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postgresql/src/backend/access/nbtree/nbtinsert.c

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/*-------------------------------------------------------------------------
*
* nbtinsert.c
* Item insertion in Lehman and Yao btrees for Postgres.
*
* Portions Copyright (c) 1996-2018, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/access/nbtree/nbtinsert.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "access/heapam.h"
#include "access/nbtree.h"
#include "access/nbtxlog.h"
#include "access/transam.h"
#include "access/xloginsert.h"
#include "miscadmin.h"
#include "storage/lmgr.h"
#include "storage/predicate.h"
#include "storage/smgr.h"
#include "utils/tqual.h"
typedef struct
{
/* context data for _bt_checksplitloc */
Size newitemsz; /* size of new item to be inserted */
int fillfactor; /* needed when splitting rightmost page */
bool is_leaf; /* T if splitting a leaf page */
bool is_rightmost; /* T if splitting a rightmost page */
OffsetNumber newitemoff; /* where the new item is to be inserted */
int leftspace; /* space available for items on left page */
int rightspace; /* space available for items on right page */
int olddataitemstotal; /* space taken by old items */
bool have_split; /* found a valid split? */
/* these fields valid only if have_split is true */
bool newitemonleft; /* new item on left or right of best split */
OffsetNumber firstright; /* best split point */
int best_delta; /* best size delta so far */
} FindSplitData;
static Buffer _bt_newroot(Relation rel, Buffer lbuf, Buffer rbuf);
static TransactionId _bt_check_unique(Relation rel, IndexTuple itup,
Relation heapRel, Buffer buf, OffsetNumber offset,
ScanKey itup_scankey,
IndexUniqueCheck checkUnique, bool *is_unique,
uint32 *speculativeToken);
static void _bt_findinsertloc(Relation rel,
Buffer *bufptr,
OffsetNumber *offsetptr,
int keysz,
ScanKey scankey,
IndexTuple newtup,
BTStack stack,
Relation heapRel);
static void _bt_insertonpg(Relation rel, Buffer buf, Buffer cbuf,
BTStack stack,
IndexTuple itup,
OffsetNumber newitemoff,
bool split_only_page);
static Buffer _bt_split(Relation rel, Buffer buf, Buffer cbuf,
OffsetNumber firstright, OffsetNumber newitemoff, Size newitemsz,
IndexTuple newitem, bool newitemonleft);
static void _bt_insert_parent(Relation rel, Buffer buf, Buffer rbuf,
BTStack stack, bool is_root, bool is_only);
static OffsetNumber _bt_findsplitloc(Relation rel, Page page,
OffsetNumber newitemoff,
Size newitemsz,
bool *newitemonleft);
static void _bt_checksplitloc(FindSplitData *state,
OffsetNumber firstoldonright, bool newitemonleft,
int dataitemstoleft, Size firstoldonrightsz);
static bool _bt_pgaddtup(Page page, Size itemsize, IndexTuple itup,
OffsetNumber itup_off);
static bool _bt_isequal(TupleDesc itupdesc, Page page, OffsetNumber offnum,
int keysz, ScanKey scankey);
static void _bt_vacuum_one_page(Relation rel, Buffer buffer, Relation heapRel);
/*
* _bt_doinsert() -- Handle insertion of a single index tuple in the tree.
*
* This routine is called by the public interface routine, btinsert.
* By here, itup is filled in, including the TID.
*
* If checkUnique is UNIQUE_CHECK_NO or UNIQUE_CHECK_PARTIAL, this
* will allow duplicates. Otherwise (UNIQUE_CHECK_YES or
* UNIQUE_CHECK_EXISTING) it will throw error for a duplicate.
* For UNIQUE_CHECK_EXISTING we merely run the duplicate check, and
* don't actually insert.
*
* The result value is only significant for UNIQUE_CHECK_PARTIAL:
* it must be true if the entry is known unique, else false.
* (In the current implementation we'll also return true after a
* successful UNIQUE_CHECK_YES or UNIQUE_CHECK_EXISTING call, but
* that's just a coding artifact.)
*/
bool
_bt_doinsert(Relation rel, IndexTuple itup,
IndexUniqueCheck checkUnique, Relation heapRel)
{
bool is_unique = false;
int natts = rel->rd_rel->relnatts;
ScanKey itup_scankey;
BTStack stack = NULL;
Buffer buf;
OffsetNumber offset;
bool fastpath;
/* we need an insertion scan key to do our search, so build one */
itup_scankey = _bt_mkscankey(rel, itup);
/*
* It's very common to have an index on an auto-incremented or
* monotonically increasing value. In such cases, every insertion happens
* towards the end of the index. We try to optimise that case by caching
* the right-most leaf of the index. If our cached block is still the
* rightmost leaf, has enough free space to accommodate a new entry and
* the insertion key is strictly greater than the first key in this page,
* then we can safely conclude that the new key will be inserted in the
* cached block. So we simply search within the cached block and insert the
* key at the appropriate location. We call it a fastpath.
*
* Testing has revealed, though, that the fastpath can result in increased
* contention on the exclusive-lock on the rightmost leaf page. So we
* conditionally check if the lock is available. If it's not available then
* we simply abandon the fastpath and take the regular path. This makes
* sense because unavailability of the lock also signals that some other
* backend might be concurrently inserting into the page, thus reducing our
* chances to finding an insertion place in this page.
*/
top:
fastpath = false;
offset = InvalidOffsetNumber;
if (RelationGetTargetBlock(rel) != InvalidBlockNumber)
{
Size itemsz;
Page page;
BTPageOpaque lpageop;
/*
* Conditionally acquire exclusive lock on the buffer before doing any
* checks. If we don't get the lock, we simply follow slowpath. If we
* do get the lock, this ensures that the index state cannot change, as
* far as the rightmost part of the index is concerned.
*/
buf = ReadBuffer(rel, RelationGetTargetBlock(rel));
if (ConditionalLockBuffer(buf))
{
_bt_checkpage(rel, buf);
page = BufferGetPage(buf);
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
itemsz = IndexTupleSize(itup);
itemsz = MAXALIGN(itemsz); /* be safe, PageAddItem will do this
* but we need to be consistent */
/*
* Check if the page is still the rightmost leaf page, has enough
* free space to accommodate the new tuple, no split is in progress
* and the scankey is greater than or equal to the first key on the
* page.
*/
if (P_ISLEAF(lpageop) && P_RIGHTMOST(lpageop) &&
!P_INCOMPLETE_SPLIT(lpageop) &&
!P_IGNORE(lpageop) &&
(PageGetFreeSpace(page) > itemsz) &&
PageGetMaxOffsetNumber(page) >= P_FIRSTDATAKEY(lpageop) &&
_bt_compare(rel, natts, itup_scankey, page,
P_FIRSTDATAKEY(lpageop)) > 0)
{
fastpath = true;
}
else
{
_bt_relbuf(rel, buf);
/*
* Something did not work out. Just forget about the cached
* block and follow the normal path. It might be set again if
* the conditions are favourable.
*/
RelationSetTargetBlock(rel, InvalidBlockNumber);
}
}
else
{
ReleaseBuffer(buf);
/*
* If someone's holding a lock, it's likely to change anyway,
* so don't try again until we get an updated rightmost leaf.
*/
RelationSetTargetBlock(rel, InvalidBlockNumber);
}
}
if (!fastpath)
{
/* find the first page containing this key */
stack = _bt_search(rel, natts, itup_scankey, false, &buf, BT_WRITE,
NULL);
/* trade in our read lock for a write lock */
LockBuffer(buf, BUFFER_LOCK_UNLOCK);
LockBuffer(buf, BT_WRITE);
/*
* If the page was split between the time that we surrendered our read
* lock and acquired our write lock, then this page may no longer be
* the right place for the key we want to insert. In this case, we
* need to move right in the tree. See Lehman and Yao for an
* excruciatingly precise description.
*/
buf = _bt_moveright(rel, buf, natts, itup_scankey, false,
true, stack, BT_WRITE, NULL);
}
/*
* If we're not allowing duplicates, make sure the key isn't already in
* the index.
*
* NOTE: obviously, _bt_check_unique can only detect keys that are already
* in the index; so it cannot defend against concurrent insertions of the
* same key. We protect against that by means of holding a write lock on
* the target page. Any other would-be inserter of the same key must
* acquire a write lock on the same target page, so only one would-be
* inserter can be making the check at one time. Furthermore, once we are
* past the check we hold write locks continuously until we have performed
* our insertion, so no later inserter can fail to see our insertion.
* (This requires some care in _bt_insertonpg.)
*
* If we must wait for another xact, we release the lock while waiting,
* and then must start over completely.
*
* For a partial uniqueness check, we don't wait for the other xact. Just
* let the tuple in and return false for possibly non-unique, or true for
* definitely unique.
*/
if (checkUnique != UNIQUE_CHECK_NO)
{
TransactionId xwait;
uint32 speculativeToken;
offset = _bt_binsrch(rel, buf, natts, itup_scankey, false);
xwait = _bt_check_unique(rel, itup, heapRel, buf, offset, itup_scankey,
checkUnique, &is_unique, &speculativeToken);
if (TransactionIdIsValid(xwait))
{
/* Have to wait for the other guy ... */
_bt_relbuf(rel, buf);
/*
* If it's a speculative insertion, wait for it to finish (ie. to
* go ahead with the insertion, or kill the tuple). Otherwise
* wait for the transaction to finish as usual.
