs.  If the range has any all-visible pages then
     * skipping makes updating relfrozenxid unsafe, which is a real downside.
     */
    if (nskippable_blocks < SKIP_PAGES_THRESHOLD)
        *skipping_current_range = false;
    else
    {
        *skipping_current_range = true;
        if (skipsallvis)
            vacrel->skippedallvis = true;
    }
 
    return next_unskippable_block;
}
 
/*
 *  lazy_scan_new_or_empty() -- lazy_scan_heap() new/empty page handling.
 *
 * Must call here to handle both new and empty pages before calling
 * lazy_scan_prune or lazy_scan_noprune, since they're not prepared to deal
 * with new or empty pages.
 *
 * It's necessary to consider new pages as a special case, since the rules for
 * maintaining the visibility map and FSM with empty pages are a little
 * different (though new pages can be truncated away during rel truncation).
 *
 * Empty pages are not really a special case -- they're just heap pages that
 * have no allocated tuples (including even LP_UNUSED items).  You might
 * wonder why we need to handle them here all the same.  It's only necessary
 * because of a corner-case involving a hard crash during heap relation
 * extension.  If we ever make relation-extension crash safe, then it should
 * no longer be necessary to deal with empty pages here (or new pages, for
 * that matter).
 *
 * Caller must hold at least a shared lock.  We might need to escalate the
 * lock in that case, so the type of lock caller holds needs to be specified
 * using 'sharelock' argument.
 *
 * Returns false in common case where caller should go on to call
 * lazy_scan_prune (or lazy_scan_noprune).  Otherwise returns true, indicating
 * that lazy_scan_heap is done processing the page, releasing lock on caller's
 * behalf.
 */
static bool
lazy_scan_new_or_empty(LVRelState *vacrel, Buffer buf, BlockNumber blkno,
                       Page page, bool sharelock, Buffer vmbuffer)
{
    Size        freespace;
 
    if (PageIsNew(page))
    {
        /*
         * All-zeroes pages can be left over if either a backend extends the
         * relation by a single page, but crashes before the newly initialized
         * page has been written out, or when bulk-extending the relation
         * (which creates a number of empty pages at the tail end of the
         * relation), and then enters them into the FSM.
         *
         * Note we do not enter the page into the visibilitymap. That has the
         * downside that we repeatedly visit this page in subsequent vacuums,
         * but otherwise we'll never discover the space on a promoted standby.
         * The harm of repeated checking ought to normally not be too bad. The
         * space usually should be used at some point, otherwise there
         * wouldn't be any regular vacuums.
         *
         * Make sure these pages are in the FSM, to ensure they can be reused.
         * Do that by testing if there's any space recorded for the page. If
         * not, enter it. We do so after releasing the lock on the heap page,
         * the FSM is approximate, after all.
         */
        UnlockReleaseBuffer(buf);
 
        if (GetRecordedFreeSpace(vacrel->rel, blkno) == 0)
        {
            freespace = BLCKSZ - SizeOfPageHeaderData;
 
            RecordPageWithFreeSpace(vacrel->rel, blkno, freespace);
        }
 
        return true;
    }
 
    if (PageIsEmpty(page))
    {
        /*
         * It seems likely that caller will always be able to get a cleanup
         * lock on an empty page.  But don't take any chances -- escalate to
         * an exclusive lock (still don't need a cleanup lock, though).
         */
        if (sharelock)
        {
            LockBuffer(buf, BUFFER_LOCK_UNLOCK);
            LockBuffer(buf, BUFFER_LOCK_EXCLUSIVE);
 
            if (!PageIsEmpty(page))
            {
                /* page isn't new or empty -- keep lock and pin for now */
                return false;
            }
        }
        else
        {
            /* Already have a full cleanup lock (which is more than enough) */
        }
 
        /*
         * Unlike new pages, empty pages are always set all-visible and
         * all-frozen.
         */
        if (!PageIsAllVisible(page))
        {
            START_CRIT_SECTION();
 
            /* mark buffer dirty before writing a WAL record */
            MarkBufferDirty(buf);
 
            /*
             * It's possible that another backend has extended the heap,
             * initialized the page, and then failed to WAL-log the page due
             * to an ERROR.  Since heap extension is not WAL-logged, recovery
             * might try to replay our record setting the page all-visible and
             * find that the page isn't initialized, which will cause a PANIC.
             * To prevent that, check whether the page has been previously
             * WAL-logged, and if not, do that now.
             */
            if (RelationNeedsWAL(vacrel->rel) &&
                PageGetLSN(page) == InvalidXLogRecPtr)
                log_newpage_buffer(buf, true);
 
            PageSetAllVisible(page);
            visibilitymap_set(vacrel->rel, blkno, buf, InvalidXLogRecPtr,
                              vmbuffer, InvalidTransactionId,
                              VISIBILITYMAP_ALL_VISIBLE | VISIBILITYMAP_ALL_FROZEN);
            END_CRIT_SECTION();
        }
 
        freespace = PageGetHeapFreeSpace(page);
        UnlockReleaseBuffer(buf);
        RecordPageWithFreeSpace(vacrel->rel, blkno, freespace);
        return true;
    }
 
    /* page isn't new or empty -- keep lock and pin */
    return false;
}
 
/*
 *  lazy_scan_prune() -- lazy_scan_heap() pruning and freezing.
 *
 * Caller must hold pin and buffer cleanup lock on the buffer.
 *
 * Prior to PostgreSQL 14 there were very rare cases where heap_page_prune()
 * was allowed to disagree with our HeapTupleSatisfiesVacuum() call about
 * whether or not a tuple should be considered DEAD.  This happened when an
 * inserting transaction concurrently aborted (after our heap_page_prune()
 * call, before our HeapTupleSatisfiesVacuum() call).  There was rather a lot
 * of complexity just so we could deal with tuples that were DEAD to VACUUM,
 * but nevertheless were left with storage after pruning.
 *
 * As of Postgres 17, we circumvent this problem altogether by reusing the
 * result of heap_page_prune()'s visibility check. Without the second call to
 * HeapTupleSatisfiesVacuum(), there is no new HTSV_Result and there can be no
 * disagreement. We'll just handle such tuples as if they had become fully dead
 * right after this operation completes instead of in the middle of it. Note that
 * any tuple that becomes dead after the call to heap_page_prune() can't need to
 * be frozen, because it was visible to another session when vacuum started.
 */
static void
lazy_scan_prune(LVRelState *vacrel,
                Buffer buf,
                BlockNumber blkno,
                Page page,
                LVPagePruneState *prunestate)
{
    Relation    rel = vacrel->rel;
    OffsetNumber offnum,
                maxoff;
    ItemId      itemid;
    PruneResult presult;
    int         tuples_frozen,
                lpdead_items,
                live_tuples,
                recently_dead_tuples;
    HeapPageFreeze pagefrz;
    int64       fpi_before = pgWalUsage.wal_fpi;
    OffsetNumber deadoffsets[MaxHeapTuplesPerPage];
    HeapTupleFreeze frozen[MaxHeapTuplesPerPage];
 
    Assert(BufferGetBlockNumber(buf) == blkno);
 
    /*
     * maxoff might be reduced following line pointer array truncation in
     * heap_page_prune.  That's safe for us to ignore, since the reclaimed
     * space will continue to look like LP_UNUSED items below.
     */
    maxoff = PageGetMaxOffsetNumber(page);
 
    /* Initialize (or reset) page-level state */
    pagefrz.freeze_required = false;
    pagefrz.FreezePageRelfrozenXid = vacrel->NewRelfrozenXid;
    pagefrz.FreezePageRelminMxid = vacrel->NewRelminMxid;
    pagefrz.NoFreezePageRelfrozenXid = vacrel->NewRelfrozenXid;
    pagefrz.NoFreezePageRelminMxid = vacrel->NewRelminMxid;
    tuples_frozen = 0;
    lpdead_items = 0;
    live_tuples = 0;
    recently_dead_tuples = 0;
 
    /*
     * Prune all HOT-update chains in this page.
     *
     * We count the number of tuples removed from the page by the pruning step
     * in presult.ndeleted. It should not be confused with lpdead_items;
     * lpdead_items's final value can be thought of as the number of tuples
     * that were deleted from indexes.
     */
    heap_page_prune(rel, buf, vacrel->vistest, &presult, &vacrel->offnum);
 
    /*
     * Now scan the page to collect LP_DEAD items and check for tuples
     * requiring freezing among remaining tuples with storage
     */
    prunestate->hastup = false;
    prunestate->has_lpdead_items = false;
    prunestate->all_visible = true;
    prunestate->all_frozen = true;
    prunestate->visibility_cutoff_xid = InvalidTransactionId;
 
    for (offnum = FirstOffsetNumber;
         offnum <= maxoff;
         offnum = OffsetNumberNext(offnum))
    {
        HeapTupleHeader htup;
        bool        totally_frozen;
 
        /*
         * Set the offset number so that we can display it along with any
         * error that occurred while processing this tuple.
         */
        vacrel->offnum = offnum;
        itemid = PageGetItemId(page, offnum);
 
        if (!ItemIdIsUsed(itemid))
            continue;
 
        /* Redirect items mustn't be touched */
        if (ItemIdIsRedirected(itemid))
        {
            /* page makes rel truncation unsafe */
            prunestate->hastup = true;
            continue;
        }
 
        if (ItemIdIsDead(itemid))
        {
            /*
             * Deliberately don't set hastup for LP_DEAD items.  We make the
             * soft assumption that any LP_DEAD items encountered here will
             * become LP_UNUSED later on, before count_nondeletable_pages is
             * reached.  If we don't make this assumption then rel truncation
             * will only happen every other VACUUM, at most.  Besides, VACUUM
             * must treat hastup/nonempty_pages as provisional no matter how
             * LP_DEAD items are handled (handled here, or handled later on).
             *
             * Also deliberately delay unsetting all_visible until just before
             * we return to lazy_scan_heap caller, as explained in full below.
             * (This is another case where it's useful to anticipate that any
             * LP_DEAD items will become LP_UNUSED during the ongoing VACUUM.)
             */
            deadoffsets[lpdead_items++] = offnum;
            continue;
        }
 
