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postgres/src/backend/access/nbtree/nbtsearch.c
Peter Geoghegan 3f44959f47 Avoid unneeded nbtree backwards scan buffer locks. 
Teach nbtree backwards scans to avoid relocking a just-read leaf page to
read its current left sibling link when it isn't truly necessary.  This
happened inside _bt_readnextpage whenever _bt_readpage had already
determined that there'll be no further matches to the left (or at least
none for the current primitive index scan, for a scan with array keys).

A new precheck inside _bt_readnextpage is all that we need to avoid
these useless lock acquisitions.  Arguably, using a precheck like this
was a missed opportunity for commit 2ed5b87f96, which taught nbtree to
drop leaf page pins early to avoid blocking cleanup by VACUUM.  Forwards
scans already managed to avoid relocking the page like this.

The optimization added by this commit is particularly helpful with
backwards scans that use array keys where the scan must perform multiple
primitive index scans.  Such backwards scans will now avoid a useless
leaf page re-lock at the end of each primitive index scan.

Note that this commit does not attempt to avoid needlessly re-locking a
leaf page that was just read when the scan must follow the leaf page's
left link.  That more ambitious optimization could work by stashing the
left link when the page is first read by a backwards scan, allowing the
subsequent _bt_readnextpage call to optimistically skip re-reading the
original page just to get a new copy of its left link.  For now we only
address cases where we don't care about our original page's left link.

Author: Peter Geoghegan <pg@bowt.ie>
Reviewed-By: Matthias van de Meent <boekewurm+postgres@gmail.com>
Discussion: https://postgr.es/m/CAH2-Wz=xgs7PojG=EUvhgadwENzu_mY_riNh-w9wFPsaS717ew@mail.gmail.com
2024-08-11 15:42:52 -04:00

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/*-------------------------------------------------------------------------
*
* nbtsearch.c
* Search code for postgres btrees.
*
*
* Portions Copyright (c) 1996-2024, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
* IDENTIFICATION
* src/backend/access/nbtree/nbtsearch.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "access/nbtree.h"
#include "access/relscan.h"
#include "access/xact.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "storage/predicate.h"
#include "utils/lsyscache.h"
#include "utils/rel.h"
static void _bt_drop_lock_and_maybe_pin(IndexScanDesc scan, BTScanPos sp);
static OffsetNumber _bt_binsrch(Relation rel, BTScanInsert key, Buffer buf);
static int _bt_binsrch_posting(BTScanInsert key, Page page,
OffsetNumber offnum);
static bool _bt_readpage(IndexScanDesc scan, ScanDirection dir,
OffsetNumber offnum, bool firstPage);
static void _bt_saveitem(BTScanOpaque so, int itemIndex,
OffsetNumber offnum, IndexTuple itup);
static int _bt_setuppostingitems(BTScanOpaque so, int itemIndex,
OffsetNumber offnum, ItemPointer heapTid,
IndexTuple itup);
static inline void _bt_savepostingitem(BTScanOpaque so, int itemIndex,
OffsetNumber offnum,
ItemPointer heapTid, int tupleOffset);
static bool _bt_steppage(IndexScanDesc scan, ScanDirection dir);
static bool _bt_readnextpage(IndexScanDesc scan, BlockNumber blkno, ScanDirection dir);
static bool _bt_parallel_readpage(IndexScanDesc scan, BlockNumber blkno,
ScanDirection dir);
static Buffer _bt_walk_left(Relation rel, Buffer buf);
static bool _bt_endpoint(IndexScanDesc scan, ScanDirection dir);
static inline void _bt_initialize_more_data(BTScanOpaque so, ScanDirection dir);
/*
* _bt_drop_lock_and_maybe_pin()
*
* Unlock the buffer; and if it is safe to release the pin, do that, too.
* This will prevent vacuum from stalling in a blocked state trying to read a
* page when a cursor is sitting on it.
*
* See nbtree/README section on making concurrent TID recycling safe.
*/
static void
_bt_drop_lock_and_maybe_pin(IndexScanDesc scan, BTScanPos sp)
{
_bt_unlockbuf(scan->indexRelation, sp->buf);
if (IsMVCCSnapshot(scan->xs_snapshot) &&
RelationNeedsWAL(scan->indexRelation) &&
!scan->xs_want_itup)
{
ReleaseBuffer(sp->buf);
sp->buf = InvalidBuffer;
}
}
/*
* _bt_search() -- Search the tree for a particular scankey,
* or more precisely for the first leaf page it could be on.
*
* The passed scankey is an insertion-type scankey (see nbtree/README),
* but it can omit the rightmost column(s) of the index.
*
* Return value is a stack of parent-page pointers (i.e. there is no entry for
* the leaf level/page). *bufP is set to the address of the leaf-page buffer,
* which is locked and pinned. No locks are held on the parent pages,
* however!
*
* The returned buffer is locked according to access parameter. Additionally,
* access = BT_WRITE will allow an empty root page to be created and returned.