*/
if (speculativeToken)
SpeculativeInsertionWait(xwait, speculativeToken);
else
XactLockTableWait(xwait, rel, &itup->t_tid, XLTW_InsertIndex);
/* start over... */
if (stack)
_bt_freestack(stack);
goto top;
}
}
if (checkUnique != UNIQUE_CHECK_EXISTING)
{
/*
* The only conflict predicate locking cares about for indexes is when
* an index tuple insert conflicts with an existing lock. Since the
* actual location of the insert is hard to predict because of the
* random search used to prevent O(N^2) performance when there are
* many duplicate entries, we can just use the "first valid" page.
*/
CheckForSerializableConflictIn(rel, NULL, buf);
/* do the insertion */
_bt_findinsertloc(rel, &buf, &offset, natts, itup_scankey, itup,
stack, heapRel);
_bt_insertonpg(rel, buf, InvalidBuffer, stack, itup, offset, false);
}
else
{
/* just release the buffer */
_bt_relbuf(rel, buf);
}
/* be tidy */
if (stack)
_bt_freestack(stack);
_bt_freeskey(itup_scankey);
return is_unique;
}
/*
* _bt_check_unique() -- Check for violation of unique index constraint
*
* offset points to the first possible item that could conflict. It can
* also point to end-of-page, which means that the first tuple to check
* is the first tuple on the next page.
*
* Returns InvalidTransactionId if there is no conflict, else an xact ID
* we must wait for to see if it commits a conflicting tuple. If an actual
* conflict is detected, no return --- just ereport(). If an xact ID is
* returned, and the conflicting tuple still has a speculative insertion in
* progress, *speculativeToken is set to non-zero, and the caller can wait for
* the verdict on the insertion using SpeculativeInsertionWait().
*
* However, if checkUnique == UNIQUE_CHECK_PARTIAL, we always return
* InvalidTransactionId because we don't want to wait. In this case we
* set *is_unique to false if there is a potential conflict, and the
* core code must redo the uniqueness check later.
*/
static TransactionId
_bt_check_unique(Relation rel, IndexTuple itup, Relation heapRel,
Buffer buf, OffsetNumber offset, ScanKey itup_scankey,
IndexUniqueCheck checkUnique, bool *is_unique,
uint32 *speculativeToken)
{
TupleDesc itupdesc = RelationGetDescr(rel);
int natts = rel->rd_rel->relnatts;
SnapshotData SnapshotDirty;
OffsetNumber maxoff;
Page page;
BTPageOpaque opaque;
Buffer nbuf = InvalidBuffer;
bool found = false;
/* Assume unique until we find a duplicate */
*is_unique = true;
InitDirtySnapshot(SnapshotDirty);
page = BufferGetPage(buf);
opaque = (BTPageOpaque) PageGetSpecialPointer(page);
maxoff = PageGetMaxOffsetNumber(page);
/*
* Scan over all equal tuples, looking for live conflicts.
*/
for (;;)
{
ItemId curitemid;
IndexTuple curitup;
BlockNumber nblkno;
/*
* make sure the offset points to an actual item before trying to
* examine it...
*/
if (offset <= maxoff)
{
curitemid = PageGetItemId(page, offset);
/*
* We can skip items that are marked killed.
*
* Formerly, we applied _bt_isequal() before checking the kill
* flag, so as to fall out of the item loop as soon as possible.
* However, in the presence of heavy update activity an index may
* contain many killed items with the same key; running
* _bt_isequal() on each killed item gets expensive. Furthermore
* it is likely that the non-killed version of each key appears
* first, so that we didn't actually get to exit any sooner
* anyway. So now we just advance over killed items as quickly as
* we can. We only apply _bt_isequal() when we get to a non-killed
* item or the end of the page.
*/
if (!ItemIdIsDead(curitemid))
{
ItemPointerData htid;
bool all_dead;
/*
* _bt_compare returns 0 for (1,NULL) and (1,NULL) - this's
* how we handling NULLs - and so we must not use _bt_compare
* in real comparison, but only for ordering/finding items on
* pages. - vadim 03/24/97
*/
if (!_bt_isequal(itupdesc, page, offset, natts, itup_scankey))
break; /* we're past all the equal tuples */
/* okay, we gotta fetch the heap tuple ... */
curitup = (IndexTuple) PageGetItem(page, curitemid);
htid = curitup->t_tid;
/*
* If we are doing a recheck, we expect to find the tuple we
* are rechecking. It's not a duplicate, but we have to keep
* scanning.
*/
if (checkUnique == UNIQUE_CHECK_EXISTING &&
ItemPointerCompare(&htid, &itup->t_tid) == 0)
{
found = true;
}
/*
* We check the whole HOT-chain to see if there is any tuple
* that satisfies SnapshotDirty. This is necessary because we
* have just a single index entry for the entire chain.
*/
else if (heap_hot_search(&htid, heapRel, &SnapshotDirty,
&all_dead))
{
TransactionId xwait;
/*
* It is a duplicate. If we are only doing a partial
* check, then don't bother checking if the tuple is being
* updated in another transaction. Just return the fact
* that it is a potential conflict and leave the full
* check till later.
*/
if (checkUnique == UNIQUE_CHECK_PARTIAL)
{
if (nbuf != InvalidBuffer)
_bt_relbuf(rel, nbuf);
*is_unique = false;
return InvalidTransactionId;
}
/*
* If this tuple is being updated by other transaction
* then we have to wait for its commit/abort.
*/
xwait = (TransactionIdIsValid(SnapshotDirty.xmin)) ?
SnapshotDirty.xmin : SnapshotDirty.xmax;
if (TransactionIdIsValid(xwait))
{
if (nbuf != InvalidBuffer)
_bt_relbuf(rel, nbuf);
/* Tell _bt_doinsert to wait... */
*speculativeToken = SnapshotDirty.speculativeToken;
return xwait;
}
/*
* Otherwise we have a definite conflict. But before
* complaining, look to see if the tuple we want to insert
* is itself now committed dead --- if so, don't complain.
* This is a waste of time in normal scenarios but we must
* do it to support CREATE INDEX CONCURRENTLY.
*
* We must follow HOT-chains here because during
* concurrent index build, we insert the root TID though
* the actual tuple may be somewhere in the HOT-chain.
* While following the chain we might not stop at the
* exact tuple which triggered the insert, but that's OK
* because if we find a live tuple anywhere in this chain,
* we have a unique key conflict. The other live tuple is
* not part of this chain because it had a different index
* entry.
*/
htid = itup->t_tid;
if (heap_hot_search(&htid, heapRel, SnapshotSelf, NULL))
{
/* Normal case --- it's still live */
}
else
{
/*
* It's been deleted, so no error, and no need to
* continue searching
*/
break;
}
/*
* Check for a conflict-in as we would if we were going to
* write to this page. We aren't actually going to write,
* but we want a chance to report SSI conflicts that would
* otherwise be masked by this unique constraint
* violation.
*/
CheckForSerializableConflictIn(rel, NULL, buf);
/*
* This is a definite conflict. Break the tuple down into
* datums and report the error. But first, make sure we
* release the buffer locks we're holding ---
* BuildIndexValueDescription could make catalog accesses,
* which in the worst case might touch this same index and
* cause deadlocks.
*/
if (nbuf != InvalidBuffer)
_bt_relbuf(rel, nbuf);
_bt_relbuf(rel, buf);
{
Datum values[INDEX_MAX_KEYS];
bool isnull[INDEX_MAX_KEYS];
char *key_desc;
index_deform_tuple(itup, RelationGetDescr(rel),
values, isnull);
key_desc = BuildIndexValueDescription(rel, values,
isnull);
ereport(ERROR,
(errcode(ERRCODE_UNIQUE_VIOLATION),
errmsg("duplicate key value violates unique constraint \"%s\"",
RelationGetRelationName(rel)),
key_desc ? errdetail("Key %s already exists.",
key_desc) : 0,
errtableconstraint(heapRel,
RelationGetRelationName(rel))));
}
}
else if (all_dead)
{
/*
* The conflicting tuple (or whole HOT chain) is dead to
* everyone, so we may as well mark the index entry
* killed.
*/
ItemIdMarkDead(curitemid);
opaque->btpo_flags |= BTP_HAS_GARBAGE;
/*
* Mark buffer with a dirty hint, since state is not
* crucial. Be sure to mark the proper buffer dirty.
*/
if (nbuf != InvalidBuffer)
MarkBufferDirtyHint(nbuf, true);
else
MarkBufferDirtyHint(buf, true);
}
}
}
/*
* Advance to next tuple to continue checking.
*/
if (offset < maxoff)
offset = OffsetNumberNext(offset);
else
{
/* If scankey == hikey we gotta check the next page too */
if (P_RIGHTMOST(opaque))
break;
if (!_bt_isequal(itupdesc, page, P_HIKEY,
natts, itup_scankey))
break;
/* Advance to next non-dead page --- there must be one */
for (;;)
{
nblkno = opaque->btpo_next;
nbuf = _bt_relandgetbuf(rel, nbuf, nblkno, BT_READ);
page = BufferGetPage(nbuf);
opaque = (BTPageOpaque) PageGetSpecialPointer(page);
if (!P_IGNORE(opaque))
break;
if (P_RIGHTMOST(opaque))
elog(ERROR, "fell off the end of index \"%s\"",
RelationGetRelationName(rel));
}
maxoff = PageGetMaxOffsetNumber(page);
offset = P_FIRSTDATAKEY(opaque);
}
}
/*
* If we are doing a recheck then we should have found the tuple we are
* checking. Otherwise there's something very wrong --- probably, the
* index is on a non-immutable expression.