        Assert(ItemIdIsNormal(itemid));
 
        htup = (HeapTupleHeader) PageGetItem(page, itemid);
 
        /*
         * The criteria for counting a tuple as live in this block need to
         * match what analyze.c's acquire_sample_rows() does, otherwise VACUUM
         * and ANALYZE may produce wildly different reltuples values, e.g.
         * when there are many recently-dead tuples.
         *
         * The logic here is a bit simpler than acquire_sample_rows(), as
         * VACUUM can't run inside a transaction block, which makes some cases
         * impossible (e.g. in-progress insert from the same transaction).
         *
         * We treat LP_DEAD items (which are the closest thing to DEAD tuples
         * that might be seen here) differently, too: we assume that they'll
         * become LP_UNUSED before VACUUM finishes.  This difference is only
         * superficial.  VACUUM effectively agrees with ANALYZE about DEAD
         * items, in the end.  VACUUM won't remember LP_DEAD items, but only
         * because they're not supposed to be left behind when it is done.
         * (Cases where we bypass index vacuuming will violate this optimistic
         * assumption, but the overall impact of that should be negligible.)
         */
        switch (htsv_get_valid_status(presult.htsv[offnum]))
        {
            case HEAPTUPLE_LIVE:
 
                /*
                 * Count it as live.  Not only is this natural, but it's also
                 * what acquire_sample_rows() does.
                 */
                live_tuples++;
 
                /*
                 * Is the tuple definitely visible to all transactions?
                 *
                 * NB: Like with per-tuple hint bits, we can't set the
                 * PD_ALL_VISIBLE flag if the inserter committed
                 * asynchronously. See SetHintBits for more info. Check that
                 * the tuple is hinted xmin-committed because of that.
                 */
                if (prunestate->all_visible)
                {
                    TransactionId xmin;
 
                    if (!HeapTupleHeaderXminCommitted(htup))
                    {
                        prunestate->all_visible = false;
                        break;
                    }
 
                    /*
                     * The inserter definitely committed. But is it old enough
                     * that everyone sees it as committed?
                     */
                    xmin = HeapTupleHeaderGetXmin(htup);
                    if (!TransactionIdPrecedes(xmin,
                                               vacrel->cutoffs.OldestXmin))
                    {
                        prunestate->all_visible = false;
                        break;
                    }
 
                    /* Track newest xmin on page. */
                    if (TransactionIdFollows(xmin, prunestate->visibility_cutoff_xid) &&
                        TransactionIdIsNormal(xmin))
                        prunestate->visibility_cutoff_xid = xmin;
                }
                break;
            case HEAPTUPLE_RECENTLY_DEAD:
 
                /*
                 * If tuple is recently dead then we must not remove it from
                 * the relation.  (We only remove items that are LP_DEAD from
                 * pruning.)
                 */
                recently_dead_tuples++;
                prunestate->all_visible = false;
                break;
            case HEAPTUPLE_INSERT_IN_PROGRESS:
 
                /*
                 * We do not count these rows as live, because we expect the
                 * inserting transaction to update the counters at commit, and
                 * we assume that will happen only after we report our
                 * results.  This assumption is a bit shaky, but it is what
                 * acquire_sample_rows() does, so be consistent.
                 */
                prunestate->all_visible = false;
                break;
            case HEAPTUPLE_DELETE_IN_PROGRESS:
                /* This is an expected case during concurrent vacuum */
                prunestate->all_visible = false;
 
                /*
                 * Count such rows as live.  As above, we assume the deleting
                 * transaction will commit and update the counters after we
                 * report.
                 */
                live_tuples++;
                break;
            default:
                elog(ERROR, "unexpected HeapTupleSatisfiesVacuum result");
                break;
        }
 
        prunestate->hastup = true;  /* page makes rel truncation unsafe */
 
        /* Tuple with storage -- consider need to freeze */
        if (heap_prepare_freeze_tuple(htup, &vacrel->cutoffs, &pagefrz,
                                      &frozen[tuples_frozen], &totally_frozen))
        {
            /* Save prepared freeze plan for later */
            frozen[tuples_frozen++].offset = offnum;
        }
 
        /*
         * If any tuple isn't either totally frozen already or eligible to
         * become totally frozen (according to its freeze plan), then the page
         * definitely cannot be set all-frozen in the visibility map later on
         */
        if (!totally_frozen)
            prunestate->all_frozen = false;
    }
 
    /*
     * We have now divided every item on the page into either an LP_DEAD item
     * that will need to be vacuumed in indexes later, or a LP_NORMAL tuple
     * that remains and needs to be considered for freezing now (LP_UNUSED and
     * LP_REDIRECT items also remain, but are of no further interest to us).
     */
    vacrel->offnum = InvalidOffsetNumber;
 
    /*
     * Freeze the page when heap_prepare_freeze_tuple indicates that at least
     * one XID/MXID from before FreezeLimit/MultiXactCutoff is present.  Also
     * freeze when pruning generated an FPI, if doing so means that we set the
     * page all-frozen afterwards (might not happen until final heap pass).
     */
    if (pagefrz.freeze_required || tuples_frozen == 0 ||
        (prunestate->all_visible && prunestate->all_frozen &&
         fpi_before != pgWalUsage.wal_fpi))
    {
        /*
         * We're freezing the page.  Our final NewRelfrozenXid doesn't need to
         * be affected by the XIDs that are just about to be frozen anyway.
         */
        vacrel->NewRelfrozenXid = pagefrz.FreezePageRelfrozenXid;
        vacrel->NewRelminMxid = pagefrz.FreezePageRelminMxid;
 
        if (tuples_frozen == 0)
        {
            /*
             * We have no freeze plans to execute, so there's no added cost
             * from following the freeze path.  That's why it was chosen. This
             * is important in the case where the page only contains totally
             * frozen tuples at this point (perhaps only following pruning).
             * Such pages can be marked all-frozen in the VM by our caller,
             * even though none of its tuples were newly frozen here (note
             * that the "no freeze" path never sets pages all-frozen).
             *
             * We never increment the frozen_pages instrumentation counter
             * here, since it only counts pages with newly frozen tuples
             * (don't confuse that with pages newly set all-frozen in VM).
             */
        }
        else
        {
            TransactionId snapshotConflictHorizon;
 
            vacrel->frozen_pages++;
 
            /*
             * We can use visibility_cutoff_xid as our cutoff for conflicts
             * when the whole page is eligible to become all-frozen in the VM
             * once we're done with it.  Otherwise we generate a conservative
             * cutoff by stepping back from OldestXmin.
             */
            if (prunestate->all_visible && prunestate->all_frozen)
            {
                /* Using same cutoff when setting VM is now unnecessary */
                snapshotConflictHorizon = prunestate->visibility_cutoff_xid;
                prunestate->visibility_cutoff_xid = InvalidTransactionId;
            }
            else
            {
                /* Avoids false conflicts when hot_standby_feedback in use */
                snapshotConflictHorizon = vacrel->cutoffs.OldestXmin;
                TransactionIdRetreat(snapshotConflictHorizon);
            }
 
            /* Execute all freeze plans for page as a single atomic action */
            heap_freeze_execute_prepared(vacrel->rel, buf,
                                         snapshotConflictHorizon,
                                         frozen, tuples_frozen);
        }
    }
    else
    {
        /*
         * Page requires "no freeze" processing.  It might be set all-visible
         * in the visibility map, but it can never be set all-frozen.
         */
        vacrel->NewRelfrozenXid = pagefrz.NoFreezePageRelfrozenXid;
        vacrel->NewRelminMxid = pagefrz.NoFreezePageRelminMxid;
        prunestate->all_frozen = false;
        tuples_frozen = 0;      /* avoid miscounts in instrumentation */
    }
 
    /*
     * VACUUM will call heap_page_is_all_visible() during the second pass over
     * the heap to determine all_visible and all_frozen for the page -- this
     * is a specialized version of the logic from this function.  Now that
     * we've finished pruning and freezing, make sure that we're in total
     * agreement with heap_page_is_all_visible() using an assertion.
     */
#ifdef USE_ASSERT_CHECKING
    /* Note that all_frozen value does not matter when !all_visible */
    if (prunestate->all_visible && lpdead_items == 0)
    {
        TransactionId cutoff;
        bool        all_frozen;
 
        if (!heap_page_is_all_visible(vacrel, buf, &cutoff, &all_frozen))
            Assert(false);
 
        Assert(!TransactionIdIsValid(cutoff) ||
               cutoff == prunestate->visibility_cutoff_xid);
    }
#endif
 
    /*
     * Now save details of the LP_DEAD items from the page in vacrel
     */
    if (lpdead_items > 0)
    {
        VacDeadItems *dead_items = vacrel->dead_items;
        ItemPointerData tmp;
 
        vacrel->lpdead_item_pages++;
        prunestate->has_lpdead_items = true;
 
        ItemPointerSetBlockNumber(&tmp, blkno);
 
        for (int i = 0; i < lpdead_items; i++)
        {
            ItemPointerSetOffsetNumber(&tmp, deadoffsets[i]);
            dead_items->items[dead_items->num_items++] = tmp;
        }
 
