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postgres/src/backend/access/nbtree/nbtinsert.c
Tom Lane b7b78d24f7 Code review for FILLFACTOR patch. Change WITH grammar as per earlier 
discussion (including making def_arg allow reserved words), add missed
opt_definition for UNIQUE case.  Put the reloptions support code in a less
random place (I chose to make a new file access/common/reloptions.c).
Eliminate header inclusion creep.  Make the index options functions safely
user-callable (seems like client apps might like to be able to test validity
of options before trying to make an index).  Reduce overhead for normal case
with no options by allowing rd_options to be NULL.  Fix some unmaintainably
klugy code, including getting rid of Natts_pg_class_fixed at long last.
Some stylistic cleanup too, and pay attention to keeping comments in sync
with code.

Documentation still needs work, though I did fix the omissions in
catalogs.sgml and indexam.sgml.
2006-07-03 22:45:41 +00:00

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/*-------------------------------------------------------------------------
*
* nbtinsert.c
* Item insertion in Lehman and Yao btrees for Postgres.
*
* Portions Copyright (c) 1996-2006, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* $PostgreSQL: pgsql/src/backend/access/nbtree/nbtinsert.c,v 1.139 2006/07/03 22:45:37 tgl Exp $
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "access/heapam.h"
#include "access/nbtree.h"
#include "miscadmin.h"
#include "utils/inval.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 */
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,
ScanKey itup_scankey);
static void _bt_insertonpg(Relation rel, Buffer buf,
BTStack stack,
int keysz, ScanKey scankey,
IndexTuple itup,
OffsetNumber afteritem,
bool split_only_page);
static Buffer _bt_split(Relation rel, Buffer buf, OffsetNumber firstright,
OffsetNumber newitemoff, Size newitemsz,
IndexTuple newitem, bool newitemonleft);
static OffsetNumber _bt_findsplitloc(Relation rel, Page page,
OffsetNumber newitemoff,
Size newitemsz,
bool *newitemonleft);
static void _bt_checksplitloc(FindSplitData *state, OffsetNumber firstright,
int leftfree, int rightfree,
bool newitemonleft, Size firstrightitemsz);
static void _bt_pgaddtup(Relation rel, Page page,
Size itemsize, IndexTuple itup,
OffsetNumber itup_off, const char *where);
static bool _bt_isequal(TupleDesc itupdesc, Page page, OffsetNumber offnum,
int keysz, ScanKey scankey);
/*
* _bt_doinsert() -- Handle insertion of a single index tuple in the tree.
*
* This routine is called by the public interface routines, btbuild
* and btinsert. By here, itup is filled in, including the TID.
*/
void
_bt_doinsert(Relation rel, IndexTuple itup,
bool index_is_unique, Relation heapRel)
{
int natts = rel->rd_rel->relnatts;
ScanKey itup_scankey;
BTStack stack;
Buffer buf;
/* we need an insertion scan key to do our search, so build one */
itup_scankey = _bt_mkscankey(rel, itup);
top:
/* find the first page containing this key */
stack = _bt_search(rel, natts, itup_scankey, false, &buf, BT_WRITE);
/* 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, BT_WRITE);
/*
* 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.
*/
if (index_is_unique)
{
TransactionId xwait;
xwait = _bt_check_unique(rel, itup, heapRel, buf, itup_scankey);
if (TransactionIdIsValid(xwait))
{
/* Have to wait for the other guy ... */
_bt_relbuf(rel, buf);
XactLockTableWait(xwait);
/* start over... */
_bt_freestack(stack);
goto top;
}
}
/* do the insertion */
_bt_insertonpg(rel, buf, stack, natts, itup_scankey, itup, 0, false);
/* be tidy */
_bt_freestack(stack);
_bt_freeskey(itup_scankey);
}
/*
* _bt_check_unique() -- Check for violation of unique index constraint
*
* 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().
*/
static TransactionId
_bt_check_unique(Relation rel, IndexTuple itup, Relation heapRel,
Buffer buf, ScanKey itup_scankey)
{
TupleDesc itupdesc = RelationGetDescr(rel);
int natts = rel->rd_rel->relnatts;
OffsetNumber offset,
maxoff;
Page page;
BTPageOpaque opaque;
Buffer nbuf = InvalidBuffer;
page = BufferGetPage(buf);
opaque = (BTPageOpaque) PageGetSpecialPointer(page);
maxoff = PageGetMaxOffsetNumber(page);
/*
* Find first item >= proposed new item. Note we could also get a pointer
* to end-of-page here.
