verify_nbtree.c

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/*-------------------------------------------------------------------------
 *
 * verify_nbtree.c
 *      Verifies the integrity of nbtree indexes based on invariants.
 *
 * For B-Tree indexes, verification includes checking that each page in the
 * target index has items in logical order as reported by an insertion scankey
 * (the insertion scankey sort-wise NULL semantics are needed for
 * verification).
 *
 * When index-to-heap verification is requested, a Bloom filter is used to
 * fingerprint all tuples in the target index, as the index is traversed to
 * verify its structure.  A heap scan later uses Bloom filter probes to verify
 * that every visible heap tuple has a matching index tuple.
 *
 *
 * Copyright (c) 2017-2020, PostgreSQL Global Development Group
 *
 * IDENTIFICATION
 *    contrib/amcheck/verify_nbtree.c
 *
 *-------------------------------------------------------------------------
 */
#include "postgres.h"

#include "access/htup_details.h"
#include "access/nbtree.h"
#include "access/table.h"
#include "access/tableam.h"
#include "access/transam.h"
#include "access/xact.h"
#include "catalog/index.h"
#include "catalog/pg_am.h"
#include "commands/tablecmds.h"
#include "lib/bloomfilter.h"
#include "miscadmin.h"
#include "storage/lmgr.h"
#include "storage/smgr.h"
#include "utils/memutils.h"
#include "utils/snapmgr.h"


PG_MODULE_MAGIC;

/*
 * A B-Tree cannot possibly have this many levels, since there must be one
 * block per level, which is bound by the range of BlockNumber:
 */
#define InvalidBtreeLevel   ((uint32) InvalidBlockNumber)
#define BTreeTupleGetNKeyAtts(itup, rel)   \
    Min(IndexRelationGetNumberOfKeyAttributes(rel), BTreeTupleGetNAtts(itup, rel))

/*
 * State associated with verifying a B-Tree index
 *
 * target is the point of reference for a verification operation.
 *
 * Other B-Tree pages may be allocated, but those are always auxiliary (e.g.,
 * they are current target's child pages).  Conceptually, problems are only
 * ever found in the current target page (or for a particular heap tuple during
 * heapallindexed verification).  Each page found by verification's left/right,
 * top/bottom scan becomes the target exactly once.
 */
typedef struct BtreeCheckState
{
    /*
     * Unchanging state, established at start of verification:
     */

    /* B-Tree Index Relation and associated heap relation */
    Relation    rel;
    Relation    heaprel;
    /* rel is heapkeyspace index? */
    bool        heapkeyspace;
    /* ShareLock held on heap/index, rather than AccessShareLock? */
    bool        readonly;
    /* Also verifying heap has no unindexed tuples? */
    bool        heapallindexed;
    /* Also making sure non-pivot tuples can be found by new search? */
    bool        rootdescend;
    /* Per-page context */
    MemoryContext targetcontext;
    /* Buffer access strategy */
    BufferAccessStrategy checkstrategy;

    /*
     * Mutable state, for verification of particular page:
     */

    /* Current target page */
    Page        target;
    /* Target block number */
    BlockNumber targetblock;
    /* Target page's LSN */
    XLogRecPtr  targetlsn;

    /*
     * Mutable state, for optional heapallindexed verification:
     */

    /* Bloom filter fingerprints B-Tree index */
    bloom_filter *filter;
    /* Bloom filter fingerprints downlink blocks within tree */
    bloom_filter *downlinkfilter;
    /* Right half of incomplete split marker */
    bool        rightsplit;
    /* Debug counter */
    int64       heaptuplespresent;
} BtreeCheckState;

/*
 * Starting point for verifying an entire B-Tree index level
 */
typedef struct BtreeLevel
{
    /* Level number (0 is leaf page level). */
    uint32      level;

    /* Left most block on level.  Scan of level begins here. */
    BlockNumber leftmost;

    /* Is this level reported as "true" root level by meta page? */
    bool        istruerootlevel;
} BtreeLevel;

PG_FUNCTION_INFO_V1(bt_index_check);
PG_FUNCTION_INFO_V1(bt_index_parent_check);

static void bt_index_check_internal(Oid indrelid, bool parentcheck,
                                    bool heapallindexed, bool rootdescend);
static inline void btree_index_checkable(Relation rel);
static inline bool btree_index_mainfork_expected(Relation rel);
static void bt_check_every_level(Relation rel, Relation heaprel,
                                 bool heapkeyspace, bool readonly, bool heapallindexed,
                                 bool rootdescend);
static BtreeLevel bt_check_level_from_leftmost(BtreeCheckState *state,
                                               BtreeLevel level);
static void bt_target_page_check(BtreeCheckState *state);
static BTScanInsert bt_right_page_check_scankey(BtreeCheckState *state);
static void bt_downlink_check(BtreeCheckState *state, BTScanInsert targetkey,
                              BlockNumber childblock);
static void bt_downlink_missing_check(BtreeCheckState *state);
static void bt_tuple_present_callback(Relation index, ItemPointer tid,
                                      Datum *values, bool *isnull,
                                      bool tupleIsAlive, void *checkstate);
static IndexTuple bt_normalize_tuple(BtreeCheckState *state,
                                     IndexTuple itup);
static bool bt_rootdescend(BtreeCheckState *state, IndexTuple itup);
static inline bool offset_is_negative_infinity(BTPageOpaque opaque,
                                               OffsetNumber offset);
static inline bool invariant_l_offset(BtreeCheckState *state, BTScanInsert key,
                                      OffsetNumber upperbound);
static inline bool invariant_leq_offset(BtreeCheckState *state,
                                        BTScanInsert key,
                                        OffsetNumber upperbound);
static inline bool invariant_g_offset(BtreeCheckState *state, BTScanInsert key,
                                      OffsetNumber lowerbound);
static inline bool invariant_l_nontarget_offset(BtreeCheckState *state,
                                                BTScanInsert key,
                                                BlockNumber nontargetblock,
                                                Page nontarget,
                                                OffsetNumber upperbound);
static Page palloc_btree_page(BtreeCheckState *state, BlockNumber blocknum);
static inline BTScanInsert bt_mkscankey_pivotsearch(Relation rel,
                                                    IndexTuple itup);
static ItemId PageGetItemIdCareful(BtreeCheckState *state, BlockNumber block,
                                   Page page, OffsetNumber offset);
static inline ItemPointer BTreeTupleGetHeapTIDCareful(BtreeCheckState *state,
                                                      IndexTuple itup, bool nonpivot);

/*
 * bt_index_check(index regclass, heapallindexed boolean)
 *
 * Verify integrity of B-Tree index.
 *
 * Acquires AccessShareLock on heap & index relations.  Does not consider
 * invariants that exist between parent/child pages.  Optionally verifies
 * that heap does not contain any unindexed or incorrectly indexed tuples.
 */
Datum
bt_index_check(PG_FUNCTION_ARGS)
{
    Oid         indrelid = PG_GETARG_OID(0);
    bool        heapallindexed = false;

    if (PG_NARGS() == 2)
        heapallindexed = PG_GETARG_BOOL(1);

    bt_index_check_internal(indrelid, false, heapallindexed, false);

    PG_RETURN_VOID();
}

/*
 * bt_index_parent_check(index regclass, heapallindexed boolean)
 *
 * Verify integrity of B-Tree index.
 *
 * Acquires ShareLock on heap & index relations.  Verifies that downlinks in
 * parent pages are valid lower bounds on child pages.  Optionally verifies
 * that heap does not contain any unindexed or incorrectly indexed tuples.
 */
Datum
bt_index_parent_check(PG_FUNCTION_ARGS)
{
    Oid         indrelid = PG_GETARG_OID(0);
    bool        heapallindexed = false;
    bool        rootdescend = false;

    if (PG_NARGS() >= 2)
        heapallindexed = PG_GETARG_BOOL(1);
    if (PG_NARGS() == 3)
        rootdescend = PG_GETARG_BOOL(2);

    bt_index_check_internal(indrelid, true, heapallindexed, rootdescend);

    PG_RETURN_VOID();
}

/*
 * Helper for bt_index_[parent_]check, coordinating the bulk of the work.
 */
static void
bt_index_check_internal(Oid indrelid, bool parentcheck, bool heapallindexed,
                        bool rootdescend)
{
    Oid         heapid;
    Relation    indrel;
    Relation    heaprel;
    LOCKMODE    lockmode;

    if (parentcheck)
        lockmode = ShareLock;
    else
        lockmode = AccessShareLock;

    /*
     * We must lock table before index to avoid deadlocks.  However, if the
     * passed indrelid isn't an index then IndexGetRelation() will fail.
     * Rather than emitting a not-very-helpful error message, postpone
     * complaining, expecting that the is-it-an-index test below will fail.
     *
     * In hot standby mode this will raise an error when parentcheck is true.
     */
    heapid = IndexGetRelation(indrelid, true);
    if (OidIsValid(heapid))
        heaprel = table_open(heapid, lockmode);
    else
        heaprel = NULL;

    /*
     * Open the target index relations separately (like relation_openrv(), but
     * with heap relation locked first to prevent deadlocking).  In hot
     * standby mode this will raise an error when parentcheck is true.
     *
     * There is no need for the usual indcheckxmin usability horizon test
     * here, even in the heapallindexed case, because index undergoing
     * verification only needs to have entries for a new transaction snapshot.
     * (If this is a parentcheck verification, there is no question about
     * committed or recently dead heap tuples lacking index entries due to
     * concurrent activity.)
     */
    indrel = index_open(indrelid, lockmode);

    /*
     * Since we did the IndexGetRelation call above without any lock, it's
     * barely possible that a race against an index drop/recreation could have
     * netted us the wrong table.
     */
    if (heaprel == NULL || heapid != IndexGetRelation(indrelid, false))
        ereport(ERROR,
                (errcode(ERRCODE_UNDEFINED_TABLE),
                 errmsg("could not open parent table of index %s",
                        RelationGetRelationName(indrel))));

    /* Relation suitable for checking as B-Tree? */
    btree_index_checkable(indrel);

    if (btree_index_mainfork_expected(indrel))
    {
        bool    heapkeyspace;

        RelationOpenSmgr(indrel);
        if (!smgrexists(indrel->rd_smgr, MAIN_FORKNUM))
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("index \"%s\" lacks a main relation fork",
                            RelationGetRelationName(indrel))));

        /* Check index, possibly against table it is an index on */
        heapkeyspace = _bt_heapkeyspace(indrel);
        bt_check_every_level(indrel, heaprel, heapkeyspace, parentcheck,
                             heapallindexed, rootdescend);
    }

    /*
     * Release locks early. That's ok here because nothing in the called
     * routines will trigger shared cache invalidations to be sent, so we can
     * relax the usual pattern of only releasing locks after commit.
     */
    index_close(indrel, lockmode);
    if (heaprel)
        table_close(heaprel, lockmode);
}

/*
 * Basic checks about the suitability of a relation for checking as a B-Tree
 * index.
 *
 * NB: Intentionally not checking permissions, the function is normally not
 * callable by non-superusers. If granted, it's useful to be able to check a
 * whole cluster.
 */
static inline void
btree_index_checkable(Relation rel)
{
    if (rel->rd_rel->relkind != RELKIND_INDEX ||
        rel->rd_rel->relam != BTREE_AM_OID)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("only B-Tree indexes are supported as targets for verification"),
                 errdetail("Relation \"%s\" is not a B-Tree index.",
                           RelationGetRelationName(rel))));

    if (RELATION_IS_OTHER_TEMP(rel))
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot access temporary tables of other sessions"),
                 errdetail("Index \"%s\" is associated with temporary relation.",
                           RelationGetRelationName(rel))));

    if (!rel->rd_index->indisvalid)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot check index \"%s\"",
                        RelationGetRelationName(rel)),
                 errdetail("Index is not valid.")));
}