        Assert(dead_items->num_items <= dead_items->max_items);
        pgstat_progress_update_param(PROGRESS_VACUUM_NUM_DEAD_TUPLES,
                                     dead_items->num_items);
 
        /*
         * It was convenient to ignore LP_DEAD items in all_visible earlier on
         * to make the choice of whether or not to freeze the page unaffected
         * by the short-term presence of LP_DEAD items.  These LP_DEAD items
         * were effectively assumed to be LP_UNUSED items in the making.  It
         * doesn't matter which heap pass (initial pass or final pass) ends up
         * setting the page all-frozen, as long as the ongoing VACUUM does it.
         *
         * Now that freezing has been finalized, unset all_visible.  It needs
         * to reflect the present state of things, as expected by our caller.
         */
        prunestate->all_visible = false;
    }
 
    /* Finally, add page-local counts to whole-VACUUM counts */
    vacrel->tuples_deleted += presult.ndeleted;
    vacrel->tuples_frozen += tuples_frozen;
    vacrel->lpdead_items += lpdead_items;
    vacrel->live_tuples += live_tuples;
    vacrel->recently_dead_tuples += recently_dead_tuples;
}
 
/*
 *  lazy_scan_noprune() -- lazy_scan_prune() without pruning or freezing
 *
 * Caller need only hold a pin and share lock on the buffer, unlike
 * lazy_scan_prune, which requires a full cleanup lock.  While pruning isn't
 * performed here, it's quite possible that an earlier opportunistic pruning
 * operation left LP_DEAD items behind.  We'll at least collect any such items
 * in the dead_items array for removal from indexes.
 *
 * For aggressive VACUUM callers, we may return false to indicate that a full
 * cleanup lock is required for processing by lazy_scan_prune.  This is only
 * necessary when the aggressive VACUUM needs to freeze some tuple XIDs from
 * one or more tuples on the page.  We always return true for non-aggressive
 * callers.
 *
 * See lazy_scan_prune for an explanation of hastup return flag.
 * recordfreespace flag instructs caller on whether or not it should do
 * generic FSM processing for page.
 */
static bool
lazy_scan_noprune(LVRelState *vacrel,
                  Buffer buf,
                  BlockNumber blkno,
                  Page page,
                  bool *hastup,
                  bool *recordfreespace)
{
    OffsetNumber offnum,
                maxoff;
    int         lpdead_items,
                live_tuples,
                recently_dead_tuples,
                missed_dead_tuples;
    HeapTupleHeader tupleheader;
    TransactionId NoFreezePageRelfrozenXid = vacrel->NewRelfrozenXid;
    MultiXactId NoFreezePageRelminMxid = vacrel->NewRelminMxid;
    OffsetNumber deadoffsets[MaxHeapTuplesPerPage];
 
    Assert(BufferGetBlockNumber(buf) == blkno);
 
    *hastup = false;            /* for now */
    *recordfreespace = false;   /* for now */
 
    lpdead_items = 0;
    live_tuples = 0;
    recently_dead_tuples = 0;
    missed_dead_tuples = 0;
 
    maxoff = PageGetMaxOffsetNumber(page);
    for (offnum = FirstOffsetNumber;
         offnum <= maxoff;
         offnum = OffsetNumberNext(offnum))
    {
        ItemId      itemid;
        HeapTupleData tuple;
 
        vacrel->offnum = offnum;
        itemid = PageGetItemId(page, offnum);
 
        if (!ItemIdIsUsed(itemid))
            continue;
 
        if (ItemIdIsRedirected(itemid))
        {
            *hastup = true;
            continue;
        }
 
        if (ItemIdIsDead(itemid))
        {
            /*
             * Deliberately don't set hastup=true here.  See same point in
             * lazy_scan_prune for an explanation.
             */
            deadoffsets[lpdead_items++] = offnum;
            continue;
        }
 
        *hastup = true;         /* page prevents rel truncation */
        tupleheader = (HeapTupleHeader) PageGetItem(page, itemid);
        if (heap_tuple_should_freeze(tupleheader, &vacrel->cutoffs,
                                     &NoFreezePageRelfrozenXid,
                                     &NoFreezePageRelminMxid))
        {
            /* Tuple with XID < FreezeLimit (or MXID < MultiXactCutoff) */
            if (vacrel->aggressive)
            {
                /*
                 * Aggressive VACUUMs must always be able to advance rel's
                 * relfrozenxid to a value >= FreezeLimit (and be able to
                 * advance rel's relminmxid to a value >= MultiXactCutoff).
                 * The ongoing aggressive VACUUM won't be able to do that
                 * unless it can freeze an XID (or MXID) from this tuple now.
                 *
                 * The only safe option is to have caller perform processing
                 * of this page using lazy_scan_prune.  Caller might have to
                 * wait a while for a cleanup lock, but it can't be helped.
                 */
                vacrel->offnum = InvalidOffsetNumber;
                return false;
            }
 
            /*
             * Non-aggressive VACUUMs are under no obligation to advance
             * relfrozenxid (even by one XID).  We can be much laxer here.
             *
             * Currently we always just accept an older final relfrozenxid
             * and/or relminmxid value.  We never make caller wait or work a
             * little harder, even when it likely makes sense to do so.
             */
        }
 
        ItemPointerSet(&(tuple.t_self), blkno, offnum);
        tuple.t_data = (HeapTupleHeader) PageGetItem(page, itemid);
        tuple.t_len = ItemIdGetLength(itemid);
        tuple.t_tableOid = RelationGetRelid(vacrel->rel);
 
        switch (HeapTupleSatisfiesVacuum(&tuple, vacrel->cutoffs.OldestXmin,
                                         buf))
        {
            case HEAPTUPLE_DELETE_IN_PROGRESS:
            case HEAPTUPLE_LIVE:
 
                /*
                 * Count both cases as live, just like lazy_scan_prune
                 */
                live_tuples++;
 
                break;
            case HEAPTUPLE_DEAD:
 
                /*
                 * There is some useful work for pruning to do, that won't be
                 * done due to failure to get a cleanup lock.
                 */
                missed_dead_tuples++;
                break;
            case HEAPTUPLE_RECENTLY_DEAD:
 
                /*
                 * Count in recently_dead_tuples, just like lazy_scan_prune
                 */
                recently_dead_tuples++;
                break;
            case HEAPTUPLE_INSERT_IN_PROGRESS:
 
                /*
                 * Do not count these rows as live, just like lazy_scan_prune
                 */
                break;
            default:
                elog(ERROR, "unexpected HeapTupleSatisfiesVacuum result");
                break;
        }
    }
 
    vacrel->offnum = InvalidOffsetNumber;
 
    /*
     * By here we know for sure that caller can put off freezing and pruning
     * this particular page until the next VACUUM.  Remember its details now.
     * (lazy_scan_prune expects a clean slate, so we have to do this last.)
     */
    vacrel->NewRelfrozenXid = NoFreezePageRelfrozenXid;
    vacrel->NewRelminMxid = NoFreezePageRelminMxid;
 
    /* Save any LP_DEAD items found on the page in dead_items array */
    if (vacrel->nindexes == 0)
    {
        /* Using one-pass strategy (since table has no indexes) */
        if (lpdead_items > 0)
        {
            /*
             * Perfunctory handling for the corner case where a single pass
             * strategy VACUUM cannot get a cleanup lock, and it turns out
             * that there is one or more LP_DEAD items: just count the LP_DEAD
             * items as missed_dead_tuples instead. (This is a bit dishonest,
             * but it beats having to maintain specialized heap vacuuming code
             * forever, for vanishingly little benefit.)
             */
            *hastup = true;
            missed_dead_tuples += lpdead_items;
        }
 
        *recordfreespace = true;
    }
    else if (lpdead_items == 0)
    {
        /*
         * Won't be vacuuming this page later, so record page's freespace in
         * the FSM now
         */
        *recordfreespace = true;
    }
    else
    {
        VacDeadItems *dead_items = vacrel->dead_items;
        ItemPointerData tmp;
 
        /*
         * Page has LP_DEAD items, and so any references/TIDs that remain in
         * indexes will be deleted during index vacuuming (and then marked
         * LP_UNUSED in the heap)
         */
        vacrel->lpdead_item_pages++;
 
        ItemPointerSetBlockNumber(&tmp, blkno);
 
        for (int i = 0; i < lpdead_items; i++)
        {
            ItemPointerSetOffsetNumber(&tmp, deadoffsets[i]);
            dead_items->items[dead_items->num_items++] = tmp;
        }
 
        Assert(dead_items->num_items <= dead_items->max_items);
        pgstat_progress_update_param(PROGRESS_VACUUM_NUM_DEAD_TUPLES,
                                     dead_items->num_items);
 
        vacrel->lpdead_items += lpdead_items;
 
        /*
         * Assume that we'll go on to vacuum this heap page during final pass
         * over the heap.  Don't record free space until then.
         */
        *recordfreespace = false;
    }
 
    /*
     * Finally, add relevant page-local counts to whole-VACUUM counts
     */
    vacrel->live_tuples += live_tuples;
    vacrel->recently_dead_tuples += recently_dead_tuples;
    vacrel->missed_dead_tuples += missed_dead_tuples;
    if (missed_dead_tuples > 0)
        vacrel->missed_dead_pages++;
 
    /* Caller won't need to call lazy_scan_prune with same page */
    return true;
}
 
/*
 * Main entry point for index vacuuming and heap vacuuming.
 *
 * Removes items collected in dead_items from table's indexes, then marks the
 * same items LP_UNUSED in the heap.  See the comments above lazy_scan_heap
 * for full details.
 *
 * Also empties dead_items, freeing up space for later TIDs.
 *
 * We may choose to bypass index vacuuming at this point, though only when the
 * ongoing VACUUM operation will definitely only have one index scan/round of
 * index vacuuming.
 */
static void
lazy_vacuum(LVRelState *vacrel)
{
    bool        bypass;
 