* When access = BT_READ, an empty index will result in *bufP being set to
* InvalidBuffer. Also, in BT_WRITE mode, any incomplete splits encountered
* during the search will be finished.
*
* heaprel must be provided by callers that pass access = BT_WRITE, since we
* might need to allocate a new root page for caller -- see _bt_allocbuf.
*/
BTStack
_bt_search(Relation rel, Relation heaprel, BTScanInsert key, Buffer *bufP,
int access)
{
BTStack stack_in = NULL;
int page_access = BT_READ;
/* heaprel must be set whenever _bt_allocbuf is reachable */
Assert(access == BT_READ || access == BT_WRITE);
Assert(access == BT_READ || heaprel != NULL);
/* Get the root page to start with */
*bufP = _bt_getroot(rel, heaprel, access);
/* If index is empty and access = BT_READ, no root page is created. */
if (!BufferIsValid(*bufP))
return (BTStack) NULL;
/* Loop iterates once per level descended in the tree */
for (;;)
{
Page page;
BTPageOpaque opaque;
OffsetNumber offnum;
ItemId itemid;
IndexTuple itup;
BlockNumber child;
BTStack new_stack;
/*
* Race -- the page we just grabbed may have split since we read its
* downlink in its parent page (or the metapage). If it has, we may
* need to move right to its new sibling. Do that.
*
* In write-mode, allow _bt_moveright to finish any incomplete splits
* along the way. Strictly speaking, we'd only need to finish an
* incomplete split on the leaf page we're about to insert to, not on
* any of the upper levels (internal pages with incomplete splits are
* also taken care of in _bt_getstackbuf). But this is a good
* opportunity to finish splits of internal pages too.
*/
*bufP = _bt_moveright(rel, heaprel, key, *bufP, (access == BT_WRITE),
stack_in, page_access);
/* if this is a leaf page, we're done */
page = BufferGetPage(*bufP);
opaque = BTPageGetOpaque(page);
if (P_ISLEAF(opaque))
break;
/*
* Find the appropriate pivot tuple on this page. Its downlink points
* to the child page that we're about to descend to.
*/
offnum = _bt_binsrch(rel, key, *bufP);
itemid = PageGetItemId(page, offnum);
itup = (IndexTuple) PageGetItem(page, itemid);
Assert(BTreeTupleIsPivot(itup) || !key->heapkeyspace);
child = BTreeTupleGetDownLink(itup);
/*
* We need to save the location of the pivot tuple we chose in a new
* stack entry for this page/level. If caller ends up splitting a
* page one level down, it usually ends up inserting a new pivot
* tuple/downlink immediately after the location recorded here.
*/
new_stack = (BTStack) palloc(sizeof(BTStackData));
new_stack->bts_blkno = BufferGetBlockNumber(*bufP);
new_stack->bts_offset = offnum;
new_stack->bts_parent = stack_in;
/*
* Page level 1 is lowest non-leaf page level prior to leaves. So, if
* we're on the level 1 and asked to lock leaf page in write mode,
* then lock next page in write mode, because it must be a leaf.
*/
if (opaque->btpo_level == 1 && access == BT_WRITE)
page_access = BT_WRITE;
/* drop the read lock on the page, then acquire one on its child */
*bufP = _bt_relandgetbuf(rel, *bufP, child, page_access);
/* okay, all set to move down a level */
stack_in = new_stack;
}
/*
* If we're asked to lock leaf in write mode, but didn't manage to, then
* relock. This should only happen when the root page is a leaf page (and
* the only page in the index other than the metapage).
*/
if (access == BT_WRITE && page_access == BT_READ)
{
/* trade in our read lock for a write lock */
_bt_unlockbuf(rel, *bufP);
_bt_lockbuf(rel, *bufP, BT_WRITE);
/*
* Race -- the leaf page may have split after we dropped the read lock
* but before we acquired a write lock. If it has, we may need to
* move right to its new sibling. Do that.
*/
*bufP = _bt_moveright(rel, heaprel, key, *bufP, true, stack_in, BT_WRITE);
}
return stack_in;
}
/*
* _bt_moveright() -- move right in the btree if necessary.
*
* When we follow a pointer to reach a page, it is possible that
* the page has changed in the meanwhile. If this happens, we're
* guaranteed that the page has "split right" -- that is, that any
* data that appeared on the page originally is either on the page
* or strictly to the right of it.
*
* This routine decides whether or not we need to move right in the
* tree by examining the high key entry on the page. If that entry is
* strictly less than the scankey, or <= the scankey in the
* key.nextkey=true case, then we followed the wrong link and we need
* to move right.
*
* The passed insertion-type scankey can omit the rightmost column(s) of the
* index. (see nbtree/README)
*
* When key.nextkey is false (the usual case), we are looking for the first
* item >= key. When key.nextkey is true, we are looking for the first item
* strictly greater than key.