*/
if (checkUnique == UNIQUE_CHECK_EXISTING && !found)
ereport(ERROR,
(errcode(ERRCODE_INTERNAL_ERROR),
errmsg("failed to re-find tuple within index \"%s\"",
RelationGetRelationName(rel)),
errhint("This may be because of a non-immutable index expression."),
errtableconstraint(heapRel,
RelationGetRelationName(rel))));
if (nbuf != InvalidBuffer)
_bt_relbuf(rel, nbuf);
return InvalidTransactionId;
}
/*
* _bt_findinsertloc() -- Finds an insert location for a tuple
*
* If the new key is equal to one or more existing keys, we can
* legitimately place it anywhere in the series of equal keys --- in fact,
* if the new key is equal to the page's "high key" we can place it on
* the next page. If it is equal to the high key, and there's not room
* to insert the new tuple on the current page without splitting, then
* we can move right hoping to find more free space and avoid a split.
* (We should not move right indefinitely, however, since that leads to
* O(N^2) insertion behavior in the presence of many equal keys.)
* Once we have chosen the page to put the key on, we'll insert it before
* any existing equal keys because of the way _bt_binsrch() works.
*
* If there's not enough room in the space, we try to make room by
* removing any LP_DEAD tuples.
*
* On entry, *bufptr and *offsetptr point to the first legal position
* where the new tuple could be inserted. The caller should hold an
* exclusive lock on *bufptr. *offsetptr can also be set to
* InvalidOffsetNumber, in which case the function will search for the
* right location within the page if needed. On exit, they point to the
* chosen insert location. If _bt_findinsertloc decides to move right,
* the lock and pin on the original page will be released and the new
* page returned to the caller is exclusively locked instead.
*
* newtup is the new tuple we're inserting, and scankey is an insertion
* type scan key for it.
*/
static void
_bt_findinsertloc(Relation rel,
Buffer *bufptr,
OffsetNumber *offsetptr,
int keysz,
ScanKey scankey,
IndexTuple newtup,
BTStack stack,
Relation heapRel)
{
Buffer buf = *bufptr;
Page page = BufferGetPage(buf);
Size itemsz;
BTPageOpaque lpageop;
bool movedright,
vacuumed;
OffsetNumber newitemoff;
OffsetNumber firstlegaloff = *offsetptr;
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
itemsz = IndexTupleSize(newtup);
itemsz = MAXALIGN(itemsz); /* be safe, PageAddItem will do this but we
* need to be consistent */
/*
* Check whether the item can fit on a btree page at all. (Eventually, we
* ought to try to apply TOAST methods if not.) We actually need to be
* able to fit three items on every page, so restrict any one item to 1/3
* the per-page available space. Note that at this point, itemsz doesn't
* include the ItemId.
*
* NOTE: if you change this, see also the similar code in _bt_buildadd().
*/
if (itemsz > BTMaxItemSize(page))
ereport(ERROR,
(errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
errmsg("index row size %zu exceeds maximum %zu for index \"%s\"",
itemsz, BTMaxItemSize(page),
RelationGetRelationName(rel)),
errhint("Values larger than 1/3 of a buffer page cannot be indexed.\n"
"Consider a function index of an MD5 hash of the value, "
"or use full text indexing."),
errtableconstraint(heapRel,
RelationGetRelationName(rel))));
/*----------
* If we will need to split the page to put the item on this page,
* check whether we can put the tuple somewhere to the right,
* instead. Keep scanning right until we
* (a) find a page with enough free space,
* (b) reach the last page where the tuple can legally go, or
* (c) get tired of searching.
* (c) is not flippant; it is important because if there are many
* pages' worth of equal keys, it's better to split one of the early
* pages than to scan all the way to the end of the run of equal keys
* on every insert. We implement "get tired" as a random choice,
* since stopping after scanning a fixed number of pages wouldn't work
* well (we'd never reach the right-hand side of previously split
* pages). Currently the probability of moving right is set at 0.99,
* which may seem too high to change the behavior much, but it does an
* excellent job of preventing O(N^2) behavior with many equal keys.
*----------
*/
movedright = false;
vacuumed = false;
while (PageGetFreeSpace(page) < itemsz)
{
Buffer rbuf;
BlockNumber rblkno;
/*
* before considering moving right, see if we can obtain enough space
* by erasing LP_DEAD items
*/
if (P_ISLEAF(lpageop) && P_HAS_GARBAGE(lpageop))
{
_bt_vacuum_one_page(rel, buf, heapRel);
/*
* remember that we vacuumed this page, because that makes the
* hint supplied by the caller invalid
*/
vacuumed = true;
if (PageGetFreeSpace(page) >= itemsz)
break; /* OK, now we have enough space */
}
/*
* nope, so check conditions (b) and (c) enumerated above
*/
if (P_RIGHTMOST(lpageop) ||
_bt_compare(rel, keysz, scankey, page, P_HIKEY) != 0 ||
random() <= (MAX_RANDOM_VALUE / 100))
break;
/*
* step right to next non-dead page
*
* must write-lock that page before releasing write lock on current
* page; else someone else's _bt_check_unique scan could fail to see
* our insertion. write locks on intermediate dead pages won't do
* because we don't know when they will get de-linked from the tree.
*/
rbuf = InvalidBuffer;
rblkno = lpageop->btpo_next;
for (;;)
{
rbuf = _bt_relandgetbuf(rel, rbuf, rblkno, BT_WRITE);
page = BufferGetPage(rbuf);
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
/*
* If this page was incompletely split, finish the split now. We
* do this while holding a lock on the left sibling, which is not
* good because finishing the split could be a fairly lengthy
* operation. But this should happen very seldom.
*/
if (P_INCOMPLETE_SPLIT(lpageop))
{
_bt_finish_split(rel, rbuf, stack);
rbuf = InvalidBuffer;
continue;
}
if (!P_IGNORE(lpageop))
break;
if (P_RIGHTMOST(lpageop))
elog(ERROR, "fell off the end of index \"%s\"",
RelationGetRelationName(rel));
rblkno = lpageop->btpo_next;
}
_bt_relbuf(rel, buf);
buf = rbuf;
movedright = true;
vacuumed = false;
}
/*
* Now we are on the right page, so find the insert position. If we moved
* right at all, we know we should insert at the start of the page. If we
* didn't move right, we can use the firstlegaloff hint if the caller
* supplied one, unless we vacuumed the page which might have moved tuples
* around making the hint invalid. If we didn't move right or can't use
* the hint, find the position by searching.
*/
if (movedright)
newitemoff = P_FIRSTDATAKEY(lpageop);
else if (firstlegaloff != InvalidOffsetNumber && !vacuumed)
newitemoff = firstlegaloff;
else
newitemoff = _bt_binsrch(rel, buf, keysz, scankey, false);
*bufptr = buf;
*offsetptr = newitemoff;
}
/*----------
* _bt_insertonpg() -- Insert a tuple on a particular page in the index.
*
* This recursive procedure does the following things:
*
* + if necessary, splits the target page (making sure that the
* split is equitable as far as post-insert free space goes).
* + inserts the tuple.
* + if the page was split, pops the parent stack, and finds the
* right place to insert the new child pointer (by walking
* right using information stored in the parent stack).
* + invokes itself with the appropriate tuple for the right
* child page on the parent.
* + updates the metapage if a true root or fast root is split.
*
* On entry, we must have the correct buffer in which to do the
* insertion, and the buffer must be pinned and write-locked. On return,
* we will have dropped both the pin and the lock on the buffer.
*
* When inserting to a non-leaf page, 'cbuf' is the left-sibling of the
* page we're inserting the downlink for. This function will clear the
* INCOMPLETE_SPLIT flag on it, and release the buffer.
*
* The locking interactions in this code are critical. You should
* grok Lehman and Yao's paper before making any changes. In addition,
* you need to understand how we disambiguate duplicate keys in this
* implementation, in order to be able to find our location using
* L&Y "move right" operations. Since we may insert duplicate user
* keys, and since these dups may propagate up the tree, we use the
* 'afteritem' parameter to position ourselves correctly for the
* insertion on internal pages.
*----------
*/
static void
_bt_insertonpg(Relation rel,
Buffer buf,
Buffer cbuf,
BTStack stack,
IndexTuple itup,
OffsetNumber newitemoff,
bool split_only_page)
{
Page page;
BTPageOpaque lpageop;
OffsetNumber firstright = InvalidOffsetNumber;
Size itemsz;
page = BufferGetPage(buf);
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
/* child buffer must be given iff inserting on an internal page */
Assert(P_ISLEAF(lpageop) == !BufferIsValid(cbuf));
/* The caller should've finished any incomplete splits already. */
if (P_INCOMPLETE_SPLIT(lpageop))
elog(ERROR, "cannot insert to incompletely split page %u",
BufferGetBlockNumber(buf));
itemsz = IndexTupleSize(itup);
itemsz = MAXALIGN(itemsz); /* be safe, PageAddItem will do this but we
* need to be consistent */
/*
* Do we need to split the page to fit the item on it?