    /* Should not end up here with no indexes */
    Assert(vacrel->nindexes > 0);
    Assert(vacrel->lpdead_item_pages > 0);
 
    if (!vacrel->do_index_vacuuming)
    {
        Assert(!vacrel->do_index_cleanup);
        vacrel->dead_items->num_items = 0;
        return;
    }
 
    /*
     * Consider bypassing index vacuuming (and heap vacuuming) entirely.
     *
     * We currently only do this in cases where the number of LP_DEAD items
     * for the entire VACUUM operation is close to zero.  This avoids sharp
     * discontinuities in the duration and overhead of successive VACUUM
     * operations that run against the same table with a fixed workload.
     * Ideally, successive VACUUM operations will behave as if there are
     * exactly zero LP_DEAD items in cases where there are close to zero.
     *
     * This is likely to be helpful with a table that is continually affected
     * by UPDATEs that can mostly apply the HOT optimization, but occasionally
     * have small aberrations that lead to just a few heap pages retaining
     * only one or two LP_DEAD items.  This is pretty common; even when the
     * DBA goes out of their way to make UPDATEs use HOT, it is practically
     * impossible to predict whether HOT will be applied in 100% of cases.
     * It's far easier to ensure that 99%+ of all UPDATEs against a table use
     * HOT through careful tuning.
     */
    bypass = false;
    if (vacrel->consider_bypass_optimization && vacrel->rel_pages > 0)
    {
        BlockNumber threshold;
 
        Assert(vacrel->num_index_scans == 0);
        Assert(vacrel->lpdead_items == vacrel->dead_items->num_items);
        Assert(vacrel->do_index_vacuuming);
        Assert(vacrel->do_index_cleanup);
 
        /*
         * This crossover point at which we'll start to do index vacuuming is
         * expressed as a percentage of the total number of heap pages in the
         * table that are known to have at least one LP_DEAD item.  This is
         * much more important than the total number of LP_DEAD items, since
         * it's a proxy for the number of heap pages whose visibility map bits
         * cannot be set on account of bypassing index and heap vacuuming.
         *
         * We apply one further precautionary test: the space currently used
         * to store the TIDs (TIDs that now all point to LP_DEAD items) must
         * not exceed 32MB.  This limits the risk that we will bypass index
         * vacuuming again and again until eventually there is a VACUUM whose
         * dead_items space is not CPU cache resident.
         *
         * We don't take any special steps to remember the LP_DEAD items (such
         * as counting them in our final update to the stats system) when the
         * optimization is applied.  Though the accounting used in analyze.c's
         * acquire_sample_rows() will recognize the same LP_DEAD items as dead
         * rows in its own stats report, that's okay. The discrepancy should
         * be negligible.  If this optimization is ever expanded to cover more
         * cases then this may need to be reconsidered.
         */
        threshold = (double) vacrel->rel_pages * BYPASS_THRESHOLD_PAGES;
        bypass = (vacrel->lpdead_item_pages < threshold &&
                  vacrel->lpdead_items < MAXDEADITEMS(32L * 1024L * 1024L));
    }
 
    if (bypass)
    {
        /*
         * There are almost zero TIDs.  Behave as if there were precisely
         * zero: bypass index vacuuming, but do index cleanup.
         *
         * We expect that the ongoing VACUUM operation will finish very
         * quickly, so there is no point in considering speeding up as a
         * failsafe against wraparound failure. (Index cleanup is expected to
         * finish very quickly in cases where there were no ambulkdelete()
         * calls.)
         */
        vacrel->do_index_vacuuming = false;
    }
    else if (lazy_vacuum_all_indexes(vacrel))
    {
        /*
         * We successfully completed a round of index vacuuming.  Do related
         * heap vacuuming now.
         */
        lazy_vacuum_heap_rel(vacrel);
    }
    else
    {
        /*
         * Failsafe case.
         *
         * We attempted index vacuuming, but didn't finish a full round/full
         * index scan.  This happens when relfrozenxid or relminmxid is too
         * far in the past.
         *
         * From this point on the VACUUM operation will do no further index
         * vacuuming or heap vacuuming.  This VACUUM operation won't end up
         * back here again.
         */
        Assert(VacuumFailsafeActive);
    }
 
    /*
     * Forget the LP_DEAD items that we just vacuumed (or just decided to not
     * vacuum)
     */
    vacrel->dead_items->num_items = 0;
}
 
/*
 *  lazy_vacuum_all_indexes() -- Main entry for index vacuuming
 *
 * Returns true in the common case when all indexes were successfully
 * vacuumed.  Returns false in rare cases where we determined that the ongoing
 * VACUUM operation is at risk of taking too long to finish, leading to
 * wraparound failure.
 */
static bool
lazy_vacuum_all_indexes(LVRelState *vacrel)
{
    bool        allindexes = true;
    double      old_live_tuples = vacrel->rel->rd_rel->reltuples;
    const int   progress_start_index[] = {
        PROGRESS_VACUUM_PHASE,
        PROGRESS_VACUUM_INDEXES_TOTAL
    };
    const int   progress_end_index[] = {
        PROGRESS_VACUUM_INDEXES_TOTAL,
        PROGRESS_VACUUM_INDEXES_PROCESSED,
        PROGRESS_VACUUM_NUM_INDEX_VACUUMS
    };
    int64       progress_start_val[2];
    int64       progress_end_val[3];
 
    Assert(vacrel->nindexes > 0);
    Assert(vacrel->do_index_vacuuming);
    Assert(vacrel->do_index_cleanup);
 
    /* Precheck for XID wraparound emergencies */
    if (lazy_check_wraparound_failsafe(vacrel))
    {
        /* Wraparound emergency -- don't even start an index scan */
        return false;
    }
 
    /*
     * Report that we are now vacuuming indexes and the number of indexes to
     * vacuum.
     */
    progress_start_val[0] = PROGRESS_VACUUM_PHASE_VACUUM_INDEX;
    progress_start_val[1] = vacrel->nindexes;
    pgstat_progress_update_multi_param(2, progress_start_index, progress_start_val);
 
    if (!ParallelVacuumIsActive(vacrel))
    {
        for (int idx = 0; idx < vacrel->nindexes; idx++)
        {
            Relation    indrel = vacrel->indrels[idx];
            IndexBulkDeleteResult *istat = vacrel->indstats[idx];
 
            vacrel->indstats[idx] = lazy_vacuum_one_index(indrel, istat,
                                                          old_live_tuples,
                                                          vacrel);
 
            /* Report the number of indexes vacuumed */
            pgstat_progress_update_param(PROGRESS_VACUUM_INDEXES_PROCESSED,
                                         idx + 1);
 
            if (lazy_check_wraparound_failsafe(vacrel))
            {
                /* Wraparound emergency -- end current index scan */
                allindexes = false;
                break;
            }
        }
    }
    else
    {
        /* Outsource everything to parallel variant */
        parallel_vacuum_bulkdel_all_indexes(vacrel->pvs, old_live_tuples,
                                            vacrel->num_index_scans);
 
        /*
         * Do a postcheck to consider applying wraparound failsafe now.  Note
         * that parallel VACUUM only gets the precheck and this postcheck.
         */
        if (lazy_check_wraparound_failsafe(vacrel))
            allindexes = false;
    }
 
    /*
     * We delete all LP_DEAD items from the first heap pass in all indexes on
     * each call here (except calls where we choose to do the failsafe). This
     * makes the next call to lazy_vacuum_heap_rel() safe (except in the event
     * of the failsafe triggering, which prevents the next call from taking
     * place).
     */
    Assert(vacrel->num_index_scans > 0 ||
           vacrel->dead_items->num_items == vacrel->lpdead_items);
    Assert(allindexes || VacuumFailsafeActive);
 
    /*
     * Increase and report the number of index scans.  Also, we reset
     * PROGRESS_VACUUM_INDEXES_TOTAL and PROGRESS_VACUUM_INDEXES_PROCESSED.
     *
     * We deliberately include the case where we started a round of bulk
     * deletes that we weren't able to finish due to the failsafe triggering.
     */
    vacrel->num_index_scans++;
    progress_end_val[0] = 0;
    progress_end_val[1] = 0;
    progress_end_val[2] = vacrel->num_index_scans;
    pgstat_progress_update_multi_param(3, progress_end_index, progress_end_val);
 
    return allindexes;
}
 
/*
 *  lazy_vacuum_heap_rel() -- second pass over the heap for two pass strategy
 *
 * This routine marks LP_DEAD items in vacrel->dead_items array as LP_UNUSED.
 * Pages that never had lazy_scan_prune record LP_DEAD items are not visited
 * at all.
 *
 * We may also be able to truncate the line pointer array of the heap pages we
 * visit.  If there is a contiguous group of LP_UNUSED items at the end of the
 * array, it can be reclaimed as free space.  These LP_UNUSED items usually
 * start out as LP_DEAD items recorded by lazy_scan_prune (we set items from
 * each page to LP_UNUSED, and then consider if it's possible to truncate the
 * page's line pointer array).
 *
 * Note: the reason for doing this as a second pass is we cannot remove the
 * tuples until we've removed their index entries, and we want to process
 * index entry removal in batches as large as possible.
 */
static void
lazy_vacuum_heap_rel(LVRelState *vacrel)
{
    int         index = 0;
    BlockNumber vacuumed_pages = 0;
    Buffer      vmbuffer = InvalidBuffer;
    LVSavedErrInfo saved_err_info;
 