/*
 * Check if B-Tree index relation should have a file for its main relation
 * fork.  Verification uses this to skip unlogged indexes when in hot standby
 * mode, where there is simply nothing to verify.
 *
 * NB: Caller should call btree_index_checkable() before calling here.
 */
static inline bool
btree_index_mainfork_expected(Relation rel)
{
    if (rel->rd_rel->relpersistence != RELPERSISTENCE_UNLOGGED ||
        !RecoveryInProgress())
        return true;

    ereport(NOTICE,
            (errcode(ERRCODE_READ_ONLY_SQL_TRANSACTION),
             errmsg("cannot verify unlogged index \"%s\" during recovery, skipping",
                    RelationGetRelationName(rel))));

    return false;
}

/*
 * Main entry point for B-Tree SQL-callable functions. Walks the B-Tree in
 * logical order, verifying invariants as it goes.  Optionally, verification
 * checks if the heap relation contains any tuples that are not represented in
 * the index but should be.
 *
 * It is the caller's responsibility to acquire appropriate heavyweight lock on
 * the index relation, and advise us if extra checks are safe when a ShareLock
 * is held.  (A lock of the same type must also have been acquired on the heap
 * relation.)
 *
 * A ShareLock is generally assumed to prevent any kind of physical
 * modification to the index structure, including modifications that VACUUM may
 * make.  This does not include setting of the LP_DEAD bit by concurrent index
 * scans, although that is just metadata that is not able to directly affect
 * any check performed here.  Any concurrent process that might act on the
 * LP_DEAD bit being set (recycle space) requires a heavyweight lock that
 * cannot be held while we hold a ShareLock.  (Besides, even if that could
 * happen, the ad-hoc recycling when a page might otherwise split is performed
 * per-page, and requires an exclusive buffer lock, which wouldn't cause us
 * trouble.  _bt_delitems_vacuum() may only delete leaf items, and so the extra
 * parent/child check cannot be affected.)
 */
static void
bt_check_every_level(Relation rel, Relation heaprel, bool heapkeyspace,
                     bool readonly, bool heapallindexed, bool rootdescend)
{
    BtreeCheckState *state;
    Page        metapage;
    BTMetaPageData *metad;
    uint32      previouslevel;
    BtreeLevel  current;
    Snapshot    snapshot = SnapshotAny;

    /*
     * RecentGlobalXmin assertion matches index_getnext_tid().  See note on
     * RecentGlobalXmin/B-Tree page deletion.
     */
    Assert(TransactionIdIsValid(RecentGlobalXmin));

    /*
     * Initialize state for entire verification operation
     */
    state = palloc0(sizeof(BtreeCheckState));
    state->rel = rel;
    state->heaprel = heaprel;
    state->heapkeyspace = heapkeyspace;
    state->readonly = readonly;
    state->heapallindexed = heapallindexed;
    state->rootdescend = rootdescend;

    if (state->heapallindexed)
    {
        int64       total_pages;
        int64       total_elems;
        uint64      seed;

        /*
         * Size Bloom filter based on estimated number of tuples in index,
         * while conservatively assuming that each block must contain at least
         * MaxIndexTuplesPerPage / 5 non-pivot tuples.  (Non-leaf pages cannot
         * contain non-pivot tuples.  That's okay because they generally make
         * up no more than about 1% of all pages in the index.)
         */
        total_pages = RelationGetNumberOfBlocks(rel);
        total_elems = Max(total_pages * (MaxIndexTuplesPerPage / 5),
                          (int64) state->rel->rd_rel->reltuples);
        /* Random seed relies on backend srandom() call to avoid repetition */
        seed = random();
        /* Create Bloom filter to fingerprint index */
        state->filter = bloom_create(total_elems, maintenance_work_mem, seed);
        state->heaptuplespresent = 0;

        /*
         * Register our own snapshot in !readonly case, rather than asking
         * table_index_build_scan() to do this for us later.  This needs to
         * happen before index fingerprinting begins, so we can later be
         * certain that index fingerprinting should have reached all tuples
         * returned by table_index_build_scan().
         *
         * In readonly case, we also check for problems with missing
         * downlinks. A second Bloom filter is used for this.
         */
        if (!state->readonly)
        {
            snapshot = RegisterSnapshot(GetTransactionSnapshot());

            /*
             * GetTransactionSnapshot() always acquires a new MVCC snapshot in
             * READ COMMITTED mode.  A new snapshot is guaranteed to have all
             * the entries it requires in the index.
             *
             * We must defend against the possibility that an old xact
             * snapshot was returned at higher isolation levels when that
             * snapshot is not safe for index scans of the target index.  This
             * is possible when the snapshot sees tuples that are before the
             * index's indcheckxmin horizon.  Throwing an error here should be
             * very rare.  It doesn't seem worth using a secondary snapshot to
             * avoid this.
             */
            if (IsolationUsesXactSnapshot() && rel->rd_index->indcheckxmin &&
                !TransactionIdPrecedes(HeapTupleHeaderGetXmin(rel->rd_indextuple->t_data),
                                       snapshot->xmin))
                ereport(ERROR,
                        (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                         errmsg("index \"%s\" cannot be verified using transaction snapshot",
                                RelationGetRelationName(rel))));
        }
        else
        {
            /*
             * Extra readonly downlink check.
             *
             * In readonly case, we know that there cannot be a concurrent
             * page split or a concurrent page deletion, which gives us the
             * opportunity to verify that every non-ignorable page had a
             * downlink one level up.  We must be tolerant of interrupted page
             * splits and page deletions, though.  This is taken care of in
             * bt_downlink_missing_check().
             */
            state->downlinkfilter = bloom_create(total_pages, work_mem, seed);
        }
    }

    Assert(!state->rootdescend || state->readonly);
    if (state->rootdescend && !state->heapkeyspace)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot verify that tuples from index \"%s\" can each be found by an independent index search",
                        RelationGetRelationName(rel)),
                 errhint("Only B-Tree version 4 indexes support rootdescend verification.")));

    /* Create context for page */
    state->targetcontext = AllocSetContextCreate(CurrentMemoryContext,
                                                 "amcheck context",
                                                 ALLOCSET_DEFAULT_SIZES);
    state->checkstrategy = GetAccessStrategy(BAS_BULKREAD);

    /* Get true root block from meta-page */
    metapage = palloc_btree_page(state, BTREE_METAPAGE);
    metad = BTPageGetMeta(metapage);

    /*
     * Certain deletion patterns can result in "skinny" B-Tree indexes, where
     * the fast root and true root differ.
     *
     * Start from the true root, not the fast root, unlike conventional index
     * scans.  This approach is more thorough, and removes the risk of
     * following a stale fast root from the meta page.
     */
    if (metad->btm_fastroot != metad->btm_root)
        ereport(DEBUG1,
                (errcode(ERRCODE_NO_DATA),
                 errmsg("harmless fast root mismatch in index %s",
                        RelationGetRelationName(rel)),
                 errdetail_internal("Fast root block %u (level %u) differs from true root block %u (level %u).",
                                    metad->btm_fastroot, metad->btm_fastlevel,
                                    metad->btm_root, metad->btm_level)));

    /*
     * Starting at the root, verify every level.  Move left to right, top to
     * bottom.  Note that there may be no pages other than the meta page (meta
     * page can indicate that root is P_NONE when the index is totally empty).
     */
    previouslevel = InvalidBtreeLevel;
    current.level = metad->btm_level;
    current.leftmost = metad->btm_root;
    current.istruerootlevel = true;
    while (current.leftmost != P_NONE)
    {
        /*
         * Leftmost page on level cannot be right half of incomplete split.
         * This can go stale immediately in !readonly case.
         */
        state->rightsplit = false;

        /*
         * Verify this level, and get left most page for next level down, if
         * not at leaf level
         */
        current = bt_check_level_from_leftmost(state, current);

        if (current.leftmost == InvalidBlockNumber)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("index \"%s\" has no valid pages on level below %u or first level",
                            RelationGetRelationName(rel), previouslevel)));

        previouslevel = current.level;
    }

    /*
     * * Check whether heap contains unindexed/malformed tuples *
     */
    if (state->heapallindexed)
    {
        IndexInfo  *indexinfo = BuildIndexInfo(state->rel);
        TableScanDesc scan;

        /* Report on extra downlink checks performed in readonly case */
        if (state->readonly)
        {
            ereport(DEBUG1,
                    (errmsg_internal("finished verifying presence of downlink blocks within index \"%s\" with bitset %.2f%% set",
                                     RelationGetRelationName(rel),
                                     100.0 * bloom_prop_bits_set(state->downlinkfilter))));
            bloom_free(state->downlinkfilter);
        }

        /*
         * Create our own scan for table_index_build_scan(), rather than
         * getting it to do so for us.  This is required so that we can
         * actually use the MVCC snapshot registered earlier in !readonly
         * case.
         *
         * Note that table_index_build_scan() calls heap_endscan() for us.
         */
        scan = table_beginscan_strat(state->heaprel,    /* relation */
                                     snapshot,  /* snapshot */
                                     0, /* number of keys */
                                     NULL,  /* scan key */
                                     true,  /* buffer access strategy OK */
                                     true); /* syncscan OK? */

        /*
         * Scan will behave as the first scan of a CREATE INDEX CONCURRENTLY
         * behaves in !readonly case.
         *
         * It's okay that we don't actually use the same lock strength for the
         * heap relation as any other ii_Concurrent caller would in !readonly
         * case.  We have no reason to care about a concurrent VACUUM
         * operation, since there isn't going to be a second scan of the heap
         * that needs to be sure that there was no concurrent recycling of
         * TIDs.
         */
        indexinfo->ii_Concurrent = !state->readonly;

        /*
         * Don't wait for uncommitted tuple xact commit/abort when index is a
         * unique index on a catalog (or an index used by an exclusion
         * constraint).  This could otherwise happen in the readonly case.
         */
        indexinfo->ii_Unique = false;
        indexinfo->ii_ExclusionOps = NULL;
        indexinfo->ii_ExclusionProcs = NULL;
        indexinfo->ii_ExclusionStrats = NULL;

        elog(DEBUG1, "verifying that tuples from index \"%s\" are present in \"%s\"",
             RelationGetRelationName(state->rel),
             RelationGetRelationName(state->heaprel));

        table_index_build_scan(state->heaprel, state->rel, indexinfo, true, false,
                               bt_tuple_present_callback, (void *) state, scan);

        ereport(DEBUG1,
                (errmsg_internal("finished verifying presence of " INT64_FORMAT " tuples from table \"%s\" with bitset %.2f%% set",
                                 state->heaptuplespresent, RelationGetRelationName(heaprel),
                                 100.0 * bloom_prop_bits_set(state->filter))));

        if (snapshot != SnapshotAny)
            UnregisterSnapshot(snapshot);

        bloom_free(state->filter);
    }

    /* Be tidy: */
    MemoryContextDelete(state->targetcontext);
}

/*
 * Given a left-most block at some level, move right, verifying each page
 * individually (with more verification across pages for "readonly"
 * callers).  Caller should pass the true root page as the leftmost initially,
 * working their way down by passing what is returned for the last call here
 * until level 0 (leaf page level) was reached.
 *
 * Returns state for next call, if any.  This includes left-most block number
 * one level lower that should be passed on next level/call, which is set to
 * P_NONE on last call here (when leaf level is verified).  Level numbers
 * follow the nbtree convention: higher levels have higher numbers, because new
 * levels are added only due to a root page split.  Note that prior to the
 * first root page split, the root is also a leaf page, so there is always a
 * level 0 (leaf level), and it's always the last level processed.
 *
 * Note on memory management:  State's per-page context is reset here, between
 * each call to bt_target_page_check().
 */
static BtreeLevel
bt_check_level_from_leftmost(BtreeCheckState *state, BtreeLevel level)
{
    /* State to establish early, concerning entire level */
    BTPageOpaque opaque;
    MemoryContext oldcontext;
    BtreeLevel  nextleveldown;

    /* Variables for iterating across level using right links */
    BlockNumber leftcurrent = P_NONE;
    BlockNumber current = level.leftmost;