*
* Note: PageGetFreeSpace() subtracts sizeof(ItemIdData) from its result,
* so this comparison is correct even though we appear to be accounting
* only for the item and not for its line pointer.
*/
if (PageGetFreeSpace(page) < itemsz)
{
bool is_root = P_ISROOT(lpageop);
bool is_only = P_LEFTMOST(lpageop) && P_RIGHTMOST(lpageop);
bool newitemonleft;
Buffer rbuf;
/* Choose the split point */
firstright = _bt_findsplitloc(rel, page,
newitemoff, itemsz,
&newitemonleft);
/* split the buffer into left and right halves */
rbuf = _bt_split(rel, buf, cbuf, firstright,
newitemoff, itemsz, itup, newitemonleft);
PredicateLockPageSplit(rel,
BufferGetBlockNumber(buf),
BufferGetBlockNumber(rbuf));
/*----------
* By here,
*
* + our target page has been split;
* + the original tuple has been inserted;
* + we have write locks on both the old (left half)
* and new (right half) buffers, after the split; and
* + we know the key we want to insert into the parent
* (it's the "high key" on the left child page).
*
* We're ready to do the parent insertion. We need to hold onto the
* locks for the child pages until we locate the parent, but we can
* release them before doing the actual insertion (see Lehman and Yao
* for the reasoning).
*----------
*/
_bt_insert_parent(rel, buf, rbuf, stack, is_root, is_only);
}
else
{
Buffer metabuf = InvalidBuffer;
Page metapg = NULL;
BTMetaPageData *metad = NULL;
OffsetNumber itup_off;
BlockNumber itup_blkno;
itup_off = newitemoff;
itup_blkno = BufferGetBlockNumber(buf);
/*
* If we are doing this insert because we split a page that was the
* only one on its tree level, but was not the root, it may have been
* the "fast root". We need to ensure that the fast root link points
* at or above the current page. We can safely acquire a lock on the
* metapage here --- see comments for _bt_newroot().
*/
if (split_only_page)
{
Assert(!P_ISLEAF(lpageop));
metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_WRITE);
metapg = BufferGetPage(metabuf);
metad = BTPageGetMeta(metapg);
if (metad->btm_fastlevel >= lpageop->btpo.level)
{
/* no update wanted */
_bt_relbuf(rel, metabuf);
metabuf = InvalidBuffer;
}
}
/* Do the update. No ereport(ERROR) until changes are logged */
START_CRIT_SECTION();
if (!_bt_pgaddtup(page, itemsz, itup, newitemoff))
elog(PANIC, "failed to add new item to block %u in index \"%s\"",
itup_blkno, RelationGetRelationName(rel));
MarkBufferDirty(buf);
if (BufferIsValid(metabuf))
{
/* upgrade meta-page if needed */
if (metad->btm_version < BTREE_VERSION)
_bt_upgrademetapage(metapg);
metad->btm_fastroot = itup_blkno;
metad->btm_fastlevel = lpageop->btpo.level;
MarkBufferDirty(metabuf);
}
/* clear INCOMPLETE_SPLIT flag on child if inserting a downlink */
if (BufferIsValid(cbuf))
{
Page cpage = BufferGetPage(cbuf);
BTPageOpaque cpageop = (BTPageOpaque) PageGetSpecialPointer(cpage);
Assert(P_INCOMPLETE_SPLIT(cpageop));
cpageop->btpo_flags &= ~BTP_INCOMPLETE_SPLIT;
MarkBufferDirty(cbuf);
}
/* XLOG stuff */
if (RelationNeedsWAL(rel))
{
xl_btree_insert xlrec;
xl_btree_metadata xlmeta;
uint8 xlinfo;
XLogRecPtr recptr;
IndexTupleData trunctuple;
xlrec.offnum = itup_off;
XLogBeginInsert();
XLogRegisterData((char *) &xlrec, SizeOfBtreeInsert);
if (P_ISLEAF(lpageop))
{
xlinfo = XLOG_BTREE_INSERT_LEAF;
/*
* Cache the block information if we just inserted into the
* rightmost leaf page of the index.
*/
if (P_RIGHTMOST(lpageop))
RelationSetTargetBlock(rel, BufferGetBlockNumber(buf));
}
else
{
/*
* Register the left child whose INCOMPLETE_SPLIT flag was
* cleared.
*/
XLogRegisterBuffer(1, cbuf, REGBUF_STANDARD);
xlinfo = XLOG_BTREE_INSERT_UPPER;
}
if (BufferIsValid(metabuf))
{
xlmeta.root = metad->btm_root;
xlmeta.level = metad->btm_level;
xlmeta.fastroot = metad->btm_fastroot;
xlmeta.fastlevel = metad->btm_fastlevel;
xlmeta.oldest_btpo_xact = metad->btm_oldest_btpo_xact;
xlmeta.last_cleanup_num_heap_tuples =
metad->btm_last_cleanup_num_heap_tuples;
XLogRegisterBuffer(2, metabuf, REGBUF_WILL_INIT | REGBUF_STANDARD);
XLogRegisterBufData(2, (char *) &xlmeta, sizeof(xl_btree_metadata));
xlinfo = XLOG_BTREE_INSERT_META;
}
/* Read comments in _bt_pgaddtup */
XLogRegisterBuffer(0, buf, REGBUF_STANDARD);
if (!P_ISLEAF(lpageop) && newitemoff == P_FIRSTDATAKEY(lpageop))
{
trunctuple = *itup;
trunctuple.t_info = sizeof(IndexTupleData);
XLogRegisterBufData(0, (char *) &trunctuple,
sizeof(IndexTupleData));
}
else
XLogRegisterBufData(0, (char *) itup, IndexTupleSize(itup));
recptr = XLogInsert(RM_BTREE_ID, xlinfo);
if (BufferIsValid(metabuf))
{
PageSetLSN(metapg, recptr);
}
if (BufferIsValid(cbuf))
{
PageSetLSN(BufferGetPage(cbuf), recptr);
}
PageSetLSN(page, recptr);
}
END_CRIT_SECTION();
/* release buffers */
if (BufferIsValid(metabuf))
_bt_relbuf(rel, metabuf);
if (BufferIsValid(cbuf))
_bt_relbuf(rel, cbuf);
_bt_relbuf(rel, buf);
}
}
/*
* _bt_split() -- split a page in the btree.
*
* On entry, buf is the page to split, and is pinned and write-locked.
* firstright is the item index of the first item to be moved to the
* new right page. newitemoff etc. tell us about the new item that
* must be inserted along with the data from the old page.
*
* When splitting a non-leaf page, 'cbuf' is the left-sibling of the
* page we're inserting the downlink for. This function will clear the
* INCOMPLETE_SPLIT flag on it, and release the buffer.
*
* Returns the new right sibling of buf, pinned and write-locked.
* The pin and lock on buf are maintained.
*/
static Buffer
_bt_split(Relation rel, Buffer buf, Buffer cbuf, OffsetNumber firstright,
OffsetNumber newitemoff, Size newitemsz, IndexTuple newitem,
bool newitemonleft)
{
Buffer rbuf;
Page origpage;
Page leftpage,
rightpage;
BlockNumber origpagenumber,
rightpagenumber;
BTPageOpaque ropaque,
lopaque,
oopaque;
Buffer sbuf = InvalidBuffer;
Page spage = NULL;
BTPageOpaque sopaque = NULL;
Size itemsz;
ItemId itemid;
IndexTuple item;
OffsetNumber leftoff,
rightoff;
OffsetNumber maxoff;
OffsetNumber i;
bool isleaf;
/* Acquire a new page to split into */
rbuf = _bt_getbuf(rel, P_NEW, BT_WRITE);
/*
* origpage is the original page to be split. leftpage is a temporary
* buffer that receives the left-sibling data, which will be copied back
* into origpage on success. rightpage is the new page that receives the
* right-sibling data. If we fail before reaching the critical section,
* origpage hasn't been modified and leftpage is only workspace. In
* principle we shouldn't need to worry about rightpage either, because it
* hasn't been linked into the btree page structure; but to avoid leaving
* possibly-confusing junk behind, we are careful to rewrite rightpage as
* zeroes before throwing any error.
*/
origpage = BufferGetPage(buf);
leftpage = PageGetTempPage(origpage);
rightpage = BufferGetPage(rbuf);
origpagenumber = BufferGetBlockNumber(buf);
rightpagenumber = BufferGetBlockNumber(rbuf);
_bt_pageinit(leftpage, BufferGetPageSize(buf));
/* rightpage was already initialized by _bt_getbuf */
/*
* Copy the original page's LSN into leftpage, which will become the
* updated version of the page. We need this because XLogInsert will
* examine the LSN and possibly dump it in a page image.