    Assert(vacrel->do_index_vacuuming);
    Assert(vacrel->do_index_cleanup);
    Assert(vacrel->num_index_scans > 0);
 
    /* Report that we are now vacuuming the heap */
    pgstat_progress_update_param(PROGRESS_VACUUM_PHASE,
                                 PROGRESS_VACUUM_PHASE_VACUUM_HEAP);
 
    /* Update error traceback information */
    update_vacuum_error_info(vacrel, &saved_err_info,
                             VACUUM_ERRCB_PHASE_VACUUM_HEAP,
                             InvalidBlockNumber, InvalidOffsetNumber);
 
    while (index < vacrel->dead_items->num_items)
    {
        BlockNumber blkno;
        Buffer      buf;
        Page        page;
        Size        freespace;
 
        vacuum_delay_point();
 
        blkno = ItemPointerGetBlockNumber(&vacrel->dead_items->items[index]);
        vacrel->blkno = blkno;
 
        /*
         * Pin the visibility map page in case we need to mark the page
         * all-visible.  In most cases this will be very cheap, because we'll
         * already have the correct page pinned anyway.
         */
        visibilitymap_pin(vacrel->rel, blkno, &vmbuffer);
 
        /* We need a non-cleanup exclusive lock to mark dead_items unused */
        buf = ReadBufferExtended(vacrel->rel, MAIN_FORKNUM, blkno, RBM_NORMAL,
                                 vacrel->bstrategy);
        LockBuffer(buf, BUFFER_LOCK_EXCLUSIVE);
        index = lazy_vacuum_heap_page(vacrel, blkno, buf, index, vmbuffer);
 
        /* Now that we've vacuumed the page, record its available space */
        page = BufferGetPage(buf);
        freespace = PageGetHeapFreeSpace(page);
 
        UnlockReleaseBuffer(buf);
        RecordPageWithFreeSpace(vacrel->rel, blkno, freespace);
        vacuumed_pages++;
    }
 
    vacrel->blkno = InvalidBlockNumber;
    if (BufferIsValid(vmbuffer))
        ReleaseBuffer(vmbuffer);
 
    /*
     * We set all LP_DEAD items from the first heap pass to LP_UNUSED during
     * the second heap pass.  No more, no less.
     */
    Assert(index > 0);
    Assert(vacrel->num_index_scans > 1 ||
           (index == vacrel->lpdead_items &&
            vacuumed_pages == vacrel->lpdead_item_pages));
 
    ereport(DEBUG2,
            (errmsg("table \"%s\": removed %lld dead item identifiers in %u pages",
                    vacrel->relname, (long long) index, vacuumed_pages)));
 
    /* Revert to the previous phase information for error traceback */
    restore_vacuum_error_info(vacrel, &saved_err_info);
}
 
/*
 *  lazy_vacuum_heap_page() -- free page's LP_DEAD items listed in the
 *                        vacrel->dead_items array.
 *
 * Caller must have an exclusive buffer lock on the buffer (though a full
 * cleanup lock is also acceptable).  vmbuffer must be valid and already have
 * a pin on blkno's visibility map page.
 *
 * index is an offset into the vacrel->dead_items array for the first listed
 * LP_DEAD item on the page.  The return value is the first index immediately
 * after all LP_DEAD items for the same page in the array.
 */
static int
lazy_vacuum_heap_page(LVRelState *vacrel, BlockNumber blkno, Buffer buffer,
                      int index, Buffer vmbuffer)
{
    VacDeadItems *dead_items = vacrel->dead_items;
    Page        page = BufferGetPage(buffer);
    OffsetNumber unused[MaxHeapTuplesPerPage];
    int         nunused = 0;
    TransactionId visibility_cutoff_xid;
    bool        all_frozen;
    LVSavedErrInfo saved_err_info;
 
    Assert(vacrel->nindexes == 0 || vacrel->do_index_vacuuming);
 
    pgstat_progress_update_param(PROGRESS_VACUUM_HEAP_BLKS_VACUUMED, blkno);
 
    /* Update error traceback information */
    update_vacuum_error_info(vacrel, &saved_err_info,
                             VACUUM_ERRCB_PHASE_VACUUM_HEAP, blkno,
                             InvalidOffsetNumber);
 
    START_CRIT_SECTION();
 
    for (; index < dead_items->num_items; index++)
    {
        BlockNumber tblk;
        OffsetNumber toff;
        ItemId      itemid;
 
        tblk = ItemPointerGetBlockNumber(&dead_items->items[index]);
        if (tblk != blkno)
            break;              /* past end of tuples for this block */
        toff = ItemPointerGetOffsetNumber(&dead_items->items[index]);
        itemid = PageGetItemId(page, toff);
 
        Assert(ItemIdIsDead(itemid) && !ItemIdHasStorage(itemid));
        ItemIdSetUnused(itemid);
        unused[nunused++] = toff;
    }
 
    Assert(nunused > 0);
 
    /* Attempt to truncate line pointer array now */
    PageTruncateLinePointerArray(page);
 
    /*
     * Mark buffer dirty before we write WAL.
     */
    MarkBufferDirty(buffer);
 
    /* XLOG stuff */
    if (RelationNeedsWAL(vacrel->rel))
    {
        xl_heap_vacuum xlrec;
        XLogRecPtr  recptr;
 
        xlrec.nunused = nunused;
 
        XLogBeginInsert();
        XLogRegisterData((char *) &xlrec, SizeOfHeapVacuum);
 
        XLogRegisterBuffer(0, buffer, REGBUF_STANDARD);
        XLogRegisterBufData(0, (char *) unused, nunused * sizeof(OffsetNumber));
 
        recptr = XLogInsert(RM_HEAP2_ID, XLOG_HEAP2_VACUUM);
 
        PageSetLSN(page, recptr);
    }
 
    /*
     * End critical section, so we safely can do visibility tests (which
     * possibly need to perform IO and allocate memory!). If we crash now the
     * page (including the corresponding vm bit) might not be marked all
     * visible, but that's fine. A later vacuum will fix that.
     */
    END_CRIT_SECTION();
 
    /*
     * Now that we have removed the LP_DEAD items from the page, once again
     * check if the page has become all-visible.  The page is already marked
     * dirty, exclusively locked, and, if needed, a full page image has been
     * emitted.
     */
    Assert(!PageIsAllVisible(page));
    if (heap_page_is_all_visible(vacrel, buffer, &visibility_cutoff_xid,
                                 &all_frozen))
    {
        uint8       flags = VISIBILITYMAP_ALL_VISIBLE;
 
        if (all_frozen)
        {
            Assert(!TransactionIdIsValid(visibility_cutoff_xid));
            flags |= VISIBILITYMAP_ALL_FROZEN;
        }
 
        PageSetAllVisible(page);
        visibilitymap_set(vacrel->rel, blkno, buffer, InvalidXLogRecPtr,
                          vmbuffer, visibility_cutoff_xid, flags);
    }
 
    /* Revert to the previous phase information for error traceback */
    restore_vacuum_error_info(vacrel, &saved_err_info);
    return index;
}
 
/*
 * Trigger the failsafe to avoid wraparound failure when vacrel table has a
 * relfrozenxid and/or relminmxid that is dangerously far in the past.
 * Triggering the failsafe makes the ongoing VACUUM bypass any further index
 * vacuuming and heap vacuuming.  Truncating the heap is also bypassed.
 *
 * Any remaining work (work that VACUUM cannot just bypass) is typically sped
 * up when the failsafe triggers.  VACUUM stops applying any cost-based delay
 * that it started out with.
 *
 * Returns true when failsafe has been triggered.
 */
static bool
lazy_check_wraparound_failsafe(LVRelState *vacrel)
{
    /* Don't warn more than once per VACUUM */
    if (VacuumFailsafeActive)
        return true;
 
    if (unlikely(vacuum_xid_failsafe_check(&vacrel->cutoffs)))
    {
        const int   progress_index[] = {
            PROGRESS_VACUUM_INDEXES_TOTAL,
            PROGRESS_VACUUM_INDEXES_PROCESSED
        };
        int64       progress_val[2] = {0, 0};
 
        VacuumFailsafeActive = true;
 
        /*
         * Abandon use of a buffer access strategy to allow use of all of
         * shared buffers.  We assume the caller who allocated the memory for
         * the BufferAccessStrategy will free it.
         */
        vacrel->bstrategy = NULL;
 
        /* Disable index vacuuming, index cleanup, and heap rel truncation */
        vacrel->do_index_vacuuming = false;
        vacrel->do_index_cleanup = false;
        vacrel->do_rel_truncate = false;
 
        /* Reset the progress counters */
        pgstat_progress_update_multi_param(2, progress_index, progress_val);
 
        ereport(WARNING,
                (errmsg("bypassing nonessential maintenance of table \"%s.%s.%s\" as a failsafe after %d index scans",
                        vacrel->dbname, vacrel->relnamespace, vacrel->relname,
                        vacrel->num_index_scans),
                 errdetail("The table's relfrozenxid or relminmxid is too far in the past."),
                 errhint("Consider increasing configuration parameter maintenance_work_mem or autovacuum_work_mem.\n"
                         "You might also need to consider other ways for VACUUM to keep up with the allocation of transaction IDs.")));
 
        /* Stop applying cost limits from this point on */
        VacuumCostActive = false;
        VacuumCostBalance = 0;
 
        return true;
    }
 
    return false;
}
 
/*
 *  lazy_cleanup_all_indexes() -- cleanup all indexes of relation.
 */
static void
lazy_cleanup_all_indexes(LVRelState *vacrel)
{
    double      reltuples = vacrel->new_rel_tuples;
    bool        estimated_count = vacrel->scanned_pages < vacrel->rel_pages;
    const int   progress_start_index[] = {
        PROGRESS_VACUUM_PHASE,
        PROGRESS_VACUUM_INDEXES_TOTAL
    };
    const int   progress_end_index[] = {
        PROGRESS_VACUUM_INDEXES_TOTAL,
        PROGRESS_VACUUM_INDEXES_PROCESSED
    };
    int64       progress_start_val[2];
    int64       progress_end_val[2] = {0, 0};
 