    /* Initialize return state */
    nextleveldown.leftmost = InvalidBlockNumber;
    nextleveldown.level = InvalidBtreeLevel;
    nextleveldown.istruerootlevel = false;

    /* Use page-level context for duration of this call */
    oldcontext = MemoryContextSwitchTo(state->targetcontext);

    elog(DEBUG2, "verifying level %u%s", level.level,
         level.istruerootlevel ?
         " (true root level)" : level.level == 0 ? " (leaf level)" : "");

    do
    {
        /* Don't rely on CHECK_FOR_INTERRUPTS() calls at lower level */
        CHECK_FOR_INTERRUPTS();

        /* Initialize state for this iteration */
        state->targetblock = current;
        state->target = palloc_btree_page(state, state->targetblock);
        state->targetlsn = PageGetLSN(state->target);

        opaque = (BTPageOpaque) PageGetSpecialPointer(state->target);

        if (P_IGNORE(opaque))
        {
            /*
             * Since there cannot be a concurrent VACUUM operation in readonly
             * mode, and since a page has no links within other pages
             * (siblings and parent) once it is marked fully deleted, it
             * should be impossible to land on a fully deleted page in
             * readonly mode. See bt_downlink_check() for further details.
             *
             * The bt_downlink_check() P_ISDELETED() check is repeated here so
             * that pages that are only reachable through sibling links get
             * checked.
             */
            if (state->readonly && P_ISDELETED(opaque))
                ereport(ERROR,
                        (errcode(ERRCODE_INDEX_CORRUPTED),
                         errmsg("downlink or sibling link points to deleted block in index \"%s\"",
                                RelationGetRelationName(state->rel)),
                         errdetail_internal("Block=%u left block=%u left link from block=%u.",
                                            current, leftcurrent, opaque->btpo_prev)));

            if (P_RIGHTMOST(opaque))
                ereport(ERROR,
                        (errcode(ERRCODE_INDEX_CORRUPTED),
                         errmsg("block %u fell off the end of index \"%s\"",
                                current, RelationGetRelationName(state->rel))));
            else
                ereport(DEBUG1,
                        (errcode(ERRCODE_NO_DATA),
                         errmsg("block %u of index \"%s\" ignored",
                                current, RelationGetRelationName(state->rel))));
            goto nextpage;
        }
        else if (nextleveldown.leftmost == InvalidBlockNumber)
        {
            /*
             * A concurrent page split could make the caller supplied leftmost
             * block no longer contain the leftmost page, or no longer be the
             * true root, but where that isn't possible due to heavyweight
             * locking, check that the first valid page meets caller's
             * expectations.
             */
            if (state->readonly)
            {
                if (!P_LEFTMOST(opaque))
                    ereport(ERROR,
                            (errcode(ERRCODE_INDEX_CORRUPTED),
                             errmsg("block %u is not leftmost in index \"%s\"",
                                    current, RelationGetRelationName(state->rel))));

                if (level.istruerootlevel && !P_ISROOT(opaque))
                    ereport(ERROR,
                            (errcode(ERRCODE_INDEX_CORRUPTED),
                             errmsg("block %u is not true root in index \"%s\"",
                                    current, RelationGetRelationName(state->rel))));
            }

            /*
             * Before beginning any non-trivial examination of level, prepare
             * state for next bt_check_level_from_leftmost() invocation for
             * the next level for the next level down (if any).
             *
             * There should be at least one non-ignorable page per level,
             * unless this is the leaf level, which is assumed by caller to be
             * final level.
             */
            if (!P_ISLEAF(opaque))
            {
                IndexTuple  itup;
                ItemId      itemid;

                /* Internal page -- downlink gets leftmost on next level */
                itemid = PageGetItemIdCareful(state, state->targetblock,
                                              state->target,
                                              P_FIRSTDATAKEY(opaque));
                itup = (IndexTuple) PageGetItem(state->target, itemid);
                nextleveldown.leftmost = BTreeTupleGetDownLink(itup);
                nextleveldown.level = opaque->btpo.level - 1;
            }
            else
            {
                /*
                 * Leaf page -- final level caller must process.
                 *
                 * Note that this could also be the root page, if there has
                 * been no root page split yet.
                 */
                nextleveldown.leftmost = P_NONE;
                nextleveldown.level = InvalidBtreeLevel;
            }

            /*
             * Finished setting up state for this call/level.  Control will
             * never end up back here in any future loop iteration for this
             * level.
             */
        }

        /*
         * readonly mode can only ever land on live pages and half-dead pages,
         * so sibling pointers should always be in mutual agreement
         */
        if (state->readonly && opaque->btpo_prev != leftcurrent)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("left link/right link pair in index \"%s\" not in agreement",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Block=%u left block=%u left link from block=%u.",
                                        current, leftcurrent, opaque->btpo_prev)));

        /* Check level, which must be valid for non-ignorable page */
        if (level.level != opaque->btpo.level)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("leftmost down link for level points to block in index \"%s\" whose level is not one level down",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Block pointed to=%u expected level=%u level in pointed to block=%u.",
                                        current, level.level, opaque->btpo.level)));

        /* Verify invariants for page */
        bt_target_page_check(state);

nextpage:

        /* Try to detect circular links */
        if (current == leftcurrent || current == opaque->btpo_prev)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("circular link chain found in block %u of index \"%s\"",
                            current, RelationGetRelationName(state->rel))));

        /*
         * Record if page that is about to become target is the right half of
         * an incomplete page split.  This can go stale immediately in
         * !readonly case.
         */
        state->rightsplit = P_INCOMPLETE_SPLIT(opaque);

        leftcurrent = current;
        current = opaque->btpo_next;

        /* Free page and associated memory for this iteration */
        MemoryContextReset(state->targetcontext);
    }
    while (current != P_NONE);

    /* Don't change context for caller */
    MemoryContextSwitchTo(oldcontext);

    return nextleveldown;
}

/*
 * Function performs the following checks on target page, or pages ancillary to
 * target page:
 *
 * - That every "real" data item is less than or equal to the high key, which
 *   is an upper bound on the items on the page.  Data items should be
 *   strictly less than the high key when the page is an internal page.
 *
 * - That within the page, every data item is strictly less than the item
 *   immediately to its right, if any (i.e., that the items are in order
 *   within the page, so that the binary searches performed by index scans are
 *   sane).
 *
 * - That the last data item stored on the page is strictly less than the
 *   first data item on the page to the right (when such a first item is
 *   available).
 *
 * - Various checks on the structure of tuples themselves.  For example, check
 *   that non-pivot tuples have no truncated attributes.
 *
 * Furthermore, when state passed shows ShareLock held, function also checks:
 *
 * - That all child pages respect strict lower bound from parent's pivot
 *   tuple.
 *
 * - That downlink to block was encountered in parent where that's expected.
 *   (Limited to heapallindexed readonly callers.)
 *
 * This is also where heapallindexed callers use their Bloom filter to
 * fingerprint IndexTuples for later table_index_build_scan() verification.
 *
 * Note:  Memory allocated in this routine is expected to be released by caller
 * resetting state->targetcontext.
 */
static void
bt_target_page_check(BtreeCheckState *state)
{
    OffsetNumber offset;
    OffsetNumber max;
    BTPageOpaque topaque;

    topaque = (BTPageOpaque) PageGetSpecialPointer(state->target);
    max = PageGetMaxOffsetNumber(state->target);

    elog(DEBUG2, "verifying %u items on %s block %u", max,
         P_ISLEAF(topaque) ? "leaf" : "internal", state->targetblock);

    /*
     * Check the number of attributes in high key. Note, rightmost page
     * doesn't contain a high key, so nothing to check
     */
    if (!P_RIGHTMOST(topaque))
    {
        ItemId      itemid;
        IndexTuple  itup;

        /* Verify line pointer before checking tuple */
        itemid = PageGetItemIdCareful(state, state->targetblock,
                                      state->target, P_HIKEY);
        if (!_bt_check_natts(state->rel, state->heapkeyspace, state->target,
                             P_HIKEY))
        {
            itup = (IndexTuple) PageGetItem(state->target, itemid);
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("wrong number of high key index tuple attributes in index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Index block=%u natts=%u block type=%s page lsn=%X/%X.",
                                        state->targetblock,
                                        BTreeTupleGetNAtts(itup, state->rel),
                                        P_ISLEAF(topaque) ? "heap" : "index",
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
        }
    }

    /*
     * Loop over page items, starting from first non-highkey item, not high
     * key (if any).  Most tests are not performed for the "negative infinity"
     * real item (if any).
     */
    for (offset = P_FIRSTDATAKEY(topaque);
         offset <= max;
         offset = OffsetNumberNext(offset))
    {
        ItemId      itemid;
        IndexTuple  itup;
        size_t      tupsize;
        BTScanInsert skey;
        bool        lowersizelimit;

        CHECK_FOR_INTERRUPTS();

        itemid = PageGetItemIdCareful(state, state->targetblock,
                                      state->target, offset);
        itup = (IndexTuple) PageGetItem(state->target, itemid);
        tupsize = IndexTupleSize(itup);

        /*
         * lp_len should match the IndexTuple reported length exactly, since
         * lp_len is completely redundant in indexes, and both sources of
         * tuple length are MAXALIGN()'d.  nbtree does not use lp_len all that
         * frequently, and is surprisingly tolerant of corrupt lp_len fields.
         */
        if (tupsize != ItemIdGetLength(itemid))
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("index tuple size does not equal lp_len in index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Index tid=(%u,%u) tuple size=%zu lp_len=%u page lsn=%X/%X.",
                                        state->targetblock, offset,
                                        tupsize, ItemIdGetLength(itemid),
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn),
                     errhint("This could be a torn page problem.")));

        /* Check the number of index tuple attributes */
        if (!_bt_check_natts(state->rel, state->heapkeyspace, state->target,
                             offset))
        {
            char       *itid,
                       *htid;

            itid = psprintf("(%u,%u)", state->targetblock, offset);
            htid = psprintf("(%u,%u)",
                            ItemPointerGetBlockNumberNoCheck(&(itup->t_tid)),
                            ItemPointerGetOffsetNumberNoCheck(&(itup->t_tid)));

            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("wrong number of index tuple attributes in index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Index tid=%s natts=%u points to %s tid=%s page lsn=%X/%X.",
                                        itid,
                                        BTreeTupleGetNAtts(itup, state->rel),
                                        P_ISLEAF(topaque) ? "heap" : "index",
                                        htid,
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
        }

        /* Fingerprint downlink blocks in heapallindexed + readonly case */
        if (state->heapallindexed && state->readonly && !P_ISLEAF(topaque))
        {
            BlockNumber childblock = BTreeTupleGetDownLink(itup);

            bloom_add_element(state->downlinkfilter,
                              (unsigned char *) &childblock,
                              sizeof(BlockNumber));
        }

        /*
         * Don't try to generate scankey using "negative infinity" item on
         * internal pages. They are always truncated to zero attributes.
         */
        if (offset_is_negative_infinity(topaque, offset))
            continue;

        /*
         * Readonly callers may optionally verify that non-pivot tuples can
         * each be found by an independent search that starts from the root
         */
        if (state->rootdescend && P_ISLEAF(topaque) &&
            !bt_rootdescend(state, itup))
        {
            char       *itid,
                       *htid;

            itid = psprintf("(%u,%u)", state->targetblock, offset);
            htid = psprintf("(%u,%u)",
                            ItemPointerGetBlockNumber(&(itup->t_tid)),
                            ItemPointerGetOffsetNumber(&(itup->t_tid)));

            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("could not find tuple using search from root page in index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Index tid=%s points to heap tid=%s page lsn=%X/%X.",
                                        itid, htid,
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
        }

        /* Build insertion scankey for current page offset */
        skey = bt_mkscankey_pivotsearch(state->rel, itup);