*/
offset = _bt_binsrch(rel, buf, natts, itup_scankey, false);
/*
* Scan over all equal tuples, looking for live conflicts.
*/
for (;;)
{
HeapTupleData htup;
Buffer hbuffer;
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 (!ItemIdDeleted(curitemid))
{
/*
* _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);
htup.t_self = curitup->t_tid;
if (heap_fetch(heapRel, SnapshotDirty, &htup, &hbuffer,
true, NULL))
{
/* it is a duplicate */
TransactionId xwait =
(TransactionIdIsValid(SnapshotDirty->xmin)) ?
SnapshotDirty->xmin : SnapshotDirty->xmax;
ReleaseBuffer(hbuffer);
/*
* If this tuple is being updated by other transaction
* then we have to wait for its commit/abort.
*/
if (TransactionIdIsValid(xwait))
{
if (nbuf != InvalidBuffer)
_bt_relbuf(rel, nbuf);
/* Tell _bt_doinsert to wait... */
return xwait;
}
/*
* Otherwise we have a definite conflict.
*/
ereport(ERROR,
(errcode(ERRCODE_UNIQUE_VIOLATION),
errmsg("duplicate key violates unique constraint \"%s\"",
RelationGetRelationName(rel))));
}
else if (htup.t_data != NULL)
{
/*
* Hmm, if we can't see the tuple, maybe it can be marked
* killed. This logic should match index_getnext and
* btgettuple.
*/
LockBuffer(hbuffer, BUFFER_LOCK_SHARE);
if (HeapTupleSatisfiesVacuum(htup.t_data, RecentGlobalXmin,
hbuffer) == HEAPTUPLE_DEAD)
{
curitemid->lp_flags |= LP_DELETE;
if (nbuf != InvalidBuffer)
SetBufferCommitInfoNeedsSave(nbuf);
else
SetBufferCommitInfoNeedsSave(buf);
}
LockBuffer(hbuffer, BUFFER_LOCK_UNLOCK);
}
ReleaseBuffer(hbuffer);
}
}
/*
* 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 \"%s\"",
RelationGetRelationName(rel));
}
maxoff = PageGetMaxOffsetNumber(page);
offset = P_FIRSTDATAKEY(opaque);
}
}
if (nbuf != InvalidBuffer)
_bt_relbuf(rel, nbuf);
return InvalidTransactionId;
}
/*----------
* _bt_insertonpg() -- Insert a tuple on a particular page in the index.
*
* This recursive procedure does the following things:
*
* + finds the right place to insert the tuple.
* + 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 right 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.
*
* If 'afteritem' is >0 then the new tuple must be inserted after the
* existing item of that number, noplace else. If 'afteritem' is 0
* then the procedure finds the exact spot to insert it by searching.
* (keysz and scankey parameters are used ONLY if afteritem == 0.
* The scankey must be an insertion-type scankey.)
*
* NOTE: 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.
*
* 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,
BTStack stack,
int keysz,
ScanKey scankey,
IndexTuple itup,
OffsetNumber afteritem,
bool split_only_page)
{
Page page;
BTPageOpaque lpageop;
OffsetNumber newitemoff;
OffsetNumber firstright = InvalidOffsetNumber;
Size itemsz;
page = BufferGetPage(buf);
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
itemsz = IndexTupleDSize(*itup);
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.
*/
if (itemsz > BTMaxItemSize(page))
ereport(ERROR,
(errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
errmsg("index row size %lu exceeds btree maximum, %lu",
(unsigned long) itemsz,
(unsigned long) BTMaxItemSize(page)),
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.")));
/*
* Determine exactly where new item will go.
*/
if (afteritem > 0)
newitemoff = afteritem + 1;
else
{
/*----------
* If we will need to split the page to put the item here,
* 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.
*----------
*/
bool movedright = false;
while (PageGetFreeSpace(page) < itemsz &&
!P_RIGHTMOST(lpageop) &&
_bt_compare(rel, keysz, scankey, page, P_HIKEY) == 0 &&
random() > (MAX_RANDOM_VALUE / 100))
{
/*
* 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.
*/
Buffer rbuf = InvalidBuffer;
for (;;)
{
BlockNumber rblkno = lpageop->btpo_next;
rbuf = _bt_relandgetbuf(rel, rbuf, rblkno, BT_WRITE);
page = BufferGetPage(rbuf);
lpageop = (BTPageOpaque) PageGetSpecialPointer(page);
if (!P_IGNORE(lpageop))
break;
if (P_RIGHTMOST(lpageop))
elog(ERROR, "fell off the end of \"%s\"",
RelationGetRelationName(rel));
}
_bt_relbuf(rel, buf);
buf = rbuf;
movedright = true;
}
/*
* 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, else must find the position by searching.
