postgresql/contrib/amcheck/verify_nbtree.c
Andres Freund 4c850ecec6 Don't include heapam.h from others headers.
heapam.h previously was included in a number of widely used
headers (e.g. execnodes.h, indirectly in executor.h, ...). That's
problematic on its own, as heapam.h contains a lot of low-level
details that don't need to be exposed that widely, but becomes more
problematic with the upcoming introduction of pluggable table storage
- it seems inappropriate for heapam.h to be included that widely
afterwards.

heapam.h was largely only included in other headers to get the
HeapScanDesc typedef (which was defined in heapam.h, even though
HeapScanDescData is defined in relscan.h). The better solution here
seems to be to just use the underlying struct (forward declared where
necessary). Similar for BulkInsertState.

Another problem was that LockTupleMode was used in executor.h - parts
of the file tried to cope without heapam.h, but due to the fact that
it indirectly included it, several subsequent violations of that goal
were not not noticed. We could just reuse the approach of declaring
parameters as int, but it seems nicer to move LockTupleMode to
lockoptions.h - that's not a perfect location, but also doesn't seem
bad.

As a number of files relied on implicitly included heapam.h, a
significant number of files grew an explicit include. It's quite
probably that a few external projects will need to do the same.

Author: Andres Freund
Reviewed-By: Alvaro Herrera
Discussion: https://postgr.es/m/20190114000701.y4ttcb74jpskkcfb@alap3.anarazel.de
2019-01-14 16:24:41 -08:00