*
* If forupdate is true, we will attempt to finish any incomplete splits
* that we encounter. This is required when locking a target page for an
* insertion, because we don't allow inserting on a page before the split is
* completed. 'heaprel' and 'stack' are only used if forupdate is true.
*
* On entry, we have the buffer pinned and a lock of the type specified by
* 'access'. If we move right, we release the buffer and lock and acquire
* the same on the right sibling. Return value is the buffer we stop at.
*/
Buffer
_bt_moveright(Relation rel,
Relation heaprel,
BTScanInsert key,
Buffer buf,
bool forupdate,
BTStack stack,
int access)
{
Page page;
BTPageOpaque opaque;
int32 cmpval;
Assert(!forupdate || heaprel != NULL);
/*
* When nextkey = false (normal case): if the scan key that brought us to
* this page is > the high key stored on the page, then the page has split
* and we need to move right. (pg_upgrade'd !heapkeyspace indexes could
* have some duplicates to the right as well as the left, but that's
* something that's only ever dealt with on the leaf level, after
* _bt_search has found an initial leaf page.)
*
* When nextkey = true: move right if the scan key is >= page's high key.
* (Note that key.scantid cannot be set in this case.)
*
* The page could even have split more than once, so scan as far as
* needed.
*
* We also have to move right if we followed a link that brought us to a
* dead page.
*/
cmpval = key->nextkey ? 0 : 1;
for (;;)
{
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
if (P_RIGHTMOST(opaque))
break;
/*
* Finish any incomplete splits we encounter along the way.
*/
if (forupdate && P_INCOMPLETE_SPLIT(opaque))
{
BlockNumber blkno = BufferGetBlockNumber(buf);
/* upgrade our lock if necessary */
if (access == BT_READ)
{
_bt_unlockbuf(rel, buf);
_bt_lockbuf(rel, buf, BT_WRITE);
}
if (P_INCOMPLETE_SPLIT(opaque))
_bt_finish_split(rel, heaprel, buf, stack);
else
_bt_relbuf(rel, buf);
/* re-acquire the lock in the right mode, and re-check */
buf = _bt_getbuf(rel, blkno, access);
continue;
}
if (P_IGNORE(opaque) || _bt_compare(rel, key, page, P_HIKEY) >= cmpval)
{
/* step right one page */
buf = _bt_relandgetbuf(rel, buf, opaque->btpo_next, access);
continue;
}
else
break;
}
if (P_IGNORE(opaque))
elog(ERROR, "fell off the end of index \"%s\"",
RelationGetRelationName(rel));
return buf;
}
/*
* _bt_binsrch() -- Do a binary search for a key on a particular page.
*
* On an internal (non-leaf) page, _bt_binsrch() returns the OffsetNumber
* of the last key < given scankey, or last key <= given scankey if nextkey
* is true. (Since _bt_compare treats the first data key of such a page as
* minus infinity, there will be at least one key < scankey, so the result
* always points at one of the keys on the page.)
*
* On a leaf page, _bt_binsrch() returns the final result of the initial
* positioning process that started with _bt_first's call to _bt_search.
* We're returning a non-pivot tuple offset, so things are a little different.
* It is possible that we'll return an offset that's either past the last
* non-pivot slot, or (in the case of a backward scan) before the first slot.
*
* This procedure is not responsible for walking right, it just examines
* the given page. _bt_binsrch() has no lock or refcount side effects
* on the buffer.
*/
static OffsetNumber
_bt_binsrch(Relation rel,
BTScanInsert key,
Buffer buf)
{
Page page;
BTPageOpaque opaque;
OffsetNumber low,
high;
int32 result,
cmpval;
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
/* Requesting nextkey semantics while using scantid seems nonsensical */
Assert(!key->nextkey || key->scantid == NULL);
/* scantid-set callers must use _bt_binsrch_insert() on leaf pages */
Assert(!P_ISLEAF(opaque) || key->scantid == NULL);
low = P_FIRSTDATAKEY(opaque);
high = PageGetMaxOffsetNumber(page);
/*
* If there are no keys on the page, return the first available slot. Note
* this covers two cases: the page is really empty (no keys), or it
* contains only a high key. The latter case is possible after vacuuming.
* This can never happen on an internal page, however, since they are
* never empty (an internal page must have at least one child).
*/
if (unlikely(high < low))
return low;
/*
* Binary search to find the first key on the page >= scan key, or first
* key > scankey when nextkey is true.
*
* For nextkey=false (cmpval=1), the loop invariant is: all slots before
* 'low' are < scan key, all slots at or after 'high' are >= scan key.
*
* For nextkey=true (cmpval=0), the loop invariant is: all slots before
* 'low' are <= scan key, all slots at or after 'high' are > scan key.
*
* We can fall out when high == low.
*/
high++; /* establish the loop invariant for high */
cmpval = key->nextkey ? 0 : 1; /* select comparison value */
while (high > low)
{
OffsetNumber mid = low + ((high - low) / 2);
/* We have low <= mid < high, so mid points at a real slot */
result = _bt_compare(rel, key, page, mid);
if (result >= cmpval)
low = mid + 1;
else
high = mid;
}
/*
* At this point we have high == low.