*/
if (movedright)
newitemoff = P_FIRSTDATAKEY(lpageop);
else
newitemoff = _bt_binsrch(rel, buf, keysz, scankey, false);
}
/*
* 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, firstright,
newitemoff, itemsz, itup, newitemonleft);
/*----------
* 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();
_bt_pgaddtup(rel, page, itemsz, itup, newitemoff, "page");
MarkBufferDirty(buf);
if (BufferIsValid(metabuf))
{
metad->btm_fastroot = itup_blkno;
metad->btm_fastlevel = lpageop->btpo.level;
MarkBufferDirty(metabuf);
}
/* XLOG stuff */
if (!rel->rd_istemp)
{
xl_btree_insert xlrec;
BlockNumber xldownlink;
xl_btree_metadata xlmeta;
uint8 xlinfo;
XLogRecPtr recptr;
XLogRecData rdata[4];
XLogRecData *nextrdata;
IndexTupleData trunctuple;
xlrec.target.node = rel->rd_node;
ItemPointerSet(&(xlrec.target.tid), itup_blkno, itup_off);
rdata[0].data = (char *) &xlrec;
rdata[0].len = SizeOfBtreeInsert;
rdata[0].buffer = InvalidBuffer;
rdata[0].next = nextrdata = &(rdata[1]);
if (P_ISLEAF(lpageop))
xlinfo = XLOG_BTREE_INSERT_LEAF;
else
{
xldownlink = ItemPointerGetBlockNumber(&(itup->t_tid));
Assert(ItemPointerGetOffsetNumber(&(itup->t_tid)) == P_HIKEY);
nextrdata->data = (char *) &xldownlink;
nextrdata->len = sizeof(BlockNumber);
nextrdata->buffer = InvalidBuffer;
nextrdata->next = nextrdata + 1;
nextrdata++;
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;
nextrdata->data = (char *) &xlmeta;
nextrdata->len = sizeof(xl_btree_metadata);
nextrdata->buffer = InvalidBuffer;
nextrdata->next = nextrdata + 1;
nextrdata++;
xlinfo = XLOG_BTREE_INSERT_META;
}
/* Read comments in _bt_pgaddtup */
if (!P_ISLEAF(lpageop) && newitemoff == P_FIRSTDATAKEY(lpageop))
{
trunctuple = *itup;
trunctuple.t_info = sizeof(IndexTupleData);
nextrdata->data = (char *) &trunctuple;
nextrdata->len = sizeof(IndexTupleData);
}
else
{
nextrdata->data = (char *) itup;
nextrdata->len = IndexTupleDSize(*itup);
}
nextrdata->buffer = buf;
nextrdata->buffer_std = true;
nextrdata->next = NULL;
recptr = XLogInsert(RM_BTREE_ID, xlinfo, rdata);
if (BufferIsValid(metabuf))
{
PageSetLSN(metapg, recptr);
PageSetTLI(metapg, ThisTimeLineID);
}
PageSetLSN(page, recptr);
PageSetTLI(page, ThisTimeLineID);
}
END_CRIT_SECTION();
/* release buffers; send out relcache inval if metapage changed */
if (BufferIsValid(metabuf))
{
CacheInvalidateRelcache(rel);
_bt_relbuf(rel, metabuf);
}
_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.