*/
PageSetLSN(leftpage, PageGetLSN(origpage));
/* init btree private data */
oopaque = (BTPageOpaque) PageGetSpecialPointer(origpage);
lopaque = (BTPageOpaque) PageGetSpecialPointer(leftpage);
ropaque = (BTPageOpaque) PageGetSpecialPointer(rightpage);
isleaf = P_ISLEAF(oopaque);
/* if we're splitting this page, it won't be the root when we're done */
/* also, clear the SPLIT_END and HAS_GARBAGE flags in both pages */
lopaque->btpo_flags = oopaque->btpo_flags;
lopaque->btpo_flags &= ~(BTP_ROOT | BTP_SPLIT_END | BTP_HAS_GARBAGE);
ropaque->btpo_flags = lopaque->btpo_flags;
/* set flag in left page indicating that the right page has no downlink */
lopaque->btpo_flags |= BTP_INCOMPLETE_SPLIT;
lopaque->btpo_prev = oopaque->btpo_prev;
lopaque->btpo_next = rightpagenumber;
ropaque->btpo_prev = origpagenumber;
ropaque->btpo_next = oopaque->btpo_next;
lopaque->btpo.level = ropaque->btpo.level = oopaque->btpo.level;
/* Since we already have write-lock on both pages, ok to read cycleid */
lopaque->btpo_cycleid = _bt_vacuum_cycleid(rel);
ropaque->btpo_cycleid = lopaque->btpo_cycleid;
/*
* If the page we're splitting is not the rightmost page at its level in
* the tree, then the first entry on the page is the high key for the
* page. We need to copy that to the right half. Otherwise (meaning the
* rightmost page case), all the items on the right half will be user
* data.
*/
rightoff = P_HIKEY;
if (!P_RIGHTMOST(oopaque))
{
itemid = PageGetItemId(origpage, P_HIKEY);
itemsz = ItemIdGetLength(itemid);
item = (IndexTuple) PageGetItem(origpage, itemid);
if (PageAddItem(rightpage, (Item) item, itemsz, rightoff,
false, false) == InvalidOffsetNumber)
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add hikey to the right sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
rightoff = OffsetNumberNext(rightoff);
}
/*
* The "high key" for the new left page will be the first key that's going
* to go into the new right page. This might be either the existing data
* item at position firstright, or the incoming tuple.
*/
leftoff = P_HIKEY;
if (!newitemonleft && newitemoff == firstright)
{
/* incoming tuple will become first on right page */
itemsz = newitemsz;
item = newitem;
}
else
{
/* existing item at firstright will become first on right page */
itemid = PageGetItemId(origpage, firstright);
itemsz = ItemIdGetLength(itemid);
item = (IndexTuple) PageGetItem(origpage, itemid);
}
if (PageAddItem(leftpage, (Item) item, itemsz, leftoff,
false, false) == InvalidOffsetNumber)
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add hikey to the left sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
leftoff = OffsetNumberNext(leftoff);
/*
* Now transfer all the data items to the appropriate page.
*
* Note: we *must* insert at least the right page's items in item-number
* order, for the benefit of _bt_restore_page().
*/
maxoff = PageGetMaxOffsetNumber(origpage);
for (i = P_FIRSTDATAKEY(oopaque); i <= maxoff; i = OffsetNumberNext(i))
{
itemid = PageGetItemId(origpage, i);
itemsz = ItemIdGetLength(itemid);
item = (IndexTuple) PageGetItem(origpage, itemid);
/* does new item belong before this one? */
if (i == newitemoff)
{
if (newitemonleft)
{
if (!_bt_pgaddtup(leftpage, newitemsz, newitem, leftoff))
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add new item to the left sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
leftoff = OffsetNumberNext(leftoff);
}
else
{
if (!_bt_pgaddtup(rightpage, newitemsz, newitem, rightoff))
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add new item to the right sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
rightoff = OffsetNumberNext(rightoff);
}
}
/* decide which page to put it on */
if (i < firstright)
{
if (!_bt_pgaddtup(leftpage, itemsz, item, leftoff))
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add old item to the left sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
leftoff = OffsetNumberNext(leftoff);
}
else
{
if (!_bt_pgaddtup(rightpage, itemsz, item, rightoff))
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add old item to the right sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
rightoff = OffsetNumberNext(rightoff);
}
}
/* cope with possibility that newitem goes at the end */
if (i <= newitemoff)
{
/*
* Can't have newitemonleft here; that would imply we were told to put
* *everything* on the left page, which cannot fit (if it could, we'd
* not be splitting the page).
*/
Assert(!newitemonleft);
if (!_bt_pgaddtup(rightpage, newitemsz, newitem, rightoff))
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "failed to add new item to the right sibling"
" while splitting block %u of index \"%s\"",
origpagenumber, RelationGetRelationName(rel));
}
rightoff = OffsetNumberNext(rightoff);
}
/*
* We have to grab the right sibling (if any) and fix the prev pointer
* there. We are guaranteed that this is deadlock-free since no other
* writer will be holding a lock on that page and trying to move left, and
* all readers release locks on a page before trying to fetch its
* neighbors.
*/
if (!P_RIGHTMOST(oopaque))
{
sbuf = _bt_getbuf(rel, oopaque->btpo_next, BT_WRITE);
spage = BufferGetPage(sbuf);
sopaque = (BTPageOpaque) PageGetSpecialPointer(spage);
if (sopaque->btpo_prev != origpagenumber)
{
memset(rightpage, 0, BufferGetPageSize(rbuf));
elog(ERROR, "right sibling's left-link doesn't match: "
"block %u links to %u instead of expected %u in index \"%s\"",
oopaque->btpo_next, sopaque->btpo_prev, origpagenumber,
RelationGetRelationName(rel));
}
/*
* Check to see if we can set the SPLIT_END flag in the right-hand
* split page; this can save some I/O for vacuum since it need not
* proceed to the right sibling. We can set the flag if the right
* sibling has a different cycleid: that means it could not be part of
* a group of pages that were all split off from the same ancestor
* page. If you're confused, imagine that page A splits to A B and
* then again, yielding A C B, while vacuum is in progress. Tuples
* originally in A could now be in either B or C, hence vacuum must
* examine both pages. But if D, our right sibling, has a different
* cycleid then it could not contain any tuples that were in A when
* the vacuum started.
*/
if (sopaque->btpo_cycleid != ropaque->btpo_cycleid)
ropaque->btpo_flags |= BTP_SPLIT_END;
}
/*
* Right sibling is locked, new siblings are prepared, but original page
* is not updated yet.
*
* NO EREPORT(ERROR) till right sibling is updated. We can get away with
* not starting the critical section till here because we haven't been
* scribbling on the original page yet; see comments above.
*/
START_CRIT_SECTION();
/*
* By here, the original data page has been split into two new halves, and
* these are correct. The algorithm requires that the left page never
* move during a split, so we copy the new left page back on top of the
* original. Note that this is not a waste of time, since we also require
* (in the page management code) that the center of a page always be
* clean, and the most efficient way to guarantee this is just to compact
* the data by reinserting it into a new left page. (XXX the latter
* comment is probably obsolete; but in any case it's good to not scribble
* on the original page until we enter the critical section.)
*
* We need to do this before writing the WAL record, so that XLogInsert
* can WAL log an image of the page if necessary.
*/
PageRestoreTempPage(leftpage, origpage);
/* leftpage, lopaque must not be used below here */
MarkBufferDirty(buf);
MarkBufferDirty(rbuf);
if (!P_RIGHTMOST(ropaque))
{
sopaque->btpo_prev = rightpagenumber;
MarkBufferDirty(sbuf);
}
/*
* Clear INCOMPLETE_SPLIT flag on child if inserting the new item finishes
* a split.
*/
if (!isleaf)
{
Page cpage = BufferGetPage(cbuf);
BTPageOpaque cpageop = (BTPageOpaque) PageGetSpecialPointer(cpage);
cpageop->btpo_flags &= ~BTP_INCOMPLETE_SPLIT;
MarkBufferDirty(cbuf);
}
/* XLOG stuff */
if (RelationNeedsWAL(rel))
{
xl_btree_split xlrec;
uint8 xlinfo;
XLogRecPtr recptr;
xlrec.level = ropaque->btpo.level;
xlrec.firstright = firstright;
xlrec.newitemoff = newitemoff;
XLogBeginInsert();
XLogRegisterData((char *) &xlrec, SizeOfBtreeSplit);
XLogRegisterBuffer(0, buf, REGBUF_STANDARD);
XLogRegisterBuffer(1, rbuf, REGBUF_WILL_INIT);
/* Log the right sibling, because we've changed its prev-pointer. */
if (!P_RIGHTMOST(ropaque))
XLogRegisterBuffer(2, sbuf, REGBUF_STANDARD);
if (BufferIsValid(cbuf))
XLogRegisterBuffer(3, cbuf, REGBUF_STANDARD);
/*
* Log the new item, if it was inserted on the left page. (If it was
* put on the right page, we don't need to explicitly WAL log it
* because it's included with all the other items on the right page.)
* Show the new item as belonging to the left page buffer, so that it
* is not stored if XLogInsert decides it needs a full-page image of
* the left page. We store the offset anyway, though, to support
* archive compression of these records.
*/
if (newitemonleft)
XLogRegisterBufData(0, (char *) newitem, MAXALIGN(newitemsz));
/* Log left page */
if (!isleaf)
{
/*
* We must also log the left page's high key, because the right
* page's leftmost key is suppressed on non-leaf levels. Show it
* as belonging to the left page buffer, so that it is not stored
* if XLogInsert decides it needs a full-page image of the left
* page.
*/
itemid = PageGetItemId(origpage, P_HIKEY);
item = (IndexTuple) PageGetItem(origpage, itemid);
XLogRegisterBufData(0, (char *) item, MAXALIGN(IndexTupleSize(item)));
}
/*
* Log the contents of the right page in the format understood by
* _bt_restore_page(). We set lastrdata->buffer to InvalidBuffer,
* because we're going to recreate the whole page anyway, so it should
* never be stored by XLogInsert.