    Assert(vacrel->do_index_cleanup);
    Assert(vacrel->nindexes > 0);
 
    /*
     * Report that we are now cleaning up indexes and the number of indexes to
     * cleanup.
     */
    progress_start_val[0] = PROGRESS_VACUUM_PHASE_INDEX_CLEANUP;
    progress_start_val[1] = vacrel->nindexes;
    pgstat_progress_update_multi_param(2, progress_start_index, progress_start_val);
 
    if (!ParallelVacuumIsActive(vacrel))
    {
        for (int idx = 0; idx < vacrel->nindexes; idx++)
        {
            Relation    indrel = vacrel->indrels[idx];
            IndexBulkDeleteResult *istat = vacrel->indstats[idx];
 
            vacrel->indstats[idx] =
                lazy_cleanup_one_index(indrel, istat, reltuples,
                                       estimated_count, vacrel);
 
            /* Report the number of indexes cleaned up */
            pgstat_progress_update_param(PROGRESS_VACUUM_INDEXES_PROCESSED,
                                         idx + 1);
        }
    }
    else
    {
        /* Outsource everything to parallel variant */
        parallel_vacuum_cleanup_all_indexes(vacrel->pvs, reltuples,
                                            vacrel->num_index_scans,
                                            estimated_count);
    }
 
    /* Reset the progress counters */
    pgstat_progress_update_multi_param(2, progress_end_index, progress_end_val);
}
 
/*
 *  lazy_vacuum_one_index() -- vacuum index relation.
 *
 *      Delete all the index tuples containing a TID collected in
 *      vacrel->dead_items array.  Also update running statistics.
 *      Exact details depend on index AM's ambulkdelete routine.
 *
 *      reltuples is the number of heap tuples to be passed to the
 *      bulkdelete callback.  It's always assumed to be estimated.
 *      See indexam.sgml for more info.
 *
 * Returns bulk delete stats derived from input stats
 */
static IndexBulkDeleteResult *
lazy_vacuum_one_index(Relation indrel, IndexBulkDeleteResult *istat,
                      double reltuples, LVRelState *vacrel)
{
    IndexVacuumInfo ivinfo;
    LVSavedErrInfo saved_err_info;
 
    ivinfo.index = indrel;
    ivinfo.heaprel = vacrel->rel;
    ivinfo.analyze_only = false;
    ivinfo.report_progress = false;
    ivinfo.estimated_count = true;
    ivinfo.message_level = DEBUG2;
    ivinfo.num_heap_tuples = reltuples;
    ivinfo.strategy = vacrel->bstrategy;
 
    /*
     * Update error traceback information.
     *
     * The index name is saved during this phase and restored immediately
     * after this phase.  See vacuum_error_callback.
     */
    Assert(vacrel->indname == NULL);
    vacrel->indname = pstrdup(RelationGetRelationName(indrel));
    update_vacuum_error_info(vacrel, &saved_err_info,
                             VACUUM_ERRCB_PHASE_VACUUM_INDEX,
                             InvalidBlockNumber, InvalidOffsetNumber);
 
    /* Do bulk deletion */
    istat = vac_bulkdel_one_index(&ivinfo, istat, (void *) vacrel->dead_items);
 
    /* Revert to the previous phase information for error traceback */
    restore_vacuum_error_info(vacrel, &saved_err_info);
    pfree(vacrel->indname);
    vacrel->indname = NULL;
 
    return istat;
}
 
/*
 *  lazy_cleanup_one_index() -- do post-vacuum cleanup for index relation.
 *
 *      Calls index AM's amvacuumcleanup routine.  reltuples is the number
 *      of heap tuples and estimated_count is true if reltuples is an
 *      estimated value.  See indexam.sgml for more info.
 *
 * Returns bulk delete stats derived from input stats
 */
static IndexBulkDeleteResult *
lazy_cleanup_one_index(Relation indrel, IndexBulkDeleteResult *istat,
                       double reltuples, bool estimated_count,
                       LVRelState *vacrel)
{
    IndexVacuumInfo ivinfo;
    LVSavedErrInfo saved_err_info;
 
    ivinfo.index = indrel;
    ivinfo.heaprel = vacrel->rel;
    ivinfo.analyze_only = false;
    ivinfo.report_progress = false;
    ivinfo.estimated_count = estimated_count;
    ivinfo.message_level = DEBUG2;
 
    ivinfo.num_heap_tuples = reltuples;
    ivinfo.strategy = vacrel->bstrategy;
 
    /*
     * Update error traceback information.
     *
     * The index name is saved during this phase and restored immediately
     * after this phase.  See vacuum_error_callback.
     */
    Assert(vacrel->indname == NULL);
    vacrel->indname = pstrdup(RelationGetRelationName(indrel));
    update_vacuum_error_info(vacrel, &saved_err_info,
                             VACUUM_ERRCB_PHASE_INDEX_CLEANUP,
                             InvalidBlockNumber, InvalidOffsetNumber);
 
    istat = vac_cleanup_one_index(&ivinfo, istat);
 
    /* Revert to the previous phase information for error traceback */
    restore_vacuum_error_info(vacrel, &saved_err_info);
    pfree(vacrel->indname);
    vacrel->indname = NULL;
 
    return istat;
}
 
/*
 * should_attempt_truncation - should we attempt to truncate the heap?
 *
 * Don't even think about it unless we have a shot at releasing a goodly
 * number of pages.  Otherwise, the time taken isn't worth it, mainly because
 * an AccessExclusive lock must be replayed on any hot standby, where it can
 * be particularly disruptive.
 *
 * Also don't attempt it if wraparound failsafe is in effect.  The entire
 * system might be refusing to allocate new XIDs at this point.  The system
 * definitely won't return to normal unless and until VACUUM actually advances
 * the oldest relfrozenxid -- which hasn't happened for target rel just yet.
 * If lazy_truncate_heap attempted to acquire an AccessExclusiveLock to
 * truncate the table under these circumstances, an XID exhaustion error might
 * make it impossible for VACUUM to fix the underlying XID exhaustion problem.
 * There is very little chance of truncation working out when the failsafe is
 * in effect in any case.  lazy_scan_prune makes the optimistic assumption
 * that any LP_DEAD items it encounters will always be LP_UNUSED by the time
 * we're called.
 */
static bool
should_attempt_truncation(LVRelState *vacrel)
{
    BlockNumber possibly_freeable;
 
    if (!vacrel->do_rel_truncate || VacuumFailsafeActive)
        return false;
 
    possibly_freeable = vacrel->rel_pages - vacrel->nonempty_pages;
    if (possibly_freeable > 0 &&
        (possibly_freeable >= REL_TRUNCATE_MINIMUM ||
         possibly_freeable >= vacrel->rel_pages / REL_TRUNCATE_FRACTION))
        return true;
 
    return false;
}
 
/*
 * lazy_truncate_heap - try to truncate off any empty pages at the end
 */
static void
lazy_truncate_heap(LVRelState *vacrel)
{
    BlockNumber orig_rel_pages = vacrel->rel_pages;
    BlockNumber new_rel_pages;
    bool        lock_waiter_detected;
    int         lock_retry;
 
    /* Report that we are now truncating */
    pgstat_progress_update_param(PROGRESS_VACUUM_PHASE,
                                 PROGRESS_VACUUM_PHASE_TRUNCATE);
 
    /* Update error traceback information one last time */
    update_vacuum_error_info(vacrel, NULL, VACUUM_ERRCB_PHASE_TRUNCATE,
                             vacrel->nonempty_pages, InvalidOffsetNumber);
 
    /*
     * Loop until no more truncating can be done.
     */
    do
    {
        /*
         * We need full exclusive lock on the relation in order to do
         * truncation. If we can't get it, give up rather than waiting --- we
         * don't want to block other backends, and we don't want to deadlock
         * (which is quite possible considering we already hold a lower-grade
         * lock).
         */
        lock_waiter_detected = false;
        lock_retry = 0;
        while (true)
        {
            if (ConditionalLockRelation(vacrel->rel, AccessExclusiveLock))
                break;
 
            /*
             * Check for interrupts while trying to (re-)acquire the exclusive
             * lock.
             */
            CHECK_FOR_INTERRUPTS();
 
            if (++lock_retry > (VACUUM_TRUNCATE_LOCK_TIMEOUT /
                                VACUUM_TRUNCATE_LOCK_WAIT_INTERVAL))
            {
                /*
                 * We failed to establish the lock in the specified number of
                 * retries. This means we give up truncating.
                 */
                ereport(vacrel->verbose ? INFO : DEBUG2,
                        (errmsg("\"%s\": stopping truncate due to conflicting lock request",
                                vacrel->relname)));
                return;
            }
 
            (void) WaitLatch(MyLatch,
                             WL_LATCH_SET | WL_TIMEOUT | WL_EXIT_ON_PM_DEATH,
                             VACUUM_TRUNCATE_LOCK_WAIT_INTERVAL,
                             WAIT_EVENT_VACUUM_TRUNCATE);
            ResetLatch(MyLatch);
        }
 