*
* 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, OffsetNumber firstright,
OffsetNumber newitemoff, Size newitemsz, IndexTuple newitem,
bool newitemonleft)
{
Buffer rbuf;
Page origpage;
Page leftpage,
rightpage;
BTPageOpaque ropaque,
lopaque,
oopaque;
Buffer sbuf = InvalidBuffer;
Page spage = NULL;
BTPageOpaque sopaque = NULL;
OffsetNumber itup_off = 0;
BlockNumber itup_blkno = 0;
Size itemsz;
ItemId itemid;
IndexTuple item;
OffsetNumber leftoff,
rightoff;
OffsetNumber maxoff;
OffsetNumber i;
rbuf = _bt_getbuf(rel, P_NEW, BT_WRITE);
origpage = BufferGetPage(buf);
leftpage = PageGetTempPage(origpage, sizeof(BTPageOpaqueData));
rightpage = BufferGetPage(rbuf);
_bt_pageinit(leftpage, BufferGetPageSize(buf));
/* rightpage was already initialized by _bt_getbuf */
/* init btree private data */
oopaque = (BTPageOpaque) PageGetSpecialPointer(origpage);
lopaque = (BTPageOpaque) PageGetSpecialPointer(leftpage);
ropaque = (BTPageOpaque) PageGetSpecialPointer(rightpage);
/* if we're splitting this page, it won't be the root when we're done */
/* also, clear the SPLIT_END flag in both pages */
lopaque->btpo_flags = oopaque->btpo_flags;
lopaque->btpo_flags &= ~(BTP_ROOT | BTP_SPLIT_END);
ropaque->btpo_flags = lopaque->btpo_flags;
lopaque->btpo_prev = oopaque->btpo_prev;
lopaque->btpo_next = BufferGetBlockNumber(rbuf);
ropaque->btpo_prev = BufferGetBlockNumber(buf);
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,
LP_USED) == InvalidOffsetNumber)
elog(PANIC, "failed to add hikey to the right sibling");
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,
LP_USED) == InvalidOffsetNumber)
elog(PANIC, "failed to add hikey to the left sibling");
leftoff = OffsetNumberNext(leftoff);
/*
* Now transfer all the data items to the appropriate 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)
{
_bt_pgaddtup(rel, leftpage, newitemsz, newitem, leftoff,
"left sibling");
itup_off = leftoff;
itup_blkno = BufferGetBlockNumber(buf);
leftoff = OffsetNumberNext(leftoff);
}
else
{
_bt_pgaddtup(rel, rightpage, newitemsz, newitem, rightoff,
"right sibling");
itup_off = rightoff;
itup_blkno = BufferGetBlockNumber(rbuf);
rightoff = OffsetNumberNext(rightoff);
}
}
/* decide which page to put it on */
if (i < firstright)
{
_bt_pgaddtup(rel, leftpage, itemsz, item, leftoff,
"left sibling");
leftoff = OffsetNumberNext(leftoff);
}
else
{
_bt_pgaddtup(rel, rightpage, itemsz, item, rightoff,
"right sibling");
rightoff = OffsetNumberNext(rightoff);
}
}
/* cope with possibility that newitem goes at the end */
if (i <= newitemoff)
{
if (newitemonleft)
{
_bt_pgaddtup(rel, leftpage, newitemsz, newitem, leftoff,
"left sibling");
itup_off = leftoff;
itup_blkno = BufferGetBlockNumber(buf);
leftoff = OffsetNumberNext(leftoff);
}
else
{
_bt_pgaddtup(rel, rightpage, newitemsz, newitem, rightoff,
"right sibling");
itup_off = rightoff;
itup_blkno = BufferGetBlockNumber(rbuf);
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(ropaque))
{
sbuf = _bt_getbuf(rel, ropaque->btpo_next, BT_WRITE);
spage = BufferGetPage(sbuf);
sopaque = (BTPageOpaque) PageGetSpecialPointer(spage);
if (sopaque->btpo_prev != ropaque->btpo_prev)
elog(PANIC, "right sibling's left-link doesn't match");
/*
* 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. Log changes before continuing.
*
* 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, and we don't care about the
* new sibling until it's linked into the btree.
*/
START_CRIT_SECTION();
MarkBufferDirty(buf);
MarkBufferDirty(rbuf);
if (!P_RIGHTMOST(ropaque))
{
sopaque->btpo_prev = BufferGetBlockNumber(rbuf);
MarkBufferDirty(sbuf);
}
/* XLOG stuff */
if (!rel->rd_istemp)
{
xl_btree_split xlrec;
uint8 xlinfo;
XLogRecPtr recptr;
XLogRecData rdata[4];
xlrec.target.node = rel->rd_node;
ItemPointerSet(&(xlrec.target.tid), itup_blkno, itup_off);
if (newitemonleft)
xlrec.otherblk = BufferGetBlockNumber(rbuf);
else
xlrec.otherblk = BufferGetBlockNumber(buf);
xlrec.leftblk = lopaque->btpo_prev;
xlrec.rightblk = ropaque->btpo_next;
xlrec.level = lopaque->btpo.level;
/*
* 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 the item pointers are in the same order
* and can be reconstructed by scanning the tuples. See comments
* for _bt_restore_page().