*
* Direct access to page is not good but faster - we should implement
* some new func in page API. Note we only store the tuples
* themselves, knowing that they were inserted in item-number order
* and so the item pointers can be reconstructed. See comments for
* _bt_restore_page().
*/
XLogRegisterBufData(1,
(char *) rightpage + ((PageHeader) rightpage)->pd_upper,
((PageHeader) rightpage)->pd_special - ((PageHeader) rightpage)->pd_upper);
xlinfo = newitemonleft ? XLOG_BTREE_SPLIT_L : XLOG_BTREE_SPLIT_R;
recptr = XLogInsert(RM_BTREE_ID, xlinfo);
PageSetLSN(origpage, recptr);
PageSetLSN(rightpage, recptr);
if (!P_RIGHTMOST(ropaque))
{
PageSetLSN(spage, recptr);
}
if (!isleaf)
{
PageSetLSN(BufferGetPage(cbuf), recptr);
}
}
END_CRIT_SECTION();
/* release the old right sibling */
if (!P_RIGHTMOST(ropaque))
_bt_relbuf(rel, sbuf);
/* release the child */
if (!isleaf)
_bt_relbuf(rel, cbuf);
/* split's done */
return rbuf;
}
/*
* _bt_findsplitloc() -- find an appropriate place to split a page.
*
* The idea here is to equalize the free space that will be on each split
* page, *after accounting for the inserted tuple*. (If we fail to account
* for it, we might find ourselves with too little room on the page that
* it needs to go into!)
*
* If the page is the rightmost page on its level, we instead try to arrange
* to leave the left split page fillfactor% full. In this way, when we are
* inserting successively increasing keys (consider sequences, timestamps,
* etc) we will end up with a tree whose pages are about fillfactor% full,
* instead of the 50% full result that we'd get without this special case.
* This is the same as nbtsort.c produces for a newly-created tree. Note
* that leaf and nonleaf pages use different fillfactors.
*
* We are passed the intended insert position of the new tuple, expressed as
* the offsetnumber of the tuple it must go in front of. (This could be
* maxoff+1 if the tuple is to go at the end.)
*
* We return the index of the first existing tuple that should go on the
* righthand page, plus a boolean indicating whether the new tuple goes on
* the left or right page. The bool is necessary to disambiguate the case
* where firstright == newitemoff.
*/
static OffsetNumber
_bt_findsplitloc(Relation rel,
Page page,
OffsetNumber newitemoff,
Size newitemsz,
bool *newitemonleft)
{
BTPageOpaque opaque;
OffsetNumber offnum;
OffsetNumber maxoff;
ItemId itemid;
FindSplitData state;
int leftspace,
rightspace,
goodenough,
olddataitemstotal,
olddataitemstoleft;
bool goodenoughfound;
opaque = (BTPageOpaque) PageGetSpecialPointer(page);
/* Passed-in newitemsz is MAXALIGNED but does not include line pointer */
newitemsz += sizeof(ItemIdData);
/* Total free space available on a btree page, after fixed overhead */
leftspace = rightspace =
PageGetPageSize(page) - SizeOfPageHeaderData -
MAXALIGN(sizeof(BTPageOpaqueData));
/* The right page will have the same high key as the old page */
if (!P_RIGHTMOST(opaque))
{
itemid = PageGetItemId(page, P_HIKEY);
rightspace -= (int) (MAXALIGN(ItemIdGetLength(itemid)) +
sizeof(ItemIdData));
}
/* Count up total space in data items without actually scanning 'em */
olddataitemstotal = rightspace - (int) PageGetExactFreeSpace(page);
state.newitemsz = newitemsz;
state.is_leaf = P_ISLEAF(opaque);
state.is_rightmost = P_RIGHTMOST(opaque);
state.have_split = false;
if (state.is_leaf)
state.fillfactor = RelationGetFillFactor(rel,
BTREE_DEFAULT_FILLFACTOR);
else
state.fillfactor = BTREE_NONLEAF_FILLFACTOR;
state.newitemonleft = false; /* these just to keep compiler quiet */
state.firstright = 0;
state.best_delta = 0;
state.leftspace = leftspace;
state.rightspace = rightspace;
state.olddataitemstotal = olddataitemstotal;
state.newitemoff = newitemoff;
/*
* Finding the best possible split would require checking all the possible
* split points, because of the high-key and left-key special cases.
* That's probably more work than it's worth; instead, stop as soon as we
* find a "good-enough" split, where good-enough is defined as an
* imbalance in free space of no more than pagesize/16 (arbitrary...) This
* should let us stop near the middle on most pages, instead of plowing to
* the end.
*/
goodenough = leftspace / 16;
/*
* Scan through the data items and calculate space usage for a split at
* each possible position.
*/
olddataitemstoleft = 0;
goodenoughfound = false;
maxoff = PageGetMaxOffsetNumber(page);
for (offnum = P_FIRSTDATAKEY(opaque);
offnum <= maxoff;
offnum = OffsetNumberNext(offnum))
{
Size itemsz;
itemid = PageGetItemId(page, offnum);
itemsz = MAXALIGN(ItemIdGetLength(itemid)) + sizeof(ItemIdData);
/*
* Will the new item go to left or right of split?
*/
if (offnum > newitemoff)
_bt_checksplitloc(&state, offnum, true,
olddataitemstoleft, itemsz);
else if (offnum < newitemoff)
_bt_checksplitloc(&state, offnum, false,
olddataitemstoleft, itemsz);
else
{
/* need to try it both ways! */
_bt_checksplitloc(&state, offnum, true,
olddataitemstoleft, itemsz);
_bt_checksplitloc(&state, offnum, false,
olddataitemstoleft, itemsz);
}
/* Abort scan once we find a good-enough choice */
if (state.have_split && state.best_delta <= goodenough)
{
goodenoughfound = true;
break;
}
olddataitemstoleft += itemsz;
}
/*
* If the new item goes as the last item, check for splitting so that all
* the old items go to the left page and the new item goes to the right
* page.
*/
if (newitemoff > maxoff && !goodenoughfound)
_bt_checksplitloc(&state, newitemoff, false, olddataitemstotal, 0);
/*
* I believe it is not possible to fail to find a feasible split, but just
* in case ...
*/
if (!state.have_split)
elog(ERROR, "could not find a feasible split point for index \"%s\"",
RelationGetRelationName(rel));
*newitemonleft = state.newitemonleft;
return state.firstright;
}
/*
* Subroutine to analyze a particular possible split choice (ie, firstright
* and newitemonleft settings), and record the best split so far in *state.
*
* firstoldonright is the offset of the first item on the original page
* that goes to the right page, and firstoldonrightsz is the size of that
* tuple. firstoldonright can be > max offset, which means that all the old
* items go to the left page and only the new item goes to the right page.
* In that case, firstoldonrightsz is not used.
*
* olddataitemstoleft is the total size of all old items to the left of
* firstoldonright.
*/
static void
_bt_checksplitloc(FindSplitData *state,
OffsetNumber firstoldonright,
bool newitemonleft,
int olddataitemstoleft,
Size firstoldonrightsz)
{
int leftfree,
rightfree;
Size firstrightitemsz;
bool newitemisfirstonright;
/* Is the new item going to be the first item on the right page? */
newitemisfirstonright = (firstoldonright == state->newitemoff
&& !newitemonleft);
if (newitemisfirstonright)
firstrightitemsz = state->newitemsz;
else
firstrightitemsz = firstoldonrightsz;
/* Account for all the old tuples */
leftfree = state->leftspace - olddataitemstoleft;
rightfree = state->rightspace -
(state->olddataitemstotal - olddataitemstoleft);
/*
* The first item on the right page becomes the high key of the left page;
* therefore it counts against left space as well as right space.
*/
leftfree -= firstrightitemsz;
/* account for the new item */
if (newitemonleft)
leftfree -= (int) state->newitemsz;
else
rightfree -= (int) state->newitemsz;
/*
* If we are not on the leaf level, we will be able to discard the key
* data from the first item that winds up on the right page.
*/
if (!state->is_leaf)
rightfree += (int) firstrightitemsz -
(int) (MAXALIGN(sizeof(IndexTupleData)) + sizeof(ItemIdData));
/*
* If feasible split point, remember best delta.
*/
if (leftfree >= 0 && rightfree >= 0)
{
int delta;
if (state->is_rightmost)
{
/*
* If splitting a rightmost page, try to put (100-fillfactor)% of
* free space on left page. See comments for _bt_findsplitloc.
*/
delta = (state->fillfactor * leftfree)
- ((100 - state->fillfactor) * rightfree);
}
else
{
/* Otherwise, aim for equal free space on both sides */
delta = leftfree - rightfree;
}
if (delta < 0)
delta = -delta;
if (!state->have_split || delta < state->best_delta)
{
state->have_split = true;
state->newitemonleft = newitemonleft;
state->firstright = firstoldonright;
state->best_delta = delta;
}
}
}
/*
* _bt_insert_parent() -- Insert downlink into parent after a page split.
*
* On entry, buf and rbuf are the left and right split pages, which we
* still hold write locks on per the L&Y algorithm. We release the
* write locks once we have write lock on the parent page. (Any sooner,
* and it'd be possible for some other process to try to split or delete
* one of these pages, and get confused because it cannot find the downlink.)