        /*
         * Make sure tuple size does not exceed the relevant BTREE_VERSION
         * specific limit.
         *
         * BTREE_VERSION 4 (which introduced heapkeyspace rules) requisitioned
         * a small amount of space from BTMaxItemSize() in order to ensure
         * that suffix truncation always has enough space to add an explicit
         * heap TID back to a tuple -- we pessimistically assume that every
         * newly inserted tuple will eventually need to have a heap TID
         * appended during a future leaf page split, when the tuple becomes
         * the basis of the new high key (pivot tuple) for the leaf page.
         *
         * Since the reclaimed space is reserved for that purpose, we must not
         * enforce the slightly lower limit when the extra space has been used
         * as intended.  In other words, there is only a cross-version
         * difference in the limit on tuple size within leaf pages.
         *
         * Still, we're particular about the details within BTREE_VERSION 4
         * internal pages.  Pivot tuples may only use the extra space for its
         * designated purpose.  Enforce the lower limit for pivot tuples when
         * an explicit heap TID isn't actually present. (In all other cases
         * suffix truncation is guaranteed to generate a pivot tuple that's no
         * larger than the first right tuple provided to it by its caller.)
         */
        lowersizelimit = skey->heapkeyspace &&
            (P_ISLEAF(topaque) || BTreeTupleGetHeapTID(itup) == NULL);
        if (tupsize > (lowersizelimit ? BTMaxItemSize(state->target) :
                       BTMaxItemSizeNoHeapTid(state->target)))
        {
            char       *itid,
                       *htid;

            itid = psprintf("(%u,%u)", state->targetblock, offset);
            htid = psprintf("(%u,%u)",
                            ItemPointerGetBlockNumberNoCheck(&(itup->t_tid)),
                            ItemPointerGetOffsetNumberNoCheck(&(itup->t_tid)));

            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("index row size %zu exceeds maximum for index \"%s\"",
                            tupsize, RelationGetRelationName(state->rel)),
                     errdetail_internal("Index tid=%s points to %s tid=%s page lsn=%X/%X.",
                                        itid,
                                        P_ISLEAF(topaque) ? "heap" : "index",
                                        htid,
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
        }

        /* Fingerprint leaf page tuples (those that point to the heap) */
        if (state->heapallindexed && P_ISLEAF(topaque) && !ItemIdIsDead(itemid))
        {
            IndexTuple  norm;

            norm = bt_normalize_tuple(state, itup);
            bloom_add_element(state->filter, (unsigned char *) norm,
                              IndexTupleSize(norm));
            /* Be tidy */
            if (norm != itup)
                pfree(norm);
        }

        /*
         * * High key check *
         *
         * If there is a high key (if this is not the rightmost page on its
         * entire level), check that high key actually is upper bound on all
         * page items.
         *
         * We prefer to check all items against high key rather than checking
         * just the last and trusting that the operator class obeys the
         * transitive law (which implies that all previous items also
         * respected the high key invariant if they pass the item order
         * check).
         *
         * Ideally, we'd compare every item in the index against every other
         * item in the index, and not trust opclass obedience of the
         * transitive law to bridge the gap between children and their
         * grandparents (as well as great-grandparents, and so on).  We don't
         * go to those lengths because that would be prohibitively expensive,
         * and probably not markedly more effective in practice.
         *
         * On the leaf level, we check that the key is <= the highkey.
         * However, on non-leaf levels we check that the key is < the highkey,
         * because the high key is "just another separator" rather than a copy
         * of some existing key item; we expect it to be unique among all keys
         * on the same level.  (Suffix truncation will sometimes produce a
         * leaf highkey that is an untruncated copy of the lastleft item, but
         * never any other item, which necessitates weakening the leaf level
         * check to <=.)
         *
         * Full explanation for why a highkey is never truly a copy of another
         * item from the same level on internal levels:
         *
         * While the new left page's high key is copied from the first offset
         * on the right page during an internal page split, that's not the
         * full story.  In effect, internal pages are split in the middle of
         * the firstright tuple, not between the would-be lastleft and
         * firstright tuples: the firstright key ends up on the left side as
         * left's new highkey, and the firstright downlink ends up on the
         * right side as right's new "negative infinity" item.  The negative
         * infinity tuple is truncated to zero attributes, so we're only left
         * with the downlink.  In other words, the copying is just an
         * implementation detail of splitting in the middle of a (pivot)
         * tuple. (See also: "Notes About Data Representation" in the nbtree
         * README.)
         */
        if (!P_RIGHTMOST(topaque) &&
            !(P_ISLEAF(topaque) ? invariant_leq_offset(state, skey, P_HIKEY) :
              invariant_l_offset(state, skey, P_HIKEY)))
        {
            char       *itid,
                       *htid;

            itid = psprintf("(%u,%u)", state->targetblock, offset);
            htid = psprintf("(%u,%u)",
                            ItemPointerGetBlockNumberNoCheck(&(itup->t_tid)),
                            ItemPointerGetOffsetNumberNoCheck(&(itup->t_tid)));

            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("high key invariant violated for index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Index tid=%s points to %s tid=%s page lsn=%X/%X.",
                                        itid,
                                        P_ISLEAF(topaque) ? "heap" : "index",
                                        htid,
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
        }

        /*
         * * Item order check *
         *
         * Check that items are stored on page in logical order, by checking
         * current item is strictly less than next item (if any).
         */
        if (OffsetNumberNext(offset) <= max &&
            !invariant_l_offset(state, skey, OffsetNumberNext(offset)))
        {
            char       *itid,
                       *htid,
                       *nitid,
                       *nhtid;

            itid = psprintf("(%u,%u)", state->targetblock, offset);
            htid = psprintf("(%u,%u)",
                            ItemPointerGetBlockNumberNoCheck(&(itup->t_tid)),
                            ItemPointerGetOffsetNumberNoCheck(&(itup->t_tid)));
            nitid = psprintf("(%u,%u)", state->targetblock,
                             OffsetNumberNext(offset));

            /* Reuse itup to get pointed-to heap location of second item */
            itemid = PageGetItemIdCareful(state, state->targetblock,
                                          state->target,
                                          OffsetNumberNext(offset));
            itup = (IndexTuple) PageGetItem(state->target, itemid);
            nhtid = psprintf("(%u,%u)",
                             ItemPointerGetBlockNumberNoCheck(&(itup->t_tid)),
                             ItemPointerGetOffsetNumberNoCheck(&(itup->t_tid)));

            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("item order invariant violated for index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Lower index tid=%s (points to %s tid=%s) "
                                        "higher index tid=%s (points to %s tid=%s) "
                                        "page lsn=%X/%X.",
                                        itid,
                                        P_ISLEAF(topaque) ? "heap" : "index",
                                        htid,
                                        nitid,
                                        P_ISLEAF(topaque) ? "heap" : "index",
                                        nhtid,
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
        }

        /*
         * * Last item check *
         *
         * Check last item against next/right page's first data item's when
         * last item on page is reached.  This additional check will detect
         * transposed pages iff the supposed right sibling page happens to
         * belong before target in the key space.  (Otherwise, a subsequent
         * heap verification will probably detect the problem.)
         *
         * This check is similar to the item order check that will have
         * already been performed for every other "real" item on target page
         * when last item is checked.  The difference is that the next item
         * (the item that is compared to target's last item) needs to come
         * from the next/sibling page.  There may not be such an item
         * available from sibling for various reasons, though (e.g., target is
         * the rightmost page on level).
         */
        else if (offset == max)
        {
            BTScanInsert rightkey;

            /* Get item in next/right page */
            rightkey = bt_right_page_check_scankey(state);

            if (rightkey &&
                !invariant_g_offset(state, rightkey, max))
            {
                /*
                 * As explained at length in bt_right_page_check_scankey(),
                 * there is a known !readonly race that could account for
                 * apparent violation of invariant, which we must check for
                 * before actually proceeding with raising error.  Our canary
                 * condition is that target page was deleted.
                 */
                if (!state->readonly)
                {
                    /* Get fresh copy of target page */
                    state->target = palloc_btree_page(state, state->targetblock);
                    /* Note that we deliberately do not update target LSN */
                    topaque = (BTPageOpaque) PageGetSpecialPointer(state->target);

                    /*
                     * All !readonly checks now performed; just return
                     */
                    if (P_IGNORE(topaque))
                        return;
                }

                ereport(ERROR,
                        (errcode(ERRCODE_INDEX_CORRUPTED),
                         errmsg("cross page item order invariant violated for index \"%s\"",
                                RelationGetRelationName(state->rel)),
                         errdetail_internal("Last item on page tid=(%u,%u) page lsn=%X/%X.",
                                            state->targetblock, offset,
                                            (uint32) (state->targetlsn >> 32),
                                            (uint32) state->targetlsn)));
            }
        }

        /*
         * * Downlink check *
         *
         * Additional check of child items iff this is an internal page and
         * caller holds a ShareLock.  This happens for every downlink (item)
         * in target excluding the negative-infinity downlink (again, this is
         * because it has no useful value to compare).
         */
        if (!P_ISLEAF(topaque) && state->readonly)
        {
            BlockNumber childblock = BTreeTupleGetDownLink(itup);

            bt_downlink_check(state, skey, childblock);
        }
    }

    /*
     * * Check if page has a downlink in parent *
     *
     * This can only be checked in heapallindexed + readonly case.
     */
    if (state->heapallindexed && state->readonly)
        bt_downlink_missing_check(state);
}

/*
 * Return a scankey for an item on page to right of current target (or the
 * first non-ignorable page), sufficient to check ordering invariant on last
 * item in current target page.  Returned scankey relies on local memory
 * allocated for the child page, which caller cannot pfree().  Caller's memory
 * context should be reset between calls here.
 *
 * This is the first data item, and so all adjacent items are checked against
 * their immediate sibling item (which may be on a sibling page, or even a
 * "cousin" page at parent boundaries where target's rightlink points to page
 * with different parent page).  If no such valid item is available, return
 * NULL instead.
 *
 * Note that !readonly callers must reverify that target page has not
 * been concurrently deleted.
 */
static BTScanInsert
bt_right_page_check_scankey(BtreeCheckState *state)
{
    BTPageOpaque opaque;
    ItemId      rightitem;
    IndexTuple  firstitup;
    BlockNumber targetnext;
    Page        rightpage;
    OffsetNumber nline;

    /* Determine target's next block number */
    opaque = (BTPageOpaque) PageGetSpecialPointer(state->target);

    /* If target is already rightmost, no right sibling; nothing to do here */
    if (P_RIGHTMOST(opaque))
        return NULL;

    /*
     * General notes on concurrent page splits and page deletion:
     *
     * Routines like _bt_search() don't require *any* page split interlock
     * when descending the tree, including something very light like a buffer
     * pin. That's why it's okay that we don't either.  This avoidance of any
     * need to "couple" buffer locks is the raison d' etre of the Lehman & Yao
     * algorithm, in fact.
     *
     * That leaves deletion.  A deleted page won't actually be recycled by
     * VACUUM early enough for us to fail to at least follow its right link
     * (or left link, or downlink) and find its sibling, because recycling
     * does not occur until no possible index scan could land on the page.
     * Index scans can follow links with nothing more than their snapshot as
     * an interlock and be sure of at least that much.  (See page
     * recycling/RecentGlobalXmin notes in nbtree README.)
     *
     * Furthermore, it's okay if we follow a rightlink and find a half-dead or
     * dead (ignorable) page one or more times.  There will either be a
     * further right link to follow that leads to a live page before too long
     * (before passing by parent's rightmost child), or we will find the end
     * of the entire level instead (possible when parent page is itself the
     * rightmost on its level).
     */
    targetnext = opaque->btpo_next;
    for (;;)
    {
        CHECK_FOR_INTERRUPTS();

        rightpage = palloc_btree_page(state, targetnext);
        opaque = (BTPageOpaque) PageGetSpecialPointer(rightpage);

        if (!P_IGNORE(opaque) || P_RIGHTMOST(opaque))
            break;