*
* On a leaf page we always return the first non-pivot tuple >= scan key
* (resp. > scan key) for forward scan callers. For backward scans, it's
* always the _last_ non-pivot tuple < scan key (resp. <= scan key).
*/
if (P_ISLEAF(opaque))
{
/*
* In the backward scan case we're supposed to locate the last
* matching tuple on the leaf level -- not the first matching tuple
* (the last tuple will be the first one returned by the scan).
*
* At this point we've located the first non-pivot tuple immediately
* after the last matching tuple (which might just be maxoff + 1).
* Compensate by stepping back.
*/
if (key->backward)
return OffsetNumberPrev(low);
return low;
}
/*
* On a non-leaf page, return the last key < scan key (resp. <= scan key).
* There must be one if _bt_compare() is playing by the rules.
*
* _bt_compare() will seldom see any exactly-matching pivot tuples, since
* a truncated -inf heap TID is usually enough to prevent it altogether.
* Even omitted scan key entries are treated as > truncated attributes.
*
* However, during backward scans _bt_compare() interprets omitted scan
* key attributes as == corresponding truncated -inf attributes instead.
* This works just like < would work here. Under this scheme, < strategy
* backward scans will always directly descend to the correct leaf page.
* In particular, they will never incur an "extra" leaf page access with a
* scan key that happens to contain the same prefix of values as some
* pivot tuple's untruncated prefix. VACUUM relies on this guarantee when
* it uses a leaf page high key to "re-find" a page undergoing deletion.
*/
Assert(low > P_FIRSTDATAKEY(opaque));
return OffsetNumberPrev(low);
}
/*
*
* _bt_binsrch_insert() -- Cacheable, incremental leaf page binary search.
*
* Like _bt_binsrch(), but with support for caching the binary search
* bounds. Only used during insertion, and only on the leaf page that it
* looks like caller will insert tuple on. Exclusive-locked and pinned
* leaf page is contained within insertstate.
*
* Caches the bounds fields in insertstate so that a subsequent call can
* reuse the low and strict high bounds of original binary search. Callers
* that use these fields directly must be prepared for the case where low
* and/or stricthigh are not on the same page (one or both exceed maxoff
* for the page). The case where there are no items on the page (high <
* low) makes bounds invalid.
*
* Caller is responsible for invalidating bounds when it modifies the page
* before calling here a second time, and for dealing with posting list
* tuple matches (callers can use insertstate's postingoff field to
* determine which existing heap TID will need to be replaced by a posting
* list split).
*/
OffsetNumber
_bt_binsrch_insert(Relation rel, BTInsertState insertstate)
{
BTScanInsert key = insertstate->itup_key;
Page page;
BTPageOpaque opaque;
OffsetNumber low,
high,
stricthigh;
int32 result,
cmpval;
page = BufferGetPage(insertstate->buf);
opaque = BTPageGetOpaque(page);
Assert(P_ISLEAF(opaque));
Assert(!key->nextkey);
Assert(insertstate->postingoff == 0);
if (!insertstate->bounds_valid)
{
/* Start new binary search */
low = P_FIRSTDATAKEY(opaque);
high = PageGetMaxOffsetNumber(page);
}
else
{
/* Restore result of previous binary search against same page */
low = insertstate->low;
high = insertstate->stricthigh;
}
/* If there are no keys on the page, return the first available slot */
if (unlikely(high < low))
{
/* Caller can't reuse bounds */
insertstate->low = InvalidOffsetNumber;
insertstate->stricthigh = InvalidOffsetNumber;
insertstate->bounds_valid = false;
return low;
}
/*
* Binary search to find the first key on the page >= scan key. (nextkey
* is always false when inserting).
*
* The loop invariant is: all slots before 'low' are < scan key, all slots
* at or after 'high' are >= scan key. 'stricthigh' is > scan key, and is
* maintained to save additional search effort for caller.
*
* We can fall out when high == low.
*/
if (!insertstate->bounds_valid)
high++; /* establish the loop invariant for high */
stricthigh = high; /* high initially strictly higher */
cmpval = 1; /* !nextkey comparison value */
while (high > low)
{
OffsetNumber mid = low + ((high - low) / 2);
/* We have low <= mid < high, so mid points at a real slot */
result = _bt_compare(rel, key, page, mid);
if (result >= cmpval)
low = mid + 1;
else
{
high = mid;
if (result != 0)
stricthigh = high;
}
/*
* If tuple at offset located by binary search is a posting list whose
* TID range overlaps with caller's scantid, perform posting list
* binary search to set postingoff for caller. Caller must split the
* posting list when postingoff is set. This should happen
* infrequently.
*/
if (unlikely(result == 0 && key->scantid != NULL))
{
/*
* postingoff should never be set more than once per leaf page
* binary search. That would mean that there are duplicate table
* TIDs in the index, which is never okay. Check for that here.