*/
xlrec.leftlen = ((PageHeader) leftpage)->pd_special -
((PageHeader) leftpage)->pd_upper;
rdata[0].data = (char *) &xlrec;
rdata[0].len = SizeOfBtreeSplit;
rdata[0].buffer = InvalidBuffer;
rdata[0].next = &(rdata[1]);
rdata[1].data = (char *) leftpage + ((PageHeader) leftpage)->pd_upper;
rdata[1].len = xlrec.leftlen;
rdata[1].buffer = InvalidBuffer;
rdata[1].next = &(rdata[2]);
rdata[2].data = (char *) rightpage + ((PageHeader) rightpage)->pd_upper;
rdata[2].len = ((PageHeader) rightpage)->pd_special -
((PageHeader) rightpage)->pd_upper;
rdata[2].buffer = InvalidBuffer;
rdata[2].next = NULL;
if (!P_RIGHTMOST(ropaque))
{
rdata[2].next = &(rdata[3]);
rdata[3].data = NULL;
rdata[3].len = 0;
rdata[3].buffer = sbuf;
rdata[3].buffer_std = true;
rdata[3].next = NULL;
}
if (P_ISROOT(oopaque))
xlinfo = newitemonleft ? XLOG_BTREE_SPLIT_L_ROOT : XLOG_BTREE_SPLIT_R_ROOT;
else
xlinfo = newitemonleft ? XLOG_BTREE_SPLIT_L : XLOG_BTREE_SPLIT_R;
recptr = XLogInsert(RM_BTREE_ID, xlinfo, rdata);
PageSetLSN(leftpage, recptr);
PageSetTLI(leftpage, ThisTimeLineID);
PageSetLSN(rightpage, recptr);
PageSetTLI(rightpage, ThisTimeLineID);
if (!P_RIGHTMOST(ropaque))
{
PageSetLSN(spage, recptr);
PageSetTLI(spage, ThisTimeLineID);
}
}
/*
* 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.)
*
* It's a bit weird that we don't fill in the left page till after writing
* the XLOG entry, but not really worth changing. Note that we use the
* origpage data (specifically its BTP_ROOT bit) while preparing the XLOG
* entry, so simply reshuffling the code won't do.
*/
PageRestoreTempPage(leftpage, origpage);
END_CRIT_SECTION();
/* release the old right sibling */
if (!P_RIGHTMOST(ropaque))
_bt_relbuf(rel, sbuf);
/* 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.
*
* 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,
dataitemtotal,
dataitemstoleft;
opaque = (BTPageOpaque) PageGetSpecialPointer(page);
/* Passed-in newitemsz is MAXALIGNED but does not include line pointer */
newitemsz += sizeof(ItemIdData);
state.newitemsz = newitemsz;
state.fillfactor = RelationGetFillFactor(rel, BTREE_DEFAULT_FILLFACTOR);
state.is_leaf = P_ISLEAF(opaque);
state.is_rightmost = P_RIGHTMOST(opaque);
state.have_split = false;
/* Total free space available on a btree page, after fixed overhead */
leftspace = rightspace =
PageGetPageSize(page) - SizeOfPageHeaderData -
MAXALIGN(sizeof(BTPageOpaqueData));
/*
* 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;
/* 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 */
dataitemtotal = rightspace - (int) PageGetFreeSpace(page);
/*
* Scan through the data items and calculate space usage for a split at
* each possible position.
*/
dataitemstoleft = 0;
maxoff = PageGetMaxOffsetNumber(page);
for (offnum = P_FIRSTDATAKEY(opaque);
offnum <= maxoff;
offnum = OffsetNumberNext(offnum))
{
Size itemsz;
int leftfree,
rightfree;
itemid = PageGetItemId(page, offnum);
itemsz = MAXALIGN(ItemIdGetLength(itemid)) + sizeof(ItemIdData);
/*
* We have to allow for the current item becoming the high key of the
* left page; therefore it counts against left space as well as right
* space.
*/
leftfree = leftspace - dataitemstoleft - (int) itemsz;
rightfree = rightspace - (dataitemtotal - dataitemstoleft);
/*
* Will the new item go to left or right of split?
*/
if (offnum > newitemoff)
_bt_checksplitloc(&state, offnum, leftfree, rightfree,
true, itemsz);
else if (offnum < newitemoff)
_bt_checksplitloc(&state, offnum, leftfree, rightfree,
false, itemsz);
else
{
/* need to try it both ways! */
_bt_checksplitloc(&state, offnum, leftfree, rightfree,
true, itemsz);
/* here we are contemplating newitem as first on right */
_bt_checksplitloc(&state, offnum, leftfree, rightfree,
false, newitemsz);
}
/* Abort scan once we find a good-enough choice */
if (state.have_split && state.best_delta <= goodenough)
break;
dataitemstoleft += itemsz;
}
/*
* 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 \"%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.