        /* We landed on a deleted page, so step right to find a live page */
        targetnext = opaque->btpo_next;
        ereport(DEBUG1,
                (errcode(ERRCODE_NO_DATA),
                 errmsg("level %u leftmost page of index \"%s\" was found deleted or half dead",
                        opaque->btpo.level, RelationGetRelationName(state->rel)),
                 errdetail_internal("Deleted page found when building scankey from right sibling.")));

        /* Be slightly more pro-active in freeing this memory, just in case */
        pfree(rightpage);
    }

    /*
     * No ShareLock held case -- why it's safe to proceed.
     *
     * Problem:
     *
     * We must avoid false positive reports of corruption when caller treats
     * item returned here as an upper bound on target's last item.  In
     * general, false positives are disallowed.  Avoiding them here when
     * caller is !readonly is subtle.
     *
     * A concurrent page deletion by VACUUM of the target page can result in
     * the insertion of items on to this right sibling page that would
     * previously have been inserted on our target page.  There might have
     * been insertions that followed the target's downlink after it was made
     * to point to right sibling instead of target by page deletion's first
     * phase. The inserters insert items that would belong on target page.
     * This race is very tight, but it's possible.  This is our only problem.
     *
     * Non-problems:
     *
     * We are not hindered by a concurrent page split of the target; we'll
     * never land on the second half of the page anyway.  A concurrent split
     * of the right page will also not matter, because the first data item
     * remains the same within the left half, which we'll reliably land on. If
     * we had to skip over ignorable/deleted pages, it cannot matter because
     * their key space has already been atomically merged with the first
     * non-ignorable page we eventually find (doesn't matter whether the page
     * we eventually find is a true sibling or a cousin of target, which we go
     * into below).
     *
     * Solution:
     *
     * Caller knows that it should reverify that target is not ignorable
     * (half-dead or deleted) when cross-page sibling item comparison appears
     * to indicate corruption (invariant fails).  This detects the single race
     * condition that exists for caller.  This is correct because the
     * continued existence of target block as non-ignorable (not half-dead or
     * deleted) implies that target page was not merged into from the right by
     * deletion; the key space at or after target never moved left.  Target's
     * parent either has the same downlink to target as before, or a <
     * downlink due to deletion at the left of target.  Target either has the
     * same highkey as before, or a highkey < before when there is a page
     * split. (The rightmost concurrently-split-from-target-page page will
     * still have the same highkey as target was originally found to have,
     * which for our purposes is equivalent to target's highkey itself never
     * changing, since we reliably skip over
     * concurrently-split-from-target-page pages.)
     *
     * In simpler terms, we allow that the key space of the target may expand
     * left (the key space can move left on the left side of target only), but
     * the target key space cannot expand right and get ahead of us without
     * our detecting it.  The key space of the target cannot shrink, unless it
     * shrinks to zero due to the deletion of the original page, our canary
     * condition.  (To be very precise, we're a bit stricter than that because
     * it might just have been that the target page split and only the
     * original target page was deleted.  We can be more strict, just not more
     * lax.)
     *
     * Top level tree walk caller moves on to next page (makes it the new
     * target) following recovery from this race.  (cf.  The rationale for
     * child/downlink verification needing a ShareLock within
     * bt_downlink_check(), where page deletion is also the main source of
     * trouble.)
     *
     * Note that it doesn't matter if right sibling page here is actually a
     * cousin page, because in order for the key space to be readjusted in a
     * way that causes us issues in next level up (guiding problematic
     * concurrent insertions to the cousin from the grandparent rather than to
     * the sibling from the parent), there'd have to be page deletion of
     * target's parent page (affecting target's parent's downlink in target's
     * grandparent page).  Internal page deletion only occurs when there are
     * no child pages (they were all fully deleted), and caller is checking
     * that the target's parent has at least one non-deleted (so
     * non-ignorable) child: the target page.  (Note that the first phase of
     * deletion atomically marks the page to be deleted half-dead/ignorable at
     * the same time downlink in its parent is removed, so caller will
     * definitely not fail to detect that this happened.)
     *
     * This trick is inspired by the method backward scans use for dealing
     * with concurrent page splits; concurrent page deletion is a problem that
     * similarly receives special consideration sometimes (it's possible that
     * the backwards scan will re-read its "original" block after failing to
     * find a right-link to it, having already moved in the opposite direction
     * (right/"forwards") a few times to try to locate one).  Just like us,
     * that happens only to determine if there was a concurrent page deletion
     * of a reference page, and just like us if there was a page deletion of
     * that reference page it means we can move on from caring about the
     * reference page.  See the nbtree README for a full description of how
     * that works.
     */
    nline = PageGetMaxOffsetNumber(rightpage);

    /*
     * Get first data item, if any
     */
    if (P_ISLEAF(opaque) && nline >= P_FIRSTDATAKEY(opaque))
    {
        /* Return first data item (if any) */
        rightitem = PageGetItemIdCareful(state, targetnext, rightpage,
                                         P_FIRSTDATAKEY(opaque));
    }
    else if (!P_ISLEAF(opaque) &&
             nline >= OffsetNumberNext(P_FIRSTDATAKEY(opaque)))
    {
        /*
         * Return first item after the internal page's "negative infinity"
         * item
         */
        rightitem = PageGetItemIdCareful(state, targetnext, rightpage,
                                         OffsetNumberNext(P_FIRSTDATAKEY(opaque)));
    }
    else
    {
        /*
         * No first item.  Page is probably empty leaf page, but it's also
         * possible that it's an internal page with only a negative infinity
         * item.
         */
        ereport(DEBUG1,
                (errcode(ERRCODE_NO_DATA),
                 errmsg("%s block %u of index \"%s\" has no first data item",
                        P_ISLEAF(opaque) ? "leaf" : "internal", targetnext,
                        RelationGetRelationName(state->rel))));
        return NULL;
    }

    /*
     * Return first real item scankey.  Note that this relies on right page
     * memory remaining allocated.
     */
    firstitup = (IndexTuple) PageGetItem(rightpage, rightitem);
    return bt_mkscankey_pivotsearch(state->rel, firstitup);
}

/*
 * Checks one of target's downlink against its child page.
 *
 * Conceptually, the target page continues to be what is checked here.  The
 * target block is still blamed in the event of finding an invariant violation.
 * The downlink insertion into the target is probably where any problem raised
 * here arises, and there is no such thing as a parent link, so doing the
 * verification this way around is much more practical.
 */
static void
bt_downlink_check(BtreeCheckState *state, BTScanInsert targetkey,
                  BlockNumber childblock)
{
    OffsetNumber offset;
    OffsetNumber maxoffset;
    Page        child;
    BTPageOpaque copaque;

    /*
     * Caller must have ShareLock on target relation, because of
     * considerations around page deletion by VACUUM.
     *
     * NB: In general, page deletion deletes the right sibling's downlink, not
     * the downlink of the page being deleted; the deleted page's downlink is
     * reused for its sibling.  The key space is thereby consolidated between
     * the deleted page and its right sibling.  (We cannot delete a parent
     * page's rightmost child unless it is the last child page, and we intend
     * to also delete the parent itself.)
     *
     * If this verification happened without a ShareLock, the following race
     * condition could cause false positives:
     *
     * In general, concurrent page deletion might occur, including deletion of
     * the left sibling of the child page that is examined here.  If such a
     * page deletion were to occur, closely followed by an insertion into the
     * newly expanded key space of the child, a window for the false positive
     * opens up: the stale parent/target downlink originally followed to get
     * to the child legitimately ceases to be a lower bound on all items in
     * the page, since the key space was concurrently expanded "left".
     * (Insertion followed the "new" downlink for the child, not our now-stale
     * downlink, which was concurrently physically removed in target/parent as
     * part of deletion's first phase.)
     *
     * Note that while the cross-page-same-level last item check uses a trick
     * that allows it to perform verification for !readonly callers, a similar
     * trick seems difficult here.  The trick that that other check uses is,
     * in essence, to lock down race conditions to those that occur due to
     * concurrent page deletion of the target; that's a race that can be
     * reliably detected before actually reporting corruption.
     *
     * On the other hand, we'd need to lock down race conditions involving
     * deletion of child's left page, for long enough to read the child page
     * into memory (in other words, a scheme with concurrently held buffer
     * locks on both child and left-of-child pages).  That's unacceptable for
     * amcheck functions on general principle, though.
     */
    Assert(state->readonly);

    /*
     * Verify child page has the downlink key from target page (its parent) as
     * a lower bound; downlink must be strictly less than all keys on the
     * page.
     *
     * Check all items, rather than checking just the first and trusting that
     * the operator class obeys the transitive law.
     */
    child = palloc_btree_page(state, childblock);
    copaque = (BTPageOpaque) PageGetSpecialPointer(child);
    maxoffset = PageGetMaxOffsetNumber(child);

    /*
     * Since there cannot be a concurrent VACUUM operation in readonly mode,
     * and since a page has no links within other pages (siblings and parent)
     * once it is marked fully deleted, it should be impossible to land on a
     * fully deleted page.
     *
     * It does not quite make sense to enforce that the page cannot even be
     * half-dead, despite the fact the downlink is modified at the same stage
     * that the child leaf page is marked half-dead.  That's incorrect because
     * there may occasionally be multiple downlinks from a chain of pages
     * undergoing deletion, where multiple successive calls are made to
     * _bt_unlink_halfdead_page() by VACUUM before it can finally safely mark
     * the leaf page as fully dead.  While _bt_mark_page_halfdead() usually
     * removes the downlink to the leaf page that is marked half-dead, that's
     * not guaranteed, so it's possible we'll land on a half-dead page with a
     * downlink due to an interrupted multi-level page deletion.
     *
     * We go ahead with our checks if the child page is half-dead.  It's safe
     * to do so because we do not test the child's high key, so it does not
     * matter that the original high key will have been replaced by a dummy
     * truncated high key within _bt_mark_page_halfdead().  All other page
     * items are left intact on a half-dead page, so there is still something
     * to test.
     */
    if (P_ISDELETED(copaque))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("downlink to deleted page found in index \"%s\"",
                        RelationGetRelationName(state->rel)),
                 errdetail_internal("Parent block=%u child block=%u parent page lsn=%X/%X.",
                                    state->targetblock, childblock,
                                    (uint32) (state->targetlsn >> 32),
                                    (uint32) state->targetlsn)));

    for (offset = P_FIRSTDATAKEY(copaque);
         offset <= maxoffset;
         offset = OffsetNumberNext(offset))
    {
        /*
         * Skip comparison of target page key against "negative infinity"
         * item, if any.  Checking it would indicate that it's not a strict
         * lower bound, but that's only because of the hard-coding for
         * negative infinity items within _bt_compare().
         *
         * If nbtree didn't truncate negative infinity tuples during internal
         * page splits then we'd expect child's negative infinity key to be
         * equal to the scankey/downlink from target/parent (it would be a
         * "low key" in this hypothetical scenario, and so it would still need
         * to be treated as a special case here).
         *
         * Negative infinity items can be thought of as a strict lower bound
         * that works transitively, with the last non-negative-infinity pivot
         * followed during a descent from the root as its "true" strict lower
         * bound.  Only a small number of negative infinity items are truly
         * negative infinity; those that are the first items of leftmost
         * internal pages.  In more general terms, a negative infinity item is
         * only negative infinity with respect to the subtree that the page is
         * at the root of.
         *
         * See also: bt_rootdescend(), which can even detect transitive
         * inconsistencies on cousin leaf pages.
         */
        if (offset_is_negative_infinity(copaque, offset))
            continue;

        if (!invariant_l_nontarget_offset(state, targetkey, childblock, child,
                                          offset))
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("down-link lower bound invariant violated for index \"%s\"",
                            RelationGetRelationName(state->rel)),
                     errdetail_internal("Parent block=%u child index tid=(%u,%u) parent page lsn=%X/%X.",
                                        state->targetblock, childblock, offset,
                                        (uint32) (state->targetlsn >> 32),
                                        (uint32) state->targetlsn)));
    }

    pfree(child);
}

/*
 * Checks if page is missing a downlink that it should have.
 *
 * A page that lacks a downlink/parent may indicate corruption.  However, we
 * must account for the fact that a missing downlink can occasionally be
 * encountered in a non-corrupt index.  This can be due to an interrupted page
 * split, or an interrupted multi-level page deletion (i.e. there was a hard
 * crash or an error during a page split, or while VACUUM was deleting a
 * multi-level chain of pages).
 *
 * Note that this can only be called in readonly mode, so there is no need to
 * be concerned about concurrent page splits or page deletions.
 */
static void
bt_downlink_missing_check(BtreeCheckState *state)
{
    BTPageOpaque topaque = (BTPageOpaque) PageGetSpecialPointer(state->target);
    ItemId      itemid;
    IndexTuple  itup;
    Page        child;
    BTPageOpaque copaque;
    uint32      level;
    BlockNumber childblk;