*/
if (insertstate->postingoff != 0)
ereport(ERROR,
(errcode(ERRCODE_INDEX_CORRUPTED),
errmsg_internal("table tid from new index tuple (%u,%u) cannot find insert offset between offsets %u and %u of block %u in index \"%s\"",
ItemPointerGetBlockNumber(key->scantid),
ItemPointerGetOffsetNumber(key->scantid),
low, stricthigh,
BufferGetBlockNumber(insertstate->buf),
RelationGetRelationName(rel))));
insertstate->postingoff = _bt_binsrch_posting(key, page, mid);
}
}
/*
* On a leaf page, a binary search always returns the first key >= scan
* key (at least in !nextkey case), which could be the last slot + 1. This
* is also the lower bound of cached search.
*
* stricthigh may also be the last slot + 1, which prevents caller from
* using bounds directly, but is still useful to us if we're called a
* second time with cached bounds (cached low will be < stricthigh when
* that happens).
*/
insertstate->low = low;
insertstate->stricthigh = stricthigh;
insertstate->bounds_valid = true;
return low;
}
/*----------
* _bt_binsrch_posting() -- posting list binary search.
*
* Helper routine for _bt_binsrch_insert().
*
* Returns offset into posting list where caller's scantid belongs.
*----------
*/
static int
_bt_binsrch_posting(BTScanInsert key, Page page, OffsetNumber offnum)
{
IndexTuple itup;
ItemId itemid;
int low,
high,
mid,
res;
/*
* If this isn't a posting tuple, then the index must be corrupt (if it is
* an ordinary non-pivot tuple then there must be an existing tuple with a
* heap TID that equals inserter's new heap TID/scantid). Defensively
* check that tuple is a posting list tuple whose posting list range
* includes caller's scantid.
*
* (This is also needed because contrib/amcheck's rootdescend option needs
* to be able to relocate a non-pivot tuple using _bt_binsrch_insert().)
*/
itemid = PageGetItemId(page, offnum);
itup = (IndexTuple) PageGetItem(page, itemid);
if (!BTreeTupleIsPosting(itup))
return 0;
Assert(key->heapkeyspace && key->allequalimage);
/*
* In the event that posting list tuple has LP_DEAD bit set, indicate this
* to _bt_binsrch_insert() caller by returning -1, a sentinel value. A
* second call to _bt_binsrch_insert() can take place when its caller has
* removed the dead item.
*/
if (ItemIdIsDead(itemid))
return -1;
/* "high" is past end of posting list for loop invariant */
low = 0;
high = BTreeTupleGetNPosting(itup);
Assert(high >= 2);
while (high > low)
{
mid = low + ((high - low) / 2);
res = ItemPointerCompare(key->scantid,
BTreeTupleGetPostingN(itup, mid));
if (res > 0)
low = mid + 1;
else if (res < 0)
high = mid;
else
return mid;
}
/* Exact match not found */
return low;
}
/*----------
* _bt_compare() -- Compare insertion-type scankey to tuple on a page.
*
* page/offnum: location of btree item to be compared to.
*
* This routine returns:
* <0 if scankey < tuple at offnum;
* 0 if scankey == tuple at offnum;
* >0 if scankey > tuple at offnum.
*
* NULLs in the keys are treated as sortable values. Therefore
* "equality" does not necessarily mean that the item should be returned
* to the caller as a matching key. Similarly, an insertion scankey
* with its scantid set is treated as equal to a posting tuple whose TID
* range overlaps with their scantid. There generally won't be a
* matching TID in the posting tuple, which caller must handle
* themselves (e.g., by splitting the posting list tuple).
*
* CRUCIAL NOTE: on a non-leaf page, the first data key is assumed to be
* "minus infinity": this routine will always claim it is less than the
* scankey. The actual key value stored is explicitly truncated to 0
* attributes (explicitly minus infinity) with version 3+ indexes, but
* that isn't relied upon. This allows us to implement the Lehman and
* Yao convention that the first down-link pointer is before the first
* key. See backend/access/nbtree/README for details.
*----------
*/
int32
_bt_compare(Relation rel,
BTScanInsert key,
Page page,
OffsetNumber offnum)
{
TupleDesc itupdesc = RelationGetDescr(rel);
BTPageOpaque opaque = BTPageGetOpaque(page);
IndexTuple itup;
ItemPointer heapTid;
ScanKey scankey;
int ncmpkey;
int ntupatts;
int32 result;
Assert(_bt_check_natts(rel, key->heapkeyspace, page, offnum));
Assert(key->keysz <= IndexRelationGetNumberOfKeyAttributes(rel));
Assert(key->heapkeyspace || key->scantid == NULL);
/*
* Force result ">" if target item is first data item on an internal page
* --- see NOTE above.