*
* stack - stack showing how we got here. May be NULL in cases that don't
* have to be efficient (concurrent ROOT split, WAL recovery)
* is_root - we split the true root
* is_only - we split a page alone on its level (might have been fast root)
*/
static void
_bt_insert_parent(Relation rel,
Buffer buf,
Buffer rbuf,
BTStack stack,
bool is_root,
bool is_only)
{
/*
* Here we have to do something Lehman and Yao don't talk about: deal with
* a root split and construction of a new root. If our stack is empty
* then we have just split a node on what had been the root level when we
* descended the tree. If it was still the root then we perform a
* new-root construction. If it *wasn't* the root anymore, search to find
* the next higher level that someone constructed meanwhile, and find the
* right place to insert as for the normal case.
*
* If we have to search for the parent level, we do so by re-descending
* from the root. This is not super-efficient, but it's rare enough not
* to matter.
*/
if (is_root)
{
Buffer rootbuf;
Assert(stack == NULL);
Assert(is_only);
/* create a new root node and update the metapage */
rootbuf = _bt_newroot(rel, buf, rbuf);
/* release the split buffers */
_bt_relbuf(rel, rootbuf);
_bt_relbuf(rel, rbuf);
_bt_relbuf(rel, buf);
}
else
{
BlockNumber bknum = BufferGetBlockNumber(buf);
BlockNumber rbknum = BufferGetBlockNumber(rbuf);
Page page = BufferGetPage(buf);
IndexTuple new_item;
BTStackData fakestack;
IndexTuple ritem;
Buffer pbuf;
if (stack == NULL)
{
BTPageOpaque lpageop;
elog(DEBUG2, "concurrent ROOT page split");
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
/* Find the leftmost page at the next level up */
pbuf = _bt_get_endpoint(rel, lpageop->btpo.level + 1, false,
NULL);
/* Set up a phony stack entry pointing there */
stack = &fakestack;
stack->bts_blkno = BufferGetBlockNumber(pbuf);
stack->bts_offset = InvalidOffsetNumber;
/* bts_btentry will be initialized below */
stack->bts_parent = NULL;
_bt_relbuf(rel, pbuf);
}
/* get high key from left page == lowest key on new right page */
ritem = (IndexTuple) PageGetItem(page,
PageGetItemId(page, P_HIKEY));
/* form an index tuple that points at the new right page */
new_item = CopyIndexTuple(ritem);
ItemPointerSet(&(new_item->t_tid), rbknum, P_HIKEY);
/*
* Find the parent buffer and get the parent page.
*
* Oops - if we were moved right then we need to change stack item! We
* want to find parent pointing to where we are, right ? - vadim
* 05/27/97
*/
ItemPointerSet(&(stack->bts_btentry.t_tid), bknum, P_HIKEY);
pbuf = _bt_getstackbuf(rel, stack, BT_WRITE);
/*
* Now we can unlock the right child. The left child will be unlocked
* by _bt_insertonpg().
*/
_bt_relbuf(rel, rbuf);
/* Check for error only after writing children */
if (pbuf == InvalidBuffer)
elog(ERROR, "failed to re-find parent key in index \"%s\" for split pages %u/%u",
RelationGetRelationName(rel), bknum, rbknum);
/* Recursively update the parent */
_bt_insertonpg(rel, pbuf, buf, stack->bts_parent,
new_item, stack->bts_offset + 1,
is_only);
/* be tidy */
pfree(new_item);
}
}
/*
* _bt_finish_split() -- Finish an incomplete split
*
* A crash or other failure can leave a split incomplete. The insertion
* routines won't allow to insert on a page that is incompletely split.
* Before inserting on such a page, call _bt_finish_split().
*
* On entry, 'lbuf' must be locked in write-mode. On exit, it is unlocked
* and unpinned.
*/
void
_bt_finish_split(Relation rel, Buffer lbuf, BTStack stack)
{
Page lpage = BufferGetPage(lbuf);
BTPageOpaque lpageop = (BTPageOpaque) PageGetSpecialPointer(lpage);
Buffer rbuf;
Page rpage;
BTPageOpaque rpageop;
bool was_root;
bool was_only;
Assert(P_INCOMPLETE_SPLIT(lpageop));
/* Lock right sibling, the one missing the downlink */
rbuf = _bt_getbuf(rel, lpageop->btpo_next, BT_WRITE);
rpage = BufferGetPage(rbuf);
rpageop = (BTPageOpaque) PageGetSpecialPointer(rpage);
/* Could this be a root split? */
if (!stack)
{
Buffer metabuf;
Page metapg;
BTMetaPageData *metad;
/* acquire lock on the metapage */
metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_WRITE);
metapg = BufferGetPage(metabuf);
metad = BTPageGetMeta(metapg);
was_root = (metad->btm_root == BufferGetBlockNumber(lbuf));
_bt_relbuf(rel, metabuf);
}
else
was_root = false;
/* Was this the only page on the level before split? */
was_only = (P_LEFTMOST(lpageop) && P_RIGHTMOST(rpageop));
elog(DEBUG1, "finishing incomplete split of %u/%u",
BufferGetBlockNumber(lbuf), BufferGetBlockNumber(rbuf));
_bt_insert_parent(rel, lbuf, rbuf, stack, was_root, was_only);
}
/*
* _bt_getstackbuf() -- Walk back up the tree one step, and find the item
* we last looked at in the parent.
*
* This is possible because we save the downlink from the parent item,
* which is enough to uniquely identify it. Insertions into the parent
* level could cause the item to move right; deletions could cause it
* to move left, but not left of the page we previously found it in.
*
* Adjusts bts_blkno & bts_offset if changed.
*
* Returns InvalidBuffer if item not found (should not happen).
*/
Buffer
_bt_getstackbuf(Relation rel, BTStack stack, int access)
{
BlockNumber blkno;
OffsetNumber start;
blkno = stack->bts_blkno;
start = stack->bts_offset;
for (;;)
{
Buffer buf;
Page page;
BTPageOpaque opaque;
buf = _bt_getbuf(rel, blkno, access);
page = BufferGetPage(buf);
opaque = (BTPageOpaque) PageGetSpecialPointer(page);
if (access == BT_WRITE && P_INCOMPLETE_SPLIT(opaque))
{
_bt_finish_split(rel, buf, stack->bts_parent);
continue;
}
if (!P_IGNORE(opaque))
{
OffsetNumber offnum,
minoff,
maxoff;
ItemId itemid;
IndexTuple item;
minoff = P_FIRSTDATAKEY(opaque);
maxoff = PageGetMaxOffsetNumber(page);
/*
* start = InvalidOffsetNumber means "search the whole page". We
* need this test anyway due to possibility that page has a high
* key now when it didn't before.
*/
if (start < minoff)
start = minoff;
/*
* Need this check too, to guard against possibility that page
* split since we visited it originally.
*/
if (start > maxoff)
start = OffsetNumberNext(maxoff);
/*
* These loops will check every item on the page --- but in an
* order that's attuned to the probability of where it actually
* is. Scan to the right first, then to the left.
*/
for (offnum = start;
offnum <= maxoff;
offnum = OffsetNumberNext(offnum))
{
itemid = PageGetItemId(page, offnum);
item = (IndexTuple) PageGetItem(page, itemid);
if (BTEntrySame(item, &stack->bts_btentry))
{
/* Return accurate pointer to where link is now */
stack->bts_blkno = blkno;
stack->bts_offset = offnum;
return buf;
}
}
for (offnum = OffsetNumberPrev(start);
offnum >= minoff;
offnum = OffsetNumberPrev(offnum))
{
itemid = PageGetItemId(page, offnum);
item = (IndexTuple) PageGetItem(page, itemid);
if (BTEntrySame(item, &stack->bts_btentry))
{
/* Return accurate pointer to where link is now */
stack->bts_blkno = blkno;
stack->bts_offset = offnum;
return buf;
}
}
}
/*
* The item we're looking for moved right at least one page.
*/
if (P_RIGHTMOST(opaque))
{
_bt_relbuf(rel, buf);
return InvalidBuffer;
}
blkno = opaque->btpo_next;
start = InvalidOffsetNumber;
_bt_relbuf(rel, buf);
}
}
/*
* _bt_newroot() -- Create a new root page for the index.
*
* We've just split the old root page and need to create a new one.
* In order to do this, we add a new root page to the file, then lock
* the metadata page and update it. This is guaranteed to be deadlock-
* free, because all readers release their locks on the metadata page
* before trying to lock the root, and all writers lock the root before
* trying to lock the metadata page. We have a write lock on the old
* root page, so we have not introduced any cycles into the waits-for
* graph.
*
* On entry, lbuf (the old root) and rbuf (its new peer) are write-
* locked. On exit, a new root page exists with entries for the
* two new children, metapage is updated and unlocked/unpinned.
* The new root buffer is returned to caller which has to unlock/unpin
* lbuf, rbuf & rootbuf.