    Assert(state->heapallindexed && state->readonly);
    Assert(!P_IGNORE(topaque));

    /* No next level up with downlinks to fingerprint from the true root */
    if (P_ISROOT(topaque))
        return;

    /*
     * Incomplete (interrupted) page splits can account for the lack of a
     * downlink.  Some inserting transaction should eventually complete the
     * page split in passing, when it notices that the left sibling page is
     * P_INCOMPLETE_SPLIT().
     *
     * In general, VACUUM is not prepared for there to be no downlink to a
     * page that it deletes.  This is the main reason why the lack of a
     * downlink can be reported as corruption here.  It's not obvious that an
     * invalid missing downlink can result in wrong answers to queries,
     * though, since index scans that land on the child may end up
     * consistently moving right. The handling of concurrent page splits (and
     * page deletions) within _bt_moveright() cannot distinguish
     * inconsistencies that last for a moment from inconsistencies that are
     * permanent and irrecoverable.
     *
     * VACUUM isn't even prepared to delete pages that have no downlink due to
     * an incomplete page split, but it can detect and reason about that case
     * by design, so it shouldn't be taken to indicate corruption.  See
     * _bt_pagedel() for full details.
     */
    if (state->rightsplit)
    {
        ereport(DEBUG1,
                (errcode(ERRCODE_NO_DATA),
                 errmsg("harmless interrupted page split detected in index %s",
                        RelationGetRelationName(state->rel)),
                 errdetail_internal("Block=%u level=%u left sibling=%u page lsn=%X/%X.",
                                    state->targetblock, topaque->btpo.level,
                                    topaque->btpo_prev,
                                    (uint32) (state->targetlsn >> 32),
                                    (uint32) state->targetlsn)));
        return;
    }

    /* Target's downlink is typically present in parent/fingerprinted */
    if (!bloom_lacks_element(state->downlinkfilter,
                             (unsigned char *) &state->targetblock,
                             sizeof(BlockNumber)))
        return;

    /*
     * Target is probably the "top parent" of a multi-level page deletion.
     * We'll need to descend the subtree to make sure that descendant pages
     * are consistent with that, though.
     *
     * If the target page (which must be non-ignorable) is a leaf page, then
     * clearly it can't be the top parent.  The lack of a downlink is probably
     * a symptom of a broad problem that could just as easily cause
     * inconsistencies anywhere else.
     */
    if (P_ISLEAF(topaque))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("leaf index block lacks downlink in index \"%s\"",
                        RelationGetRelationName(state->rel)),
                 errdetail_internal("Block=%u page lsn=%X/%X.",
                                    state->targetblock,
                                    (uint32) (state->targetlsn >> 32),
                                    (uint32) state->targetlsn)));

    /* Descend from the target page, which is an internal page */
    elog(DEBUG1, "checking for interrupted multi-level deletion due to missing downlink in index \"%s\"",
         RelationGetRelationName(state->rel));

    level = topaque->btpo.level;
    itemid = PageGetItemIdCareful(state, state->targetblock, state->target,
                                  P_FIRSTDATAKEY(topaque));
    itup = (IndexTuple) PageGetItem(state->target, itemid);
    childblk = BTreeTupleGetDownLink(itup);
    for (;;)
    {
        CHECK_FOR_INTERRUPTS();

        child = palloc_btree_page(state, childblk);
        copaque = (BTPageOpaque) PageGetSpecialPointer(child);

        if (P_ISLEAF(copaque))
            break;

        /* Do an extra sanity check in passing on internal pages */
        if (copaque->btpo.level != level - 1)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg_internal("downlink points to block in index \"%s\" whose level is not one level down",
                                     RelationGetRelationName(state->rel)),
                     errdetail_internal("Top parent/target block=%u block pointed to=%u expected level=%u level in pointed to block=%u.",
                                        state->targetblock, childblk,
                                        level - 1, copaque->btpo.level)));

        level = copaque->btpo.level;
        itemid = PageGetItemIdCareful(state, childblk, child,
                                      P_FIRSTDATAKEY(copaque));
        itup = (IndexTuple) PageGetItem(child, itemid);
        childblk = BTreeTupleGetDownLink(itup);
        /* Be slightly more pro-active in freeing this memory, just in case */
        pfree(child);
    }

    /*
     * Since there cannot be a concurrent VACUUM operation in readonly mode,
     * and since a page has no links within other pages (siblings and parent)
     * once it is marked fully deleted, it should be impossible to land on a
     * fully deleted page.  See bt_downlink_check() for further details.
     *
     * The bt_downlink_check() P_ISDELETED() check is repeated here because
     * bt_downlink_check() does not visit pages reachable through negative
     * infinity items.  Besides, bt_downlink_check() is unwilling to descend
     * multiple levels.  (The similar bt_downlink_check() P_ISDELETED() check
     * within bt_check_level_from_leftmost() won't reach the page either,
     * since the leaf's live siblings should have their sibling links updated
     * to bypass the deletion target page when it is marked fully dead.)
     *
     * If this error is raised, it might be due to a previous multi-level page
     * deletion that failed to realize that it wasn't yet safe to mark the
     * leaf page as fully dead.  A "dangling downlink" will still remain when
     * this happens.  The fact that the dangling downlink's page (the leaf's
     * parent/ancestor page) lacked a downlink is incidental.
     */
    if (P_ISDELETED(copaque))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg_internal("downlink to deleted leaf page found in index \"%s\"",
                                 RelationGetRelationName(state->rel)),
                 errdetail_internal("Top parent/target block=%u leaf block=%u top parent/target lsn=%X/%X.",
                                    state->targetblock, childblk,
                                    (uint32) (state->targetlsn >> 32),
                                    (uint32) state->targetlsn)));

    /*
     * Iff leaf page is half-dead, its high key top parent link should point
     * to what VACUUM considered to be the top parent page at the instant it
     * was interrupted.  Provided the high key link actually points to the
     * target page, the missing downlink we detected is consistent with there
     * having been an interrupted multi-level page deletion.  This means that
     * the subtree with the target page at its root (a page deletion chain) is
     * in a consistent state, enabling VACUUM to resume deleting the entire
     * chain the next time it encounters the half-dead leaf page.
     */
    if (P_ISHALFDEAD(copaque) && !P_RIGHTMOST(copaque))
    {
        itemid = PageGetItemIdCareful(state, childblk, child, P_HIKEY);
        itup = (IndexTuple) PageGetItem(child, itemid);
        if (BTreeTupleGetTopParent(itup) == state->targetblock)
            return;
    }

    ereport(ERROR,
            (errcode(ERRCODE_INDEX_CORRUPTED),
             errmsg("internal index block lacks downlink in index \"%s\"",
                    RelationGetRelationName(state->rel)),
             errdetail_internal("Block=%u level=%u page lsn=%X/%X.",
                                state->targetblock, topaque->btpo.level,
                                (uint32) (state->targetlsn >> 32),
                                (uint32) state->targetlsn)));
}

/*
 * Per-tuple callback from table_index_build_scan, used to determine if index has
 * all the entries that definitely should have been observed in leaf pages of
 * the target index (that is, all IndexTuples that were fingerprinted by our
 * Bloom filter).  All heapallindexed checks occur here.
 *
 * The redundancy between an index and the table it indexes provides a good
 * opportunity to detect corruption, especially corruption within the table.
 * The high level principle behind the verification performed here is that any
 * IndexTuple that should be in an index following a fresh CREATE INDEX (based
 * on the same index definition) should also have been in the original,
 * existing index, which should have used exactly the same representation
 *
 * Since the overall structure of the index has already been verified, the most
 * likely explanation for error here is a corrupt heap page (could be logical
 * or physical corruption).  Index corruption may still be detected here,
 * though.  Only readonly callers will have verified that left links and right
 * links are in agreement, and so it's possible that a leaf page transposition
 * within index is actually the source of corruption detected here (for
 * !readonly callers).  The checks performed only for readonly callers might
 * more accurately frame the problem as a cross-page invariant issue (this
 * could even be due to recovery not replaying all WAL records).  The !readonly
 * ERROR message raised here includes a HINT about retrying with readonly
 * verification, just in case it's a cross-page invariant issue, though that
 * isn't particularly likely.
 *
 * table_index_build_scan() expects to be able to find the root tuple when a
 * heap-only tuple (the live tuple at the end of some HOT chain) needs to be
 * indexed, in order to replace the actual tuple's TID with the root tuple's
 * TID (which is what we're actually passed back here).  The index build heap
 * scan code will raise an error when a tuple that claims to be the root of the
 * heap-only tuple's HOT chain cannot be located.  This catches cases where the
 * original root item offset/root tuple for a HOT chain indicates (for whatever
 * reason) that the entire HOT chain is dead, despite the fact that the latest
 * heap-only tuple should be indexed.  When this happens, sequential scans may
 * always give correct answers, and all indexes may be considered structurally
 * consistent (i.e. the nbtree structural checks would not detect corruption).
 * It may be the case that only index scans give wrong answers, and yet heap or
 * SLRU corruption is the real culprit.  (While it's true that LP_DEAD bit
 * setting will probably also leave the index in a corrupt state before too
 * long, the problem is nonetheless that there is heap corruption.)
 *
 * Heap-only tuple handling within table_index_build_scan() works in a way that
 * helps us to detect index tuples that contain the wrong values (values that
 * don't match the latest tuple in the HOT chain).  This can happen when there
 * is no superseding index tuple due to a faulty assessment of HOT safety,
 * perhaps during the original CREATE INDEX.  Because the latest tuple's
 * contents are used with the root TID, an error will be raised when a tuple
 * with the same TID but non-matching attribute values is passed back to us.
 * Faulty assessment of HOT-safety was behind at least two distinct CREATE
 * INDEX CONCURRENTLY bugs that made it into stable releases, one of which was
 * undetected for many years.  In short, the same principle that allows a
 * REINDEX to repair corruption when there was an (undetected) broken HOT chain
 * also allows us to detect the corruption in many cases.
 */
static void
bt_tuple_present_callback(Relation index, ItemPointer tid, Datum *values,
                          bool *isnull, bool tupleIsAlive, void *checkstate)
{
    BtreeCheckState *state = (BtreeCheckState *) checkstate;
    IndexTuple  itup,
                norm;

    Assert(state->heapallindexed);

    /* Generate a normalized index tuple for fingerprinting */
    itup = index_form_tuple(RelationGetDescr(index), values, isnull);
    itup->t_tid = *tid;
    norm = bt_normalize_tuple(state, itup);

    /* Probe Bloom filter -- tuple should be present */
    if (bloom_lacks_element(state->filter, (unsigned char *) norm,
                            IndexTupleSize(norm)))
        ereport(ERROR,
                (errcode(ERRCODE_DATA_CORRUPTED),
                 errmsg("heap tuple (%u,%u) from table \"%s\" lacks matching index tuple within index \"%s\"",
                        ItemPointerGetBlockNumber(&(itup->t_tid)),
                        ItemPointerGetOffsetNumber(&(itup->t_tid)),
                        RelationGetRelationName(state->heaprel),
                        RelationGetRelationName(state->rel)),
                 !state->readonly
                 ? errhint("Retrying verification using the function bt_index_parent_check() might provide a more specific error.")
                 : 0));

    state->heaptuplespresent++;
    pfree(itup);
    /* Cannot leak memory here */
    if (norm != itup)
        pfree(norm);
}