        /*
         * Now that we have exclusive lock, look to see if the rel has grown
         * whilst we were vacuuming with non-exclusive lock.  If so, give up;
         * the newly added pages presumably contain non-deletable tuples.
         */
        new_rel_pages = RelationGetNumberOfBlocks(vacrel->rel);
        if (new_rel_pages != orig_rel_pages)
        {
            /*
             * Note: we intentionally don't update vacrel->rel_pages with the
             * new rel size here.  If we did, it would amount to assuming that
             * the new pages are empty, which is unlikely. Leaving the numbers
             * alone amounts to assuming that the new pages have the same
             * tuple density as existing ones, which is less unlikely.
             */
            UnlockRelation(vacrel->rel, AccessExclusiveLock);
            return;
        }
 
        /*
         * Scan backwards from the end to verify that the end pages actually
         * contain no tuples.  This is *necessary*, not optional, because
         * other backends could have added tuples to these pages whilst we
         * were vacuuming.
         */
        new_rel_pages = count_nondeletable_pages(vacrel, &lock_waiter_detected);
        vacrel->blkno = new_rel_pages;
 
        if (new_rel_pages >= orig_rel_pages)
        {
            /* can't do anything after all */
            UnlockRelation(vacrel->rel, AccessExclusiveLock);
            return;
        }
 
        /*
         * Okay to truncate.
         */
        RelationTruncate(vacrel->rel, new_rel_pages);
 
        /*
         * We can release the exclusive lock as soon as we have truncated.
         * Other backends can't safely access the relation until they have
         * processed the smgr invalidation that smgrtruncate sent out ... but
         * that should happen as part of standard invalidation processing once
         * they acquire lock on the relation.
         */
        UnlockRelation(vacrel->rel, AccessExclusiveLock);
 
        /*
         * Update statistics.  Here, it *is* correct to adjust rel_pages
         * without also touching reltuples, since the tuple count wasn't
         * changed by the truncation.
         */
        vacrel->removed_pages += orig_rel_pages - new_rel_pages;
        vacrel->rel_pages = new_rel_pages;
 
        ereport(vacrel->verbose ? INFO : DEBUG2,
                (errmsg("table \"%s\": truncated %u to %u pages",
                        vacrel->relname,
                        orig_rel_pages, new_rel_pages)));
        orig_rel_pages = new_rel_pages;
    } while (new_rel_pages > vacrel->nonempty_pages && lock_waiter_detected);
}
 
/*
 * Rescan end pages to verify that they are (still) empty of tuples.
 *
 * Returns number of nondeletable pages (last nonempty page + 1).
 */
static BlockNumber
count_nondeletable_pages(LVRelState *vacrel, bool *lock_waiter_detected)
{
    BlockNumber blkno;
    BlockNumber prefetchedUntil;
    instr_time  starttime;
 
    /* Initialize the starttime if we check for conflicting lock requests */
    INSTR_TIME_SET_CURRENT(starttime);
 
    /*
     * Start checking blocks at what we believe relation end to be and move
     * backwards.  (Strange coding of loop control is needed because blkno is
     * unsigned.)  To make the scan faster, we prefetch a few blocks at a time
     * in forward direction, so that OS-level readahead can kick in.
     */
    blkno = vacrel->rel_pages;
    StaticAssertStmt((PREFETCH_SIZE & (PREFETCH_SIZE - 1)) == 0,
                     "prefetch size must be power of 2");
    prefetchedUntil = InvalidBlockNumber;
    while (blkno > vacrel->nonempty_pages)
    {
        Buffer      buf;
        Page        page;
        OffsetNumber offnum,
                    maxoff;
        bool        hastup;
 
        /*
         * Check if another process requests a lock on our relation. We are
         * holding an AccessExclusiveLock here, so they will be waiting. We
         * only do this once per VACUUM_TRUNCATE_LOCK_CHECK_INTERVAL, and we
         * only check if that interval has elapsed once every 32 blocks to
         * keep the number of system calls and actual shared lock table
         * lookups to a minimum.
         */
        if ((blkno % 32) == 0)
        {
            instr_time  currenttime;
            instr_time  elapsed;
 
            INSTR_TIME_SET_CURRENT(currenttime);
            elapsed = currenttime;
            INSTR_TIME_SUBTRACT(elapsed, starttime);
            if ((INSTR_TIME_GET_MICROSEC(elapsed) / 1000)
                >= VACUUM_TRUNCATE_LOCK_CHECK_INTERVAL)
            {
                if (LockHasWaitersRelation(vacrel->rel, AccessExclusiveLock))
                {
                    ereport(vacrel->verbose ? INFO : DEBUG2,
                            (errmsg("table \"%s\": suspending truncate due to conflicting lock request",
                                    vacrel->relname)));
 
                    *lock_waiter_detected = true;
                    return blkno;
                }
                starttime = currenttime;
            }
        }
 
        /*
         * We don't insert a vacuum delay point here, because we have an
         * exclusive lock on the table which we want to hold for as short a
         * time as possible.  We still need to check for interrupts however.
         */
        CHECK_FOR_INTERRUPTS();
 
        blkno--;
 
        /* If we haven't prefetched this lot yet, do so now. */
        if (prefetchedUntil > blkno)
        {
            BlockNumber prefetchStart;
            BlockNumber pblkno;
 
            prefetchStart = blkno & ~(PREFETCH_SIZE - 1);
            for (pblkno = prefetchStart; pblkno <= blkno; pblkno++)
            {
                PrefetchBuffer(vacrel->rel, MAIN_FORKNUM, pblkno);
                CHECK_FOR_INTERRUPTS();
            }
            prefetchedUntil = prefetchStart;
        }
 
        buf = ReadBufferExtended(vacrel->rel, MAIN_FORKNUM, blkno, RBM_NORMAL,
                                 vacrel->bstrategy);
 
        /* In this phase we only need shared access to the buffer */
        LockBuffer(buf, BUFFER_LOCK_SHARE);
 
        page = BufferGetPage(buf);
 
        if (PageIsNew(page) || PageIsEmpty(page))
        {
            UnlockReleaseBuffer(buf);
            continue;
        }
 
        hastup = false;
        maxoff = PageGetMaxOffsetNumber(page);
        for (offnum = FirstOffsetNumber;
             offnum <= maxoff;
             offnum = OffsetNumberNext(offnum))
        {
            ItemId      itemid;
 
            itemid = PageGetItemId(page, offnum);
 
            /*
             * Note: any non-unused item should be taken as a reason to keep
             * this page.  Even an LP_DEAD item makes truncation unsafe, since
             * we must not have cleaned out its index entries.
             */
            if (ItemIdIsUsed(itemid))
            {
                hastup = true;
                break;          /* can stop scanning */
            }
        }                       /* scan along page */
 
        UnlockReleaseBuffer(buf);
 
        /* Done scanning if we found a tuple here */
        if (hastup)
            return blkno + 1;
    }
 
    /*
     * If we fall out of the loop, all the previously-thought-to-be-empty
     * pages still are; we need not bother to look at the last known-nonempty
     * page.
     */
    return vacrel->nonempty_pages;
}
 
/*
 * Returns the number of dead TIDs that VACUUM should allocate space to
 * store, given a heap rel of size vacrel->rel_pages, and given current
 * maintenance_work_mem setting (or current autovacuum_work_mem setting,
 * when applicable).
 *
 * See the comments at the head of this file for rationale.
 */
static int
dead_items_max_items(LVRelState *vacrel)
{
    int64       max_items;
    int         vac_work_mem = IsAutoVacuumWorkerProcess() &&
        autovacuum_work_mem != -1 ?
        autovacuum_work_mem : maintenance_work_mem;
 
    if (vacrel->nindexes > 0)
    {
        BlockNumber rel_pages = vacrel->rel_pages;
 
        max_items = MAXDEADITEMS(vac_work_mem * 1024L);
        max_items = Min(max_items, INT_MAX);
        max_items = Min(max_items, MAXDEADITEMS(MaxAllocSize));
 
        /* curious coding here to ensure the multiplication can't overflow */
        if ((BlockNumber) (max_items / MaxHeapTuplesPerPage) > rel_pages)
            max_items = rel_pages * MaxHeapTuplesPerPage;
 
        /* stay sane if small maintenance_work_mem */
        max_items = Max(max_items, MaxHeapTuplesPerPage);
    }
    else
    {
        /* One-pass case only stores a single heap page's TIDs at a time */
        max_items = MaxHeapTuplesPerPage;
    }
 
    return (int) max_items;
}
 
/*
 * Allocate dead_items (either using palloc, or in dynamic shared memory).
 * Sets dead_items in vacrel for caller.
 *
 * Also handles parallel initialization as part of allocating dead_items in
 * DSM when required.
 */
static void
dead_items_alloc(LVRelState *vacrel, int nworkers)
{
    VacDeadItems *dead_items;
    int         max_items;
 
    max_items = dead_items_max_items(vacrel);
    Assert(max_items >= MaxHeapTuplesPerPage);
 
    /*
     * Initialize state for a parallel vacuum.  As of now, only one worker can
     * be used for an index, so we invoke parallelism only if there are at
     * least two indexes on a table.
     */
    if (nworkers >= 0 && vacrel->nindexes > 1 && vacrel->do_index_vacuuming)
    {
        /*
         * Since parallel workers cannot access data in temporary tables, we
         * can't perform parallel vacuum on them.
         */
        if (RelationUsesLocalBuffers(vacrel->rel))
        {
            /*
             * Give warning only if the user explicitly tries to perform a
             * parallel vacuum on the temporary table.
             */
            if (nworkers > 0)
                ereport(WARNING,
                        (errmsg("disabling parallel option of vacuum on \"%s\" --- cannot vacuum temporary tables in parallel",
                                vacrel->relname)));
        }
        else
            vacrel->pvs = parallel_vacuum_init(vacrel->rel, vacrel->indrels,
                                               vacrel->nindexes, nworkers,
                                               max_items,
                                               vacrel->verbose ? INFO : DEBUG2,
                                               vacrel->bstrategy);
 