*/
if (!P_ISLEAF(opaque) && offnum == P_FIRSTDATAKEY(opaque))
return 1;
itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, offnum));
ntupatts = BTreeTupleGetNAtts(itup, rel);
/*
* The scan key is set up with the attribute number associated with each
* term in the key. It is important that, if the index is multi-key, the
* scan contain the first k key attributes, and that they be in order. If
* you think about how multi-key ordering works, you'll understand why
* this is.
*
* We don't test for violation of this condition here, however. The
* initial setup for the index scan had better have gotten it right (see
* _bt_first).
*/
ncmpkey = Min(ntupatts, key->keysz);
Assert(key->heapkeyspace || ncmpkey == key->keysz);
Assert(!BTreeTupleIsPosting(itup) || key->allequalimage);
scankey = key->scankeys;
for (int i = 1; i <= ncmpkey; i++)
{
Datum datum;
bool isNull;
datum = index_getattr(itup, scankey->sk_attno, itupdesc, &isNull);
if (scankey->sk_flags & SK_ISNULL) /* key is NULL */
{
if (isNull)
result = 0; /* NULL "=" NULL */
else if (scankey->sk_flags & SK_BT_NULLS_FIRST)
result = -1; /* NULL "<" NOT_NULL */
else
result = 1; /* NULL ">" NOT_NULL */
}
else if (isNull) /* key is NOT_NULL and item is NULL */
{
if (scankey->sk_flags & SK_BT_NULLS_FIRST)
result = 1; /* NOT_NULL ">" NULL */
else
result = -1; /* NOT_NULL "<" NULL */
}
else
{
/*
* The sk_func needs to be passed the index value as left arg and
* the sk_argument as right arg (they might be of different
* types). Since it is convenient for callers to think of
* _bt_compare as comparing the scankey to the index item, we have
* to flip the sign of the comparison result. (Unless it's a DESC
* column, in which case we *don't* flip the sign.)
*/
result = DatumGetInt32(FunctionCall2Coll(&scankey->sk_func,
scankey->sk_collation,
datum,
scankey->sk_argument));
if (!(scankey->sk_flags & SK_BT_DESC))
INVERT_COMPARE_RESULT(result);
}
/* if the keys are unequal, return the difference */
if (result != 0)
return result;
scankey++;
}
/*
* All non-truncated attributes (other than heap TID) were found to be
* equal. Treat truncated attributes as minus infinity when scankey has a
* key attribute value that would otherwise be compared directly.
*
* Note: it doesn't matter if ntupatts includes non-key attributes;
* scankey won't, so explicitly excluding non-key attributes isn't
* necessary.
*/
if (key->keysz > ntupatts)
return 1;
/*
* Use the heap TID attribute and scantid to try to break the tie. The
* rules are the same as any other key attribute -- only the
* representation differs.
*/
heapTid = BTreeTupleGetHeapTID(itup);
if (key->scantid == NULL)
{
/*
* Forward scans have a scankey that is considered greater than a
* truncated pivot tuple if and when the scankey has equal values for
* attributes up to and including the least significant untruncated
* attribute in tuple. Even attributes that were omitted from the
* scan key are considered greater than -inf truncated attributes.
* (See _bt_binsrch for an explanation of our backward scan behavior.)
*
* For example, if an index has the minimum two attributes (single
* user key attribute, plus heap TID attribute), and a page's high key
* is ('foo', -inf), and scankey is ('foo', <omitted>), the search
* will not descend to the page to the left. The search will descend
* right instead. The truncated attribute in pivot tuple means that
* all non-pivot tuples on the page to the left are strictly < 'foo',
* so it isn't necessary to descend left. In other words, search
* doesn't have to descend left because it isn't interested in a match
* that has a heap TID value of -inf.
*
* Note: the heap TID part of the test ensures that scankey is being
* compared to a pivot tuple with one or more truncated -inf key
* attributes. The heap TID attribute is the last key attribute in
* every index, of course, but other than that it isn't special.
*/
if (!key->backward && key->keysz == ntupatts && heapTid == NULL &&
key->heapkeyspace)
return 1;
/* All provided scankey arguments found to be equal */
return 0;
}
/*
* Treat truncated heap TID as minus infinity, since scankey has a key
* attribute value (scantid) that would otherwise be compared directly
*/
Assert(key->keysz == IndexRelationGetNumberOfKeyAttributes(rel));
if (heapTid == NULL)
return 1;
/*
* Scankey must be treated as equal to a posting list tuple if its scantid
* value falls within the range of the posting list. In all other cases
* there can only be a single heap TID value, which is compared directly
* with scantid.
*/
Assert(ntupatts >= IndexRelationGetNumberOfKeyAttributes(rel));
result = ItemPointerCompare(key->scantid, heapTid);
if (result <= 0 || !BTreeTupleIsPosting(itup))
return result;
else
{
result = ItemPointerCompare(key->scantid,
BTreeTupleGetMaxHeapTID(itup));
if (result > 0)
return 1;
}
return 0;
}
/*
* _bt_first() -- Find the first item in a scan.