*/
static void
_bt_checksplitloc(FindSplitData *state, OffsetNumber firstright,
int leftfree, int rightfree,
bool newitemonleft, Size firstrightitemsz)
{
/*
* Account for the new item on whichever side it is to be put.
*/
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 = firstright;
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)
*
* This is exported so it can be called by nbtxlog.c.
*/
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. (This path is also taken when called from WAL recovery ---
* we have no stack in that case.)
*/
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;
if (!InRecovery)
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);
/* 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 children */
_bt_relbuf(rel, rbuf);
_bt_relbuf(rel, buf);
/* Check for error only after writing children */
if (pbuf == InvalidBuffer)
elog(ERROR, "failed to re-find parent key in \"%s\"",
RelationGetRelationName(rel));
/* Recursively update the parent */
_bt_insertonpg(rel, pbuf, stack->bts_parent,
0, NULL, new_item, stack->bts_offset,
is_only);
/* be tidy */
pfree(new_item);
}
}
/*
* _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 (!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;
ItemId itemid;
IndexTuple item;
Size itemsz;
IndexTuple new_item;
Buffer metabuf;
Page metapg;
BTMetaPageData *metad;
lbkno = BufferGetBlockNumber(lbuf);
rbkno = BufferGetBlockNumber(rbuf);
lpage = BufferGetPage(lbuf);
/* 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);
/* 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;
/*
* 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.
*/
itemsz = sizeof(IndexTupleData);
new_item = (IndexTuple) palloc(itemsz);
new_item->t_info = itemsz;
ItemPointerSet(&(new_item->t_tid), lbkno, P_HIKEY);
/*
* 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) new_item, itemsz, P_HIKEY, LP_USED) == InvalidOffsetNumber)
elog(PANIC, "failed to add leftkey to new root page");
pfree(new_item);
/*
* 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);
itemsz = ItemIdGetLength(itemid);
item = (IndexTuple) PageGetItem(lpage, itemid);
new_item = CopyIndexTuple(item);
ItemPointerSet(&(new_item->t_tid), rbkno, P_HIKEY);
/*
* insert the right page pointer into the new root page.
*/
if (PageAddItem(rootpage, (Item) new_item, itemsz, P_FIRSTKEY, LP_USED) == InvalidOffsetNumber)
elog(PANIC, "failed to add rightkey to new root page");
pfree(new_item);
MarkBufferDirty(rootbuf);
MarkBufferDirty(metabuf);
/* XLOG stuff */
if (!rel->rd_istemp)
{
xl_btree_newroot xlrec;
XLogRecPtr recptr;
XLogRecData rdata[2];
xlrec.node = rel->rd_node;
xlrec.rootblk = rootblknum;
xlrec.level = metad->btm_level;
rdata[0].data = (char *) &xlrec;
rdata[0].len = SizeOfBtreeNewroot;
rdata[0].buffer = InvalidBuffer;
rdata[0].next = &(rdata[1]);
/*
* Direct access to page is not good but faster - we should implement
* some new func in page API.
*/
rdata[1].data = (char *) rootpage + ((PageHeader) rootpage)->pd_upper;
rdata[1].len = ((PageHeader) rootpage)->pd_special -
((PageHeader) rootpage)->pd_upper;
rdata[1].buffer = InvalidBuffer;
rdata[1].next = NULL;
recptr = XLogInsert(RM_BTREE_ID, XLOG_BTREE_NEWROOT, rdata);
PageSetLSN(rootpage, recptr);
PageSetTLI(rootpage, ThisTimeLineID);
PageSetLSN(metapg, recptr);
PageSetTLI(metapg, ThisTimeLineID);
}
END_CRIT_SECTION();
/* send out relcache inval for metapage change */
CacheInvalidateRelcache(rel);
/* done with metapage */
_bt_relbuf(rel, metabuf);
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 void
_bt_pgaddtup(Relation rel,
Page page,
Size itemsize,
IndexTuple itup,
OffsetNumber itup_off,
const char *where)
{
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,
LP_USED) == InvalidOffsetNumber)
elog(PANIC, "failed to add item to the %s for \"%s\"",
where, RelationGetRelationName(rel));
}
/*
* _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(FunctionCall2(&scankey->sk_func,
datum,
scankey->sk_argument));
if (result != 0)
return false;
scankey++;
}
/* if we get here, the keys are equal */
return true;
}
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