*/
static Buffer
_bt_newroot(Relation rel, Buffer lbuf, Buffer rbuf)
{
Buffer rootbuf;
Page lpage,
rootpage;
BlockNumber lbkno,
rbkno;
BlockNumber rootblknum;
BTPageOpaque rootopaque;
BTPageOpaque lopaque;
ItemId itemid;
IndexTuple item;
IndexTuple left_item;
Size left_item_sz;
IndexTuple right_item;
Size right_item_sz;
Buffer metabuf;
Page metapg;
BTMetaPageData *metad;
lbkno = BufferGetBlockNumber(lbuf);
rbkno = BufferGetBlockNumber(rbuf);
lpage = BufferGetPage(lbuf);
lopaque = (BTPageOpaque) PageGetSpecialPointer(lpage);
/* get a new root page */
rootbuf = _bt_getbuf(rel, P_NEW, BT_WRITE);
rootpage = BufferGetPage(rootbuf);
rootblknum = BufferGetBlockNumber(rootbuf);
/* acquire lock on the metapage */
metabuf = _bt_getbuf(rel, BTREE_METAPAGE, BT_WRITE);
metapg = BufferGetPage(metabuf);
metad = BTPageGetMeta(metapg);
/* upgrade metapage if needed */
if (metad->btm_version < BTREE_VERSION)
_bt_upgrademetapage(metapg);
/*
* Create downlink item for left page (old root). Since this will be the
* first item in a non-leaf page, it implicitly has minus-infinity key
* value, so we need not store any actual key in it.
*/
left_item_sz = sizeof(IndexTupleData);
left_item = (IndexTuple) palloc(left_item_sz);
left_item->t_info = left_item_sz;
ItemPointerSet(&(left_item->t_tid), lbkno, P_HIKEY);
/*
* Create downlink item for right page. The key for it is obtained from
* the "high key" position in the left page.
*/
itemid = PageGetItemId(lpage, P_HIKEY);
right_item_sz = ItemIdGetLength(itemid);
item = (IndexTuple) PageGetItem(lpage, itemid);
right_item = CopyIndexTuple(item);
ItemPointerSet(&(right_item->t_tid), rbkno, P_HIKEY);
/* NO EREPORT(ERROR) from here till newroot op is logged */
START_CRIT_SECTION();
/* set btree special data */
rootopaque = (BTPageOpaque) PageGetSpecialPointer(rootpage);
rootopaque->btpo_prev = rootopaque->btpo_next = P_NONE;
rootopaque->btpo_flags = BTP_ROOT;
rootopaque->btpo.level =
((BTPageOpaque) PageGetSpecialPointer(lpage))->btpo.level + 1;
rootopaque->btpo_cycleid = 0;
/* update metapage data */
metad->btm_root = rootblknum;
metad->btm_level = rootopaque->btpo.level;
metad->btm_fastroot = rootblknum;
metad->btm_fastlevel = rootopaque->btpo.level;
/*
* Insert the left page pointer into the new root page. The root page is
* the rightmost page on its level so there is no "high key" in it; the
* two items will go into positions P_HIKEY and P_FIRSTKEY.
*
* Note: we *must* insert the two items in item-number order, for the
* benefit of _bt_restore_page().
*/
if (PageAddItem(rootpage, (Item) left_item, left_item_sz, P_HIKEY,
false, false) == InvalidOffsetNumber)
elog(PANIC, "failed to add leftkey to new root page"
" while splitting block %u of index \"%s\"",
BufferGetBlockNumber(lbuf), RelationGetRelationName(rel));
/*
* insert the right page pointer into the new root page.
*/
if (PageAddItem(rootpage, (Item) right_item, right_item_sz, P_FIRSTKEY,
false, false) == InvalidOffsetNumber)
elog(PANIC, "failed to add rightkey to new root page"
" while splitting block %u of index \"%s\"",
BufferGetBlockNumber(lbuf), RelationGetRelationName(rel));
/* Clear the incomplete-split flag in the left child */
Assert(P_INCOMPLETE_SPLIT(lopaque));
lopaque->btpo_flags &= ~BTP_INCOMPLETE_SPLIT;
MarkBufferDirty(lbuf);
MarkBufferDirty(rootbuf);
MarkBufferDirty(metabuf);
/* XLOG stuff */
if (RelationNeedsWAL(rel))
{
xl_btree_newroot xlrec;
XLogRecPtr recptr;
xl_btree_metadata md;
xlrec.rootblk = rootblknum;
xlrec.level = metad->btm_level;
XLogBeginInsert();
XLogRegisterData((char *) &xlrec, SizeOfBtreeNewroot);
XLogRegisterBuffer(0, rootbuf, REGBUF_WILL_INIT);
XLogRegisterBuffer(1, lbuf, REGBUF_STANDARD);
XLogRegisterBuffer(2, metabuf, REGBUF_WILL_INIT | REGBUF_STANDARD);
md.root = rootblknum;
md.level = metad->btm_level;
md.fastroot = rootblknum;
md.fastlevel = metad->btm_level;
md.oldest_btpo_xact = metad->btm_oldest_btpo_xact;
md.last_cleanup_num_heap_tuples = metad->btm_last_cleanup_num_heap_tuples;
XLogRegisterBufData(2, (char *) &md, sizeof(xl_btree_metadata));
/*
* Direct access to page is not good but faster - we should implement
* some new func in page API.
*/
XLogRegisterBufData(0,
(char *) rootpage + ((PageHeader) rootpage)->pd_upper,
((PageHeader) rootpage)->pd_special -
((PageHeader) rootpage)->pd_upper);
recptr = XLogInsert(RM_BTREE_ID, XLOG_BTREE_NEWROOT);
PageSetLSN(lpage, recptr);
PageSetLSN(rootpage, recptr);
PageSetLSN(metapg, recptr);
}
END_CRIT_SECTION();
/* done with metapage */
_bt_relbuf(rel, metabuf);
pfree(left_item);
pfree(right_item);
return rootbuf;
}
/*
* _bt_pgaddtup() -- add a tuple to a particular page in the index.
*
* This routine adds the tuple to the page as requested. It does
* not affect pin/lock status, but you'd better have a write lock
* and pin on the target buffer! Don't forget to write and release
* the buffer afterwards, either.
*
* The main difference between this routine and a bare PageAddItem call
* is that this code knows that the leftmost index tuple on a non-leaf
* btree page doesn't need to have a key. Therefore, it strips such
* tuples down to just the tuple header. CAUTION: this works ONLY if
* we insert the tuples in order, so that the given itup_off does
* represent the final position of the tuple!
*/
static bool
_bt_pgaddtup(Page page,
Size itemsize,
IndexTuple itup,
OffsetNumber itup_off)
{
BTPageOpaque opaque = (BTPageOpaque) PageGetSpecialPointer(page);
IndexTupleData trunctuple;
if (!P_ISLEAF(opaque) && itup_off == P_FIRSTDATAKEY(opaque))
{
trunctuple = *itup;
trunctuple.t_info = sizeof(IndexTupleData);
itup = &trunctuple;
itemsize = sizeof(IndexTupleData);
}
if (PageAddItem(page, (Item) itup, itemsize, itup_off,
false, false) == InvalidOffsetNumber)
return false;
return true;
}
/*
* _bt_isequal - used in _bt_doinsert in check for duplicates.
*
* This is very similar to _bt_compare, except for NULL handling.
* Rule is simple: NOT_NULL not equal NULL, NULL not equal NULL too.
*/
static bool
_bt_isequal(TupleDesc itupdesc, Page page, OffsetNumber offnum,
int keysz, ScanKey scankey)
{
IndexTuple itup;
int i;
/* Better be comparing to a leaf item */
Assert(P_ISLEAF((BTPageOpaque) PageGetSpecialPointer(page)));
itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, offnum));
for (i = 1; i <= keysz; i++)
{
AttrNumber attno;
Datum datum;
bool isNull;
int32 result;
attno = scankey->sk_attno;
Assert(attno == i);
datum = index_getattr(itup, attno, itupdesc, &isNull);
/* NULLs are never equal to anything */
if (isNull || (scankey->sk_flags & SK_ISNULL))
return false;
result = DatumGetInt32(FunctionCall2Coll(&scankey->sk_func,
scankey->sk_collation,
datum,
scankey->sk_argument));
if (result != 0)
return false;
scankey++;
}
/* if we get here, the keys are equal */
return true;
}
/*
* _bt_vacuum_one_page - vacuum just one index page.
*
* Try to remove LP_DEAD items from the given page. The passed buffer
* must be exclusive-locked, but unlike a real VACUUM, we don't need a
* super-exclusive "cleanup" lock (see nbtree/README).
*/
static void
_bt_vacuum_one_page(Relation rel, Buffer buffer, Relation heapRel)
{
OffsetNumber deletable[MaxOffsetNumber];
int ndeletable = 0;
OffsetNumber offnum,
minoff,
maxoff;
Page page = BufferGetPage(buffer);
BTPageOpaque opaque = (BTPageOpaque) PageGetSpecialPointer(page);
/*
* Scan over all items to see which ones need to be deleted according to
* LP_DEAD flags.
*/
minoff = P_FIRSTDATAKEY(opaque);
maxoff = PageGetMaxOffsetNumber(page);
for (offnum = minoff;
offnum <= maxoff;
offnum = OffsetNumberNext(offnum))
{
ItemId itemId = PageGetItemId(page, offnum);
if (ItemIdIsDead(itemId))
deletable[ndeletable++] = offnum;
}
if (ndeletable > 0)
_bt_delitems_delete(rel, buffer, deletable, ndeletable, heapRel);
/*
* Note: if we didn't find any LP_DEAD items, then the page's
* BTP_HAS_GARBAGE hint bit is falsely set. We do not bother expending a
* separate write to clear it, however. We will clear it when we split
* the page.
*/
}
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