1969 lines
74 KiB
C

/*-------------------------------------------------------------------------
*
* 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) 2017-2019, PostgreSQL Global Development Group
*
* IDENTIFICATION
* contrib/amcheck/verify_nbtree.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "access/heapam.h"
#include "access/htup_details.h"
#include "access/nbtree.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 "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)
/*
* 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;
/* ShareLock held on heap/index, rather than AccessShareLock? */
bool readonly;
/* Also verifying heap has no unindexed tuples? */
bool heapallindexed;
/* 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);
static inline void btree_index_checkable(Relation rel);
static void bt_check_every_level(Relation rel, Relation heaprel,
bool readonly, bool heapallindexed);
static BtreeLevel bt_check_level_from_leftmost(BtreeCheckState *state,
BtreeLevel level);
static void bt_target_page_check(BtreeCheckState *state);
static ScanKey bt_right_page_check_scankey(BtreeCheckState *state);
static void bt_downlink_check(BtreeCheckState *state, BlockNumber childblock,
ScanKey targetkey);
static void bt_downlink_missing_check(BtreeCheckState *state);
static void bt_tuple_present_callback(Relation index, HeapTuple htup,
Datum *values, bool *isnull,
bool tupleIsAlive, void *checkstate);
static inline bool offset_is_negative_infinity(BTPageOpaque opaque,
OffsetNumber offset);
static inline bool invariant_leq_offset(BtreeCheckState *state,
ScanKey key,
OffsetNumber upperbound);
static inline bool invariant_geq_offset(BtreeCheckState *state,
ScanKey key,
OffsetNumber lowerbound);
static inline bool invariant_leq_nontarget_offset(BtreeCheckState *state,
Page other,
ScanKey key,
OffsetNumber upperbound);
static Page palloc_btree_page(BtreeCheckState *state, BlockNumber blocknum);
/*
* 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);
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;
if (PG_NARGS() == 2)
heapallindexed = PG_GETARG_BOOL(1);
bt_index_check_internal(indrelid, true, heapallindexed);
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)
{
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 = heap_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);
/* Check index, possibly against table it is an index on */
bt_check_every_level(indrel, heaprel, parentcheck, heapallindexed);
/*
* 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)
heap_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.")));
}
/*
* 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 readonly,
bool heapallindexed)
{
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->readonly = readonly;
state->heapallindexed = heapallindexed;
if (state->heapallindexed)
{
int64 total_elems;
uint64 seed;
/* Size Bloom filter based on estimated number of tuples in index */
total_elems = (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
* IndexBuildHeapScan() 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
* IndexBuildHeapScan().
*
* 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
{
int64 total_pages;
/*
* 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().
*/
total_pages = (int64) state->rel->rd_rel->relpages;
state->downlinkfilter = bloom_create(total_pages, work_mem, seed);
}
}
/* 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);
HeapScanDesc 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 IndexBuildHeapScan(), 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 IndexBuildHeapScan() calls heap_endscan() for us.
*/
scan = heap_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));
IndexBuildHeapScan(state->heaprel, state->rel, indexinfo, true,
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 = PageGetItemId(state->target, P_FIRSTDATAKEY(opaque));
itup = (IndexTuple) PageGetItem(state->target, itemid);
nextleveldown.leftmost = BTreeInnerTupleGetDownLink(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 pages (where there is a high key at
* all -- pages that are rightmost lack one).
*
* - That within the page, every "real" item is less than or equal to 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 item stored on the page is less than or equal to the first
* "real" data item on the page to the right (if such a first item is
* available).
*
* - That tuples report that they have the expected number of attributes.
* INCLUDE index pivot tuples should not contain non-key attributes.
*
* Furthermore, when state passed shows ShareLock held, function also checks:
*
* - That all child pages respect downlinks lower bound.
*
* - 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 IndexBuildHeapScan() 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) &&
!_bt_check_natts(state->rel, state->target, P_HIKEY))
{
ItemId itemid;
IndexTuple itup;
itemid = PageGetItemId(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;
ScanKey skey;
size_t tupsize;
CHECK_FOR_INTERRUPTS();
itemid = PageGetItemId(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->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 = BTreeInnerTupleGetDownLink(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;
/* Build insertion scankey for current page offset */
skey = _bt_mkscankey(state->rel, itup);
/* Fingerprint leaf page tuples (those that point to the heap) */
if (state->heapallindexed && P_ISLEAF(topaque) && !ItemIdIsDead(itemid))
bloom_add_element(state->filter, (unsigned char *) itup, tupsize);
/*
* * 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.
*/
if (!P_RIGHTMOST(topaque) &&
!invariant_leq_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 less than or equal to next item (if any).
*/
if (OffsetNumberNext(offset) <= max &&
!invariant_leq_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 = PageGetItemId(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)
{
ScanKey rightkey;
/* Get item in next/right page */
rightkey = bt_right_page_check_scankey(state);
if (rightkey &&
!invariant_geq_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 = BTreeInnerTupleGetDownLink(itup);
bt_downlink_check(state, childblock, skey);
}
}
/*
* * 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 ScanKey
bt_right_page_check_scankey(BtreeCheckState *state)
{
BTPageOpaque opaque;
ItemId rightitem;
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 = PageGetItemId(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 = PageGetItemId(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.
*/
return _bt_mkscankey(state->rel,
(IndexTuple) PageGetItem(rightpage, rightitem));
}
/*
* 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, BlockNumber childblock,
ScanKey targetkey)
{
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.
*
* 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 an upper
* bound, but that's only because of the hard-coding within
* _bt_compare().
*/
if (offset_is_negative_infinity(copaque, offset))
continue;
if (!invariant_leq_nontarget_offset(state, child,
targetkey, 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 = PageGetItemId(state->target, P_FIRSTDATAKEY(topaque));
itup = (IndexTuple) PageGetItem(state->target, itemid);
childblk = BTreeInnerTupleGetDownLink(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 = PageGetItemId(child, P_FIRSTDATAKEY(copaque));
itup = (IndexTuple) PageGetItem(child, itemid);
childblk = BTreeInnerTupleGetDownLink(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 = PageGetItemId(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 IndexBuildHeapScan, 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.
*
* IndexBuildHeapScan() 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 IndexBuildHeapScan() 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, HeapTuple htup, Datum *values,
bool *isnull, bool tupleIsAlive, void *checkstate)
{
BtreeCheckState *state = (BtreeCheckState *) checkstate;
IndexTuple itup;
Assert(state->heapallindexed);
/*
* Generate an index tuple for fingerprinting.
*
* Index tuple formation is assumed to be deterministic, and IndexTuples
* are assumed immutable. While the LP_DEAD bit is mutable in leaf pages,
* that's ItemId metadata, which was not fingerprinted. (There will often
* be some dead-to-everyone IndexTuples fingerprinted by the Bloom filter,
* but we only try to detect the absence of needed tuples, so that's
* okay.)
*
* Note that we rely on deterministic index_form_tuple() TOAST
* compression. If index_form_tuple() was ever enhanced to compress datums
* out-of-line, or otherwise varied when or how compression was applied,
* our assumption would break, leading to false positive reports of
* corruption. It's also possible that non-pivot tuples could in the
* future have alternative equivalent representations (e.g. by using the
* INDEX_ALT_TID_MASK bit). For now, we don't decompress/normalize toasted
* values as part of fingerprinting.
*/
itup = index_form_tuple(RelationGetDescr(index), values, isnull);
itup->t_tid = htup->t_self;
/* Probe Bloom filter -- tuple should be present */
if (bloom_lacks_element(state->filter, (unsigned char *) itup,
IndexTupleSize(itup)))
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);
}
/*
* 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 less than or equal to a given upper
* bound offset item?
*
* If this function returns false, convention is that caller throws error due
* to corruption.
*/
static inline bool
invariant_leq_offset(BtreeCheckState *state, ScanKey key,
OffsetNumber upperbound)
{
int16 nkeyatts = IndexRelationGetNumberOfKeyAttributes(state->rel);
int32 cmp;
cmp = _bt_compare(state->rel, nkeyatts, key, state->target, upperbound);
return cmp <= 0;
}
/*
* Does the invariant hold that the key is greater than or equal to a given
* lower bound offset item?
*
* If this function returns false, convention is that caller throws error due
* to corruption.
*/
static inline bool
invariant_geq_offset(BtreeCheckState *state, ScanKey key,
OffsetNumber lowerbound)
{
int16 nkeyatts = IndexRelationGetNumberOfKeyAttributes(state->rel);
int32 cmp;
cmp = _bt_compare(state->rel, nkeyatts, key, state->target, lowerbound);
return cmp >= 0;
}
/*
* Does the invariant hold that the key is less than or equal to 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 typically 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).
*
* If this function returns false, convention is that caller throws error due
* to corruption.
*/
static inline bool
invariant_leq_nontarget_offset(BtreeCheckState *state,
Page nontarget, ScanKey key,
OffsetNumber upperbound)
{
int16 nkeyatts = IndexRelationGetNumberOfKeyAttributes(state->rel);
int32 cmp;
cmp = _bt_compare(state->rel, nkeyatts, key, nontarget, upperbound);
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;
}