        /* If parallel mode started, dead_items space is allocated in DSM */
        if (ParallelVacuumIsActive(vacrel))
        {
            vacrel->dead_items = parallel_vacuum_get_dead_items(vacrel->pvs);
            return;
        }
    }
 
    /* Serial VACUUM case */
    dead_items = (VacDeadItems *) palloc(vac_max_items_to_alloc_size(max_items));
    dead_items->max_items = max_items;
    dead_items->num_items = 0;
 
    vacrel->dead_items = dead_items;
}
 
/*
 * Perform cleanup for resources allocated in dead_items_alloc
 */
static void
dead_items_cleanup(LVRelState *vacrel)
{
    if (!ParallelVacuumIsActive(vacrel))
    {
        /* Don't bother with pfree here */
        return;
    }
 
    /* End parallel mode */
    parallel_vacuum_end(vacrel->pvs, vacrel->indstats);
    vacrel->pvs = NULL;
}
 
/*
 * Check if every tuple in the given page is visible to all current and future
 * transactions. Also return the visibility_cutoff_xid which is the highest
 * xmin amongst the visible tuples.  Set *all_frozen to true if every tuple
 * on this page is frozen.
 *
 * This is a stripped down version of lazy_scan_prune().  If you change
 * anything here, make sure that everything stays in sync.  Note that an
 * assertion calls us to verify that everybody still agrees.  Be sure to avoid
 * introducing new side-effects here.
 */
static bool
heap_page_is_all_visible(LVRelState *vacrel, Buffer buf,
                         TransactionId *visibility_cutoff_xid,
                         bool *all_frozen)
{
    Page        page = BufferGetPage(buf);
    BlockNumber blockno = BufferGetBlockNumber(buf);
    OffsetNumber offnum,
                maxoff;
    bool        all_visible = true;
 
    *visibility_cutoff_xid = InvalidTransactionId;
    *all_frozen = true;
 
    maxoff = PageGetMaxOffsetNumber(page);
    for (offnum = FirstOffsetNumber;
         offnum <= maxoff && all_visible;
         offnum = OffsetNumberNext(offnum))
    {
        ItemId      itemid;
        HeapTupleData tuple;
 
        /*
         * Set the offset number so that we can display it along with any
         * error that occurred while processing this tuple.
         */
        vacrel->offnum = offnum;
        itemid = PageGetItemId(page, offnum);
 
        /* Unused or redirect line pointers are of no interest */
        if (!ItemIdIsUsed(itemid) || ItemIdIsRedirected(itemid))
            continue;
 
        ItemPointerSet(&(tuple.t_self), blockno, offnum);
 
        /*
         * Dead line pointers can have index pointers pointing to them. So
         * they can't be treated as visible
         */
        if (ItemIdIsDead(itemid))
        {
            all_visible = false;
            *all_frozen = false;
            break;
        }
 
        Assert(ItemIdIsNormal(itemid));
 
        tuple.t_data = (HeapTupleHeader) PageGetItem(page, itemid);
        tuple.t_len = ItemIdGetLength(itemid);
        tuple.t_tableOid = RelationGetRelid(vacrel->rel);
 
        switch (HeapTupleSatisfiesVacuum(&tuple, vacrel->cutoffs.OldestXmin,
                                         buf))
        {
            case HEAPTUPLE_LIVE:
                {
                    TransactionId xmin;
 
                    /* Check comments in lazy_scan_prune. */
                    if (!HeapTupleHeaderXminCommitted(tuple.t_data))
                    {
                        all_visible = false;
                        *all_frozen = false;
                        break;
                    }
 
                    /*
                     * The inserter definitely committed. But is it old enough
                     * that everyone sees it as committed?
                     */
                    xmin = HeapTupleHeaderGetXmin(tuple.t_data);
                    if (!TransactionIdPrecedes(xmin,
                                               vacrel->cutoffs.OldestXmin))
                    {
                        all_visible = false;
                        *all_frozen = false;
                        break;
                    }
 
                    /* Track newest xmin on page. */
                    if (TransactionIdFollows(xmin, *visibility_cutoff_xid) &&
                        TransactionIdIsNormal(xmin))
                        *visibility_cutoff_xid = xmin;
 
                    /* Check whether this tuple is already frozen or not */
                    if (all_visible && *all_frozen &&
                        heap_tuple_needs_eventual_freeze(tuple.t_data))
                        *all_frozen = false;
                }
                break;
 
            case HEAPTUPLE_DEAD:
            case HEAPTUPLE_RECENTLY_DEAD:
            case HEAPTUPLE_INSERT_IN_PROGRESS:
            case HEAPTUPLE_DELETE_IN_PROGRESS:
                {
                    all_visible = false;
                    *all_frozen = false;
                    break;
                }
            default:
                elog(ERROR, "unexpected HeapTupleSatisfiesVacuum result");
                break;
        }
    }                           /* scan along page */
 
    /* Clear the offset information once we have processed the given page. */
    vacrel->offnum = InvalidOffsetNumber;
 
    return all_visible;
}
 
/*
 * Update index statistics in pg_class if the statistics are accurate.
 */
static void
update_relstats_all_indexes(LVRelState *vacrel)
{
    Relation   *indrels = vacrel->indrels;
    int         nindexes = vacrel->nindexes;
    IndexBulkDeleteResult **indstats = vacrel->indstats;
 
    Assert(vacrel->do_index_cleanup);
 
    for (int idx = 0; idx < nindexes; idx++)
    {
        Relation    indrel = indrels[idx];
        IndexBulkDeleteResult *istat = indstats[idx];
 
        if (istat == NULL || istat->estimated_count)
            continue;
 
        /* Update index statistics */
        vac_update_relstats(indrel,
                            istat->num_pages,
                            istat->num_index_tuples,
                            0,
                            false,
                            InvalidTransactionId,
                            InvalidMultiXactId,
                            NULL, NULL, false);
    }
}
 
/*
 * Error context callback for errors occurring during vacuum.  The error
 * context messages for index phases should match the messages set in parallel
 * vacuum.  If you change this function for those phases, change
 * parallel_vacuum_error_callback() as well.
 */
static void
vacuum_error_callback(void *arg)
{
    LVRelState *errinfo = arg;
 
    switch (errinfo->phase)
    {
        case VACUUM_ERRCB_PHASE_SCAN_HEAP:
            if (BlockNumberIsValid(errinfo->blkno))
            {
                if (OffsetNumberIsValid(errinfo->offnum))
                    errcontext("while scanning block %u offset %u of relation \"%s.%s\"",
                               errinfo->blkno, errinfo->offnum, errinfo->relnamespace, errinfo->relname);
                else
                    errcontext("while scanning block %u of relation \"%s.%s\"",
                               errinfo->blkno, errinfo->relnamespace, errinfo->relname);
            }
            else
                errcontext("while scanning relation \"%s.%s\"",
                           errinfo->relnamespace, errinfo->relname);
            break;
 
        case VACUUM_ERRCB_PHASE_VACUUM_HEAP:
            if (BlockNumberIsValid(errinfo->blkno))
            {
                if (OffsetNumberIsValid(errinfo->offnum))
                    errcontext("while vacuuming block %u offset %u of relation \"%s.%s\"",
                               errinfo->blkno, errinfo->offnum, errinfo->relnamespace, errinfo->relname);
                else
                    errcontext("while vacuuming block %u of relation \"%s.%s\"",
                               errinfo->blkno, errinfo->relnamespace, errinfo->relname);
            }
            else
                errcontext("while vacuuming relation \"%s.%s\"",
                           errinfo->relnamespace, errinfo->relname);
            break;
 
        case VACUUM_ERRCB_PHASE_VACUUM_INDEX:
            errcontext("while vacuuming index \"%s\" of relation \"%s.%s\"",
                       errinfo->indname, errinfo->relnamespace, errinfo->relname);
            break;
 
        case VACUUM_ERRCB_PHASE_INDEX_CLEANUP:
            errcontext("while cleaning up index \"%s\" of relation \"%s.%s\"",
                       errinfo->indname, errinfo->relnamespace, errinfo->relname);
            break;
 
        case VACUUM_ERRCB_PHASE_TRUNCATE:
            if (BlockNumberIsValid(errinfo->blkno))
                errcontext("while truncating relation \"%s.%s\" to %u blocks",
                           errinfo->relnamespace, errinfo->relname, errinfo->blkno);
            break;
 
        case VACUUM_ERRCB_PHASE_UNKNOWN:
        default:
            return;             /* do nothing; the errinfo may not be
                                 * initialized */
    }
}
 
/*
 * Updates the information required for vacuum error callback.  This also saves
 * the current information which can be later restored via restore_vacuum_error_info.
 */
static void
update_vacuum_error_info(LVRelState *vacrel, LVSavedErrInfo *saved_vacrel,
                         int phase, BlockNumber blkno, OffsetNumber offnum)
{
    if (saved_vacrel)
    {
        saved_vacrel->offnum = vacrel->offnum;
        saved_vacrel->blkno = vacrel->blkno;
        saved_vacrel->phase = vacrel->phase;
    }
 
    vacrel->blkno = blkno;
    vacrel->offnum = offnum;
    vacrel->phase = phase;
}
 
/*
 * Restores the vacuum information saved via a prior call to update_vacuum_error_info.
 */
static void
restore_vacuum_error_info(LVRelState *vacrel,
                          const LVSavedErrInfo *saved_vacrel)
{
    vacrel->blkno = saved_vacrel->blkno;
    vacrel->offnum = saved_vacrel->offnum;
    vacrel->phase = saved_vacrel->phase;
}