*
* We need to be clever about the direction of scan, the search
* conditions, and the tree ordering. We find the first item (or,
* if backwards scan, the last item) in the tree that satisfies the
* qualifications in the scan key. On success exit, the page containing
* the current index tuple is pinned but not locked, and data about
* the matching tuple(s) on the page has been loaded into so->currPos.
* scan->xs_heaptid is set to the heap TID of the current tuple, and if
* requested, scan->xs_itup points to a copy of the index tuple.
*
* If there are no matching items in the index, we return false, with no
* pins or locks held.
*
* Note that scan->keyData[], and the so->keyData[] scankey built from it,
* are both search-type scankeys (see nbtree/README for more about this).
* Within this routine, we build a temporary insertion-type scankey to use
* in locating the scan start position.
*/
bool
_bt_first(IndexScanDesc scan, ScanDirection dir)
{
Relation rel = scan->indexRelation;
BTScanOpaque so = (BTScanOpaque) scan->opaque;
Buffer buf;
BTStack stack;
OffsetNumber offnum;
StrategyNumber strat;
BTScanInsertData inskey;
ScanKey startKeys[INDEX_MAX_KEYS];
ScanKeyData notnullkeys[INDEX_MAX_KEYS];
int keysz = 0;
int i;
bool status;
StrategyNumber strat_total;
BTScanPosItem *currItem;
BlockNumber blkno;
Assert(!BTScanPosIsValid(so->currPos));
pgstat_count_index_scan(rel);
/*
* Examine the scan keys and eliminate any redundant keys; also mark the
* keys that must be matched to continue the scan.
*/
_bt_preprocess_keys(scan);
/*
* Quit now if _bt_preprocess_keys() discovered that the scan keys can
* never be satisfied (eg, x == 1 AND x > 2).
*/
if (!so->qual_ok)
{
_bt_parallel_done(scan);
return false;
}
/*
* For parallel scans, get the starting page from shared state. If the
* scan has not started, proceed to find out first leaf page in the usual
* way while keeping other participating processes waiting. If the scan
* has already begun, use the page number from the shared structure.
*
* When a parallel scan has another primitive index scan scheduled, a
* parallel worker will seize the scan for that purpose now. This is
* similar to the case where the top-level scan hasn't started.
*/
if (scan->parallel_scan != NULL)
{
status = _bt_parallel_seize(scan, &blkno, true);
/*
* Initialize arrays (when _bt_parallel_seize didn't already set up
* the next primitive index scan)
*/
if (so->numArrayKeys && !so->needPrimScan)
_bt_start_array_keys(scan, dir);
if (!status)
return false;
else if (blkno == P_NONE)
{
_bt_parallel_done(scan);
return false;
}
else if (blkno != InvalidBlockNumber)
{
if (!_bt_parallel_readpage(scan, blkno, dir))
return false;
goto readcomplete;
}
}
else if (so->numArrayKeys && !so->needPrimScan)
{
/*
* First _bt_first call (for current btrescan) without parallelism.
*
* Initialize arrays, and the corresponding scan keys that were just
* output by _bt_preprocess_keys.
*/
_bt_start_array_keys(scan, dir);
}
/*----------
* Examine the scan keys to discover where we need to start the scan.
*
* We want to identify the keys that can be used as starting boundaries;
* these are =, >, or >= keys for a forward scan or =, <, <= keys for
* a backwards scan. We can use keys for multiple attributes so long as
* the prior attributes had only =, >= (resp. =, <=) keys. Once we accept
* a > or < boundary or find an attribute with no boundary (which can be
* thought of as the same as "> -infinity"), we can't use keys for any
* attributes to its right, because it would break our simplistic notion
* of what initial positioning strategy to use.
*
* When the scan keys include cross-type operators, _bt_preprocess_keys
* may not be able to eliminate redundant keys; in such cases we will
* arbitrarily pick a usable one for each attribute. This is correct
* but possibly not optimal behavior. (For example, with keys like
* "x >= 4 AND x >= 5" we would elect to scan starting at x=4 when
* x=5 would be more efficient.) Since the situation only arises given
* a poorly-worded query plus an incomplete opfamily, live with it.
*
* When both equality and inequality keys appear for a single attribute
* (again, only possible when cross-type operators appear), we *must*
* select one of the equality keys for the starting point, because
* _bt_checkkeys() will stop the scan as soon as an equality qual fails.
* For example, if we have keys like "x >= 4 AND x = 10" and we elect to
* start at x=4, we will fail and stop before reaching x=10. If multiple
* equality quals survive preprocessing, however, it doesn't matter which
* one we use --- by definition, they are either redundant or
* contradictory.
*
* Any regular (not SK_SEARCHNULL) key implies a NOT NULL qualifier.
* If the index stores nulls at the end of the index we'll be starting
* from, and we have no boundary key for the column (which means the key
* we deduced NOT NULL from is an inequality key that constrains the other
* end of the index), then we cons up an explicit SK_SEARCHNOTNULL key to
* use as a boundary key. If we didn't do this, we might find ourselves
* traversing a lot of null entries at the start of the scan.