/*
 * Normalize an index tuple for fingerprinting.
 *
 * In general, index tuple formation is assumed to be deterministic by
 * heapallindexed verification, and IndexTuples are assumed immutable.  While
 * the LP_DEAD bit is mutable in leaf pages, that's ItemId metadata, which is
 * not fingerprinted.  Normalization is required to compensate for corner
 * cases where the determinism assumption doesn't quite work.
 *
 * There is currently one such case: index_form_tuple() does not try to hide
 * the source TOAST state of input datums.  The executor applies TOAST
 * compression for heap tuples based on different criteria to the compression
 * applied within btinsert()'s call to index_form_tuple(): it sometimes
 * compresses more aggressively, resulting in compressed heap tuple datums but
 * uncompressed corresponding index tuple datums.  A subsequent heapallindexed
 * verification will get a logically equivalent though bitwise unequal tuple
 * from index_form_tuple().  False positive heapallindexed corruption reports
 * could occur without normalizing away the inconsistency.
 *
 * Returned tuple is often caller's own original tuple.  Otherwise, it is a
 * new representation of caller's original index tuple, palloc()'d in caller's
 * memory context.
 *
 * Note: This routine is not concerned with distinctions about the
 * representation of tuples beyond those that might break heapallindexed
 * verification.  In particular, it won't try to normalize opclass-equal
 * datums with potentially distinct representations (e.g., btree/numeric_ops
 * index datums will not get their display scale normalized-away here).
 * Normalization may need to be expanded to handle more cases in the future,
 * though.  For example, it's possible that non-pivot tuples could in the
 * future have alternative logically equivalent representations due to using
 * the INDEX_ALT_TID_MASK bit to implement intelligent deduplication.
 */
static IndexTuple
bt_normalize_tuple(BtreeCheckState *state, IndexTuple itup)
{
    TupleDesc   tupleDescriptor = RelationGetDescr(state->rel);
    Datum       normalized[INDEX_MAX_KEYS];
    bool        isnull[INDEX_MAX_KEYS];
    bool        toast_free[INDEX_MAX_KEYS];
    bool        formnewtup = false;
    IndexTuple  reformed;
    int         i;

    /* Easy case: It's immediately clear that tuple has no varlena datums */
    if (!IndexTupleHasVarwidths(itup))
        return itup;

    for (i = 0; i < tupleDescriptor->natts; i++)
    {
        Form_pg_attribute att;

        att = TupleDescAttr(tupleDescriptor, i);

        /* Assume untoasted/already normalized datum initially */
        toast_free[i] = false;
        normalized[i] = index_getattr(itup, att->attnum,
                                      tupleDescriptor,
                                      &isnull[i]);
        if (att->attbyval || att->attlen != -1 || isnull[i])
            continue;

        /*
         * Callers always pass a tuple that could safely be inserted into the
         * index without further processing, so an external varlena header
         * should never be encountered here
         */
        if (VARATT_IS_EXTERNAL(DatumGetPointer(normalized[i])))
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("external varlena datum in tuple that references heap row (%u,%u) in index \"%s\"",
                            ItemPointerGetBlockNumber(&(itup->t_tid)),
                            ItemPointerGetOffsetNumber(&(itup->t_tid)),
                            RelationGetRelationName(state->rel))));
        else if (VARATT_IS_COMPRESSED(DatumGetPointer(normalized[i])))
        {
            formnewtup = true;
            normalized[i] = PointerGetDatum(PG_DETOAST_DATUM(normalized[i]));
            toast_free[i] = true;
        }
    }

    /* Easier case: Tuple has varlena datums, none of which are compressed */
    if (!formnewtup)
        return itup;

    /*
     * Hard case: Tuple had compressed varlena datums that necessitate
     * creating normalized version of the tuple from uncompressed input datums
     * (normalized input datums).  This is rather naive, but shouldn't be
     * necessary too often.
     *
     * Note that we rely on deterministic index_form_tuple() TOAST compression
     * of normalized input.
     */
    reformed = index_form_tuple(tupleDescriptor, normalized, isnull);
    reformed->t_tid = itup->t_tid;

    /* Cannot leak memory here */
    for (i = 0; i < tupleDescriptor->natts; i++)
        if (toast_free[i])
            pfree(DatumGetPointer(normalized[i]));

    return reformed;
}

/*
 * Search for itup in index, starting from fast root page.  itup must be a
 * non-pivot tuple.  This is only supported with heapkeyspace indexes, since
 * we rely on having fully unique keys to find a match with only a single
 * visit to a leaf page, barring an interrupted page split, where we may have
 * to move right.  (A concurrent page split is impossible because caller must
 * be readonly caller.)
 *
 * This routine can detect very subtle transitive consistency issues across
 * more than one level of the tree.  Leaf pages all have a high key (even the
 * rightmost page has a conceptual positive infinity high key), but not a low
 * key.  Their downlink in parent is a lower bound, which along with the high
 * key is almost enough to detect every possible inconsistency.  A downlink
 * separator key value won't always be available from parent, though, because
 * the first items of internal pages are negative infinity items, truncated
 * down to zero attributes during internal page splits.  While it's true that
 * bt_downlink_check() and the high key check can detect most imaginable key
 * space problems, there are remaining problems it won't detect with non-pivot
 * tuples in cousin leaf pages.  Starting a search from the root for every
 * existing leaf tuple detects small inconsistencies in upper levels of the
 * tree that cannot be detected any other way.  (Besides all this, this is
 * probably also useful as a direct test of the code used by index scans
 * themselves.)
 */
static bool
bt_rootdescend(BtreeCheckState *state, IndexTuple itup)
{
    BTScanInsert key;
    BTStack     stack;
    Buffer      lbuf;
    bool        exists;

    key = _bt_mkscankey(state->rel, itup);
    Assert(key->heapkeyspace && key->scantid != NULL);

    /*
     * Search from root.
     *
     * Ideally, we would arrange to only move right within _bt_search() when
     * an interrupted page split is detected (i.e. when the incomplete split
     * bit is found to be set), but for now we accept the possibility that
     * that could conceal an inconsistency.
     */
    Assert(state->readonly && state->rootdescend);
    exists = false;
    stack = _bt_search(state->rel, key, &lbuf, BT_READ, NULL);

    if (BufferIsValid(lbuf))
    {
        BTInsertStateData insertstate;
        OffsetNumber offnum;
        Page        page;

        insertstate.itup = itup;
        insertstate.itemsz = MAXALIGN(IndexTupleSize(itup));
        insertstate.itup_key = key;
        insertstate.bounds_valid = false;
        insertstate.buf = lbuf;

        /* Get matching tuple on leaf page */
        offnum = _bt_binsrch_insert(state->rel, &insertstate);
        /* Compare first >= matching item on leaf page, if any */
        page = BufferGetPage(lbuf);
        if (offnum <= PageGetMaxOffsetNumber(page) &&
            _bt_compare(state->rel, key, page, offnum) == 0)
            exists = true;
        _bt_relbuf(state->rel, lbuf);
    }

    _bt_freestack(stack);
    pfree(key);

    return exists;
}

/*
 * Is particular offset within page (whose special state is passed by caller)
 * the page negative-infinity item?
 *
 * As noted in comments above _bt_compare(), there is special handling of the
 * first data item as a "negative infinity" item.  The hard-coding within
 * _bt_compare() makes comparing this item for the purposes of verification
 * pointless at best, since the IndexTuple only contains a valid TID (a
 * reference TID to child page).
 */
static inline bool
offset_is_negative_infinity(BTPageOpaque opaque, OffsetNumber offset)
{
    /*
     * For internal pages only, the first item after high key, if any, is
     * negative infinity item.  Internal pages always have a negative infinity
     * item, whereas leaf pages never have one.  This implies that negative
     * infinity item is either first or second line item, or there is none
     * within page.
     *
     * Negative infinity items are a special case among pivot tuples.  They
     * always have zero attributes, while all other pivot tuples always have
     * nkeyatts attributes.
     *
     * Right-most pages don't have a high key, but could be said to
     * conceptually have a "positive infinity" high key.  Thus, there is a
     * symmetry between down link items in parent pages, and high keys in
     * children.  Together, they represent the part of the key space that
     * belongs to each page in the index.  For example, all children of the
     * root page will have negative infinity as a lower bound from root
     * negative infinity downlink, and positive infinity as an upper bound
     * (implicitly, from "imaginary" positive infinity high key in root).
     */
    return !P_ISLEAF(opaque) && offset == P_FIRSTDATAKEY(opaque);
}

/*
 * Does the invariant hold that the key is strictly less than a given upper
 * bound offset item?
 *
 * Verifies line pointer on behalf of caller.
 *
 * If this function returns false, convention is that caller throws error due
 * to corruption.
 */
static inline bool
invariant_l_offset(BtreeCheckState *state, BTScanInsert key,
                   OffsetNumber upperbound)
{
    ItemId      itemid;
    int32       cmp;

    Assert(key->pivotsearch);

    /* Verify line pointer before checking tuple */
    itemid = PageGetItemIdCareful(state, state->targetblock, state->target,
                                  upperbound);
    /* pg_upgrade'd indexes may legally have equal sibling tuples */
    if (!key->heapkeyspace)
        return invariant_leq_offset(state, key, upperbound);

    cmp = _bt_compare(state->rel, key, state->target, upperbound);

    /*
     * _bt_compare() is capable of determining that a scankey with a
     * filled-out attribute is greater than pivot tuples where the comparison
     * is resolved at a truncated attribute (value of attribute in pivot is
     * minus infinity).  However, it is not capable of determining that a
     * scankey is _less than_ a tuple on the basis of a comparison resolved at
     * _scankey_ minus infinity attribute.  Complete an extra step to simulate
     * having minus infinity values for omitted scankey attribute(s).
     */
    if (cmp == 0)
    {
        BTPageOpaque topaque;
        IndexTuple  ritup;
        int         uppnkeyatts;
        ItemPointer rheaptid;
        bool        nonpivot;

        ritup = (IndexTuple) PageGetItem(state->target, itemid);
        topaque = (BTPageOpaque) PageGetSpecialPointer(state->target);
        nonpivot = P_ISLEAF(topaque) && upperbound >= P_FIRSTDATAKEY(topaque);

        /* Get number of keys + heap TID for item to the right */
        uppnkeyatts = BTreeTupleGetNKeyAtts(ritup, state->rel);
        rheaptid = BTreeTupleGetHeapTIDCareful(state, ritup, nonpivot);

        /* Heap TID is tiebreaker key attribute */
        if (key->keysz == uppnkeyatts)
            return key->scantid == NULL && rheaptid != NULL;

        return key->keysz < uppnkeyatts;
    }

    return cmp < 0;
}

/*
 * Does the invariant hold that the key is less than or equal to a given upper
 * bound offset item?
 *
 * Caller should have verified that upperbound's line pointer is consistent
 * using PageGetItemIdCareful() call.
 *
 * If this function returns false, convention is that caller throws error due
 * to corruption.
 */
static inline bool
invariant_leq_offset(BtreeCheckState *state, BTScanInsert key,
                     OffsetNumber upperbound)
{
    int32       cmp;

    Assert(key->pivotsearch);

    cmp = _bt_compare(state->rel, key, state->target, upperbound);

    return cmp <= 0;
}

/*
 * Does the invariant hold that the key is strictly greater than a given lower
 * bound offset item?
 *
 * Caller should have verified that lowerbound's line pointer is consistent
 * using PageGetItemIdCareful() call.
 *
 * If this function returns false, convention is that caller throws error due
 * to corruption.
 */
static inline bool
invariant_g_offset(BtreeCheckState *state, BTScanInsert key,
                   OffsetNumber lowerbound)
{
    int32       cmp;

    Assert(key->pivotsearch);

    cmp = _bt_compare(state->rel, key, state->target, lowerbound);

    /* pg_upgrade'd indexes may legally have equal sibling tuples */
    if (!key->heapkeyspace)
        return cmp >= 0;

    /*
     * No need to consider the possibility that scankey has attributes that we
     * need to force to be interpreted as negative infinity.  _bt_compare() is
     * able to determine that scankey is greater than negative infinity.  The
     * distinction between "==" and "<" isn't interesting here, since
     * corruption is indicated either way.
     */
    return cmp > 0;
}

/*
 * Does the invariant hold that the key is strictly less than a given upper
 * bound offset item, with the offset relating to a caller-supplied page that
 * is not the current target page?
 *
 * Caller's non-target page is a child page of the target, checked as part of
 * checking a property of the target page (i.e. the key comes from the
 * target).  Verifies line pointer on behalf of caller.
 *
 * If this function returns false, convention is that caller throws error due
 * to corruption.
 */
static inline bool
invariant_l_nontarget_offset(BtreeCheckState *state, BTScanInsert key,
                             BlockNumber nontargetblock, Page nontarget,
                             OffsetNumber upperbound)
{
    ItemId      itemid;
    int32       cmp;

    Assert(key->pivotsearch);

    /* Verify line pointer before checking tuple */
    itemid = PageGetItemIdCareful(state, nontargetblock, nontarget,
                                  upperbound);
    cmp = _bt_compare(state->rel, key, nontarget, upperbound);

    /* pg_upgrade'd indexes may legally have equal sibling tuples */
    if (!key->heapkeyspace)
        return cmp <= 0;

    /* See invariant_l_offset() for an explanation of this extra step */
    if (cmp == 0)
    {
        IndexTuple  child;
        int         uppnkeyatts;
        ItemPointer childheaptid;
        BTPageOpaque copaque;
        bool        nonpivot;

        child = (IndexTuple) PageGetItem(nontarget, itemid);
        copaque = (BTPageOpaque) PageGetSpecialPointer(nontarget);
        nonpivot = P_ISLEAF(copaque) && upperbound >= P_FIRSTDATAKEY(copaque);

        /* Get number of keys + heap TID for child/non-target item */
        uppnkeyatts = BTreeTupleGetNKeyAtts(child, state->rel);
        childheaptid = BTreeTupleGetHeapTIDCareful(state, child, nonpivot);

        /* Heap TID is tiebreaker key attribute */
        if (key->keysz == uppnkeyatts)
            return key->scantid == NULL && childheaptid != NULL;

        return key->keysz < uppnkeyatts;
    }

    return cmp < 0;
}

/*
 * Given a block number of a B-Tree page, return page in palloc()'d memory.
 * While at it, perform some basic checks of the page.
 *
 * There is never an attempt to get a consistent view of multiple pages using
 * multiple concurrent buffer locks; in general, we only acquire a single pin
 * and buffer lock at a time, which is often all that the nbtree code requires.
 *
 * Operating on a copy of the page is useful because it prevents control
 * getting stuck in an uninterruptible state when an underlying operator class
 * misbehaves.
 */
static Page
palloc_btree_page(BtreeCheckState *state, BlockNumber blocknum)
{
    Buffer      buffer;
    Page        page;
    BTPageOpaque opaque;
    OffsetNumber maxoffset;

    page = palloc(BLCKSZ);

    /*
     * We copy the page into local storage to avoid holding pin on the buffer
     * longer than we must.
     */
    buffer = ReadBufferExtended(state->rel, MAIN_FORKNUM, blocknum, RBM_NORMAL,
                                state->checkstrategy);
    LockBuffer(buffer, BT_READ);

    /*
     * Perform the same basic sanity checking that nbtree itself performs for
     * every page:
     */
    _bt_checkpage(state->rel, buffer);

    /* Only use copy of page in palloc()'d memory */
    memcpy(page, BufferGetPage(buffer), BLCKSZ);
    UnlockReleaseBuffer(buffer);

    opaque = (BTPageOpaque) PageGetSpecialPointer(page);

    if (P_ISMETA(opaque) && blocknum != BTREE_METAPAGE)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("invalid meta page found at block %u in index \"%s\"",
                        blocknum, RelationGetRelationName(state->rel))));

    /* Check page from block that ought to be meta page */
    if (blocknum == BTREE_METAPAGE)
    {
        BTMetaPageData *metad = BTPageGetMeta(page);

        if (!P_ISMETA(opaque) ||
            metad->btm_magic != BTREE_MAGIC)
            ereport(ERROR,
                    (errcode(ERRCODE_INDEX_CORRUPTED),
                     errmsg("index \"%s\" meta page is corrupt",
                            RelationGetRelationName(state->rel))));

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

        /* Finished with metapage checks */
        return page;
    }

    /*
     * Deleted pages have no sane "level" field, so can only check non-deleted
     * page level
     */
    if (P_ISLEAF(opaque) && !P_ISDELETED(opaque) && opaque->btpo.level != 0)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("invalid leaf page level %u for block %u in index \"%s\"",
                        opaque->btpo.level, blocknum, RelationGetRelationName(state->rel))));

    if (!P_ISLEAF(opaque) && !P_ISDELETED(opaque) &&
        opaque->btpo.level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("invalid internal page level 0 for block %u in index \"%s\"",
                        blocknum, RelationGetRelationName(state->rel))));

    /*
     * Sanity checks for number of items on page.
     *
     * As noted at the beginning of _bt_binsrch(), an internal page must have
     * children, since there must always be a negative infinity downlink
     * (there may also be a highkey).  In the case of non-rightmost leaf
     * pages, there must be at least a highkey.
     *
     * This is correct when pages are half-dead, since internal pages are
     * never half-dead, and leaf pages must have a high key when half-dead
     * (the rightmost page can never be deleted).  It's also correct with
     * fully deleted pages: _bt_unlink_halfdead_page() doesn't change anything
     * about the target page other than setting the page as fully dead, and
     * setting its xact field.  In particular, it doesn't change the sibling
     * links in the deletion target itself, since they're required when index
     * scans land on the deletion target, and then need to move right (or need
     * to move left, in the case of backward index scans).
     */
    maxoffset = PageGetMaxOffsetNumber(page);
    if (maxoffset > MaxIndexTuplesPerPage)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("Number of items on block %u of index \"%s\" exceeds MaxIndexTuplesPerPage (%u)",
                        blocknum, RelationGetRelationName(state->rel),
                        MaxIndexTuplesPerPage)));

    if (!P_ISLEAF(opaque) && maxoffset < P_FIRSTDATAKEY(opaque))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("internal block %u in index \"%s\" lacks high key and/or at least one downlink",
                        blocknum, RelationGetRelationName(state->rel))));

    if (P_ISLEAF(opaque) && !P_RIGHTMOST(opaque) && maxoffset < P_HIKEY)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("non-rightmost leaf block %u in index \"%s\" lacks high key item",
                        blocknum, RelationGetRelationName(state->rel))));

    /*
     * In general, internal pages are never marked half-dead, except on
     * versions of Postgres prior to 9.4, where it can be valid transient
     * state.  This state is nonetheless treated as corruption by VACUUM on
     * from version 9.4 on, so do the same here.  See _bt_pagedel() for full
     * details.
     *
     * Internal pages should never have garbage items, either.
     */
    if (!P_ISLEAF(opaque) && P_ISHALFDEAD(opaque))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("internal page block %u in index \"%s\" is half-dead",
                        blocknum, RelationGetRelationName(state->rel)),
                 errhint("This can be caused by an interrupted VACUUM in version 9.3 or older, before upgrade. Please REINDEX it.")));

    if (!P_ISLEAF(opaque) && P_HAS_GARBAGE(opaque))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("internal page block %u in index \"%s\" has garbage items",
                        blocknum, RelationGetRelationName(state->rel))));

    return page;
}

/*
 * _bt_mkscankey() wrapper that automatically prevents insertion scankey from
 * being considered greater than the pivot tuple that its values originated
 * from (or some other identical pivot tuple) in the common case where there
 * are truncated/minus infinity attributes.  Without this extra step, there
 * are forms of corruption that amcheck could theoretically fail to report.
 *
 * For example, invariant_g_offset() might miss a cross-page invariant failure
 * on an internal level if the scankey built from the first item on the
 * target's right sibling page happened to be equal to (not greater than) the
 * last item on target page.  The !pivotsearch tiebreaker in _bt_compare()
 * might otherwise cause amcheck to assume (rather than actually verify) that
 * the scankey is greater.
 */
static inline BTScanInsert
bt_mkscankey_pivotsearch(Relation rel, IndexTuple itup)
{
    BTScanInsert skey;

    skey = _bt_mkscankey(rel, itup);
    skey->pivotsearch = true;

    return skey;
}

/*
 * PageGetItemId() wrapper that validates returned line pointer.
 *
 * Buffer page/page item access macros generally trust that line pointers are
 * not corrupt, which might cause problems for verification itself.  For
 * example, there is no bounds checking in PageGetItem().  Passing it a
 * corrupt line pointer can cause it to return a tuple/pointer that is unsafe
 * to dereference.
 *
 * Validating line pointers before tuples avoids undefined behavior and
 * assertion failures with corrupt indexes, making the verification process
 * more robust and predictable.
 */
static ItemId
PageGetItemIdCareful(BtreeCheckState *state, BlockNumber block, Page page,
                     OffsetNumber offset)
{
    ItemId      itemid = PageGetItemId(page, offset);

    if (ItemIdGetOffset(itemid) + ItemIdGetLength(itemid) >
        BLCKSZ - sizeof(BTPageOpaqueData))
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("line pointer points past end of tuple space in index \"%s\"",
                        RelationGetRelationName(state->rel)),
                 errdetail_internal("Index tid=(%u,%u) lp_off=%u, lp_len=%u lp_flags=%u.",
                                    block, offset, ItemIdGetOffset(itemid),
                                    ItemIdGetLength(itemid),
                                    ItemIdGetFlags(itemid))));

    /*
     * Verify that line pointer isn't LP_REDIRECT or LP_UNUSED, since nbtree
     * never uses either.  Verify that line pointer has storage, too, since
     * even LP_DEAD items should within nbtree.
     */
    if (ItemIdIsRedirected(itemid) || !ItemIdIsUsed(itemid) ||
        ItemIdGetLength(itemid) == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("invalid line pointer storage in index \"%s\"",
                        RelationGetRelationName(state->rel)),
                 errdetail_internal("Index tid=(%u,%u) lp_off=%u, lp_len=%u lp_flags=%u.",
                                    block, offset, ItemIdGetOffset(itemid),
                                    ItemIdGetLength(itemid),
                                    ItemIdGetFlags(itemid))));

    return itemid;
}

/*
 * BTreeTupleGetHeapTID() wrapper that lets caller enforce that a heap TID must
 * be present in cases where that is mandatory.
 *
 * This doesn't add much as of BTREE_VERSION 4, since the INDEX_ALT_TID_MASK
 * bit is effectively a proxy for whether or not the tuple is a pivot tuple.
 * It may become more useful in the future, when non-pivot tuples support their
 * own alternative INDEX_ALT_TID_MASK representation.
 */
static inline ItemPointer
BTreeTupleGetHeapTIDCareful(BtreeCheckState *state, IndexTuple itup,
                            bool nonpivot)
{
    ItemPointer result = BTreeTupleGetHeapTID(itup);
    BlockNumber targetblock = state->targetblock;

    if (result == NULL && nonpivot)
        ereport(ERROR,
                (errcode(ERRCODE_INDEX_CORRUPTED),
                 errmsg("block %u or its right sibling block or child block in index \"%s\" contains non-pivot tuple that lacks a heap TID",
                        targetblock, RelationGetRelationName(state->rel))));

    return result;
}