*
* In this loop, row-comparison keys are treated the same as keys on their
* first (leftmost) columns. We'll add on lower-order columns of the row
* comparison below, if possible.
*
* The selected scan keys (at most one per index column) are remembered by
* storing their addresses into the local startKeys[] array.
*
* _bt_checkkeys/_bt_advance_array_keys decide whether and when to start
* the next primitive index scan (for scans with array keys) based in part
* on an understanding of how it'll enable us to reposition the scan.
* They're directly aware of how we'll sometimes cons up an explicit
* SK_SEARCHNOTNULL key. They'll even end primitive scans by applying a
* symmetric "deduce NOT NULL" rule of their own. This allows top-level
* scans to skip large groups of NULLs through repeated deductions about
* key strictness (for a required inequality key) and whether NULLs in the
* key's index column are stored last or first (relative to non-NULLs).
* If you update anything here, _bt_checkkeys/_bt_advance_array_keys might
* need to be kept in sync.
*----------
*/
strat_total = BTEqualStrategyNumber;
if (so->numberOfKeys > 0)
{
AttrNumber curattr;
ScanKey chosen;
ScanKey impliesNN;
ScanKey cur;
/*
* chosen is the so-far-chosen key for the current attribute, if any.
* We don't cast the decision in stone until we reach keys for the
* next attribute.
*/
curattr = 1;
chosen = NULL;
/* Also remember any scankey that implies a NOT NULL constraint */
impliesNN = NULL;
/*
* Loop iterates from 0 to numberOfKeys inclusive; we use the last
* pass to handle after-last-key processing. Actual exit from the
* loop is at one of the "break" statements below.
*/
for (cur = so->keyData, i = 0;; cur++, i++)
{
if (i >= so->numberOfKeys || cur->sk_attno != curattr)
{
/*
* Done looking at keys for curattr. If we didn't find a
* usable boundary key, see if we can deduce a NOT NULL key.
*/
if (chosen == NULL && impliesNN != NULL &&
((impliesNN->sk_flags & SK_BT_NULLS_FIRST) ?
ScanDirectionIsForward(dir) :
ScanDirectionIsBackward(dir)))
{
/* Yes, so build the key in notnullkeys[keysz] */
chosen = &notnullkeys[keysz];
ScanKeyEntryInitialize(chosen,
(SK_SEARCHNOTNULL | SK_ISNULL |
(impliesNN->sk_flags &
(SK_BT_DESC | SK_BT_NULLS_FIRST))),
curattr,
((impliesNN->sk_flags & SK_BT_NULLS_FIRST) ?
BTGreaterStrategyNumber :
BTLessStrategyNumber),
InvalidOid,
InvalidOid,
InvalidOid,
(Datum) 0);
}
/*
* If we still didn't find a usable boundary key, quit; else
* save the boundary key pointer in startKeys.
*/
if (chosen == NULL)
break;
startKeys[keysz++] = chosen;
/*
* Adjust strat_total, and quit if we have stored a > or <
* key.
*/
strat = chosen->sk_strategy;
if (strat != BTEqualStrategyNumber)
{
strat_total = strat;
if (strat == BTGreaterStrategyNumber ||
strat == BTLessStrategyNumber)
break;
}
/*
* Done if that was the last attribute, or if next key is not
* in sequence (implying no boundary key is available for the
* next attribute).
*/
if (i >= so->numberOfKeys ||
cur->sk_attno != curattr + 1)
break;
/*
* Reset for next attr.
*/
curattr = cur->sk_attno;
chosen = NULL;
impliesNN = NULL;
}
/*
* Can we use this key as a starting boundary for this attr?
*
* If not, does it imply a NOT NULL constraint? (Because
* SK_SEARCHNULL keys are always assigned BTEqualStrategyNumber,
* *any* inequality key works for that; we need not test.)
*/
switch (cur->sk_strategy)
{
case BTLessStrategyNumber:
case BTLessEqualStrategyNumber:
if (chosen == NULL)
{
if (ScanDirectionIsBackward(dir))
chosen = cur;
else
impliesNN = cur;
}
break;
case BTEqualStrategyNumber:
/* override any non-equality choice */
chosen = cur;
break;
case BTGreaterEqualStrategyNumber:
case BTGreaterStrategyNumber:
if (chosen == NULL)
{
if (ScanDirectionIsForward(dir))
chosen = cur;
else
impliesNN = cur;
}
break;
}
}
}
/*
* If we found no usable boundary keys, we have to start from one end of
* the tree. Walk down that edge to the first or last key, and scan from
* there.
*/
if (keysz == 0)
{
bool match;
match = _bt_endpoint(scan, dir);
if (!match)
{
/* No match, so mark (parallel) scan finished */
_bt_parallel_done(scan);
}
return match;
}
/*
* We want to start the scan somewhere within the index. Set up an
* insertion scankey we can use to search for the boundary point we
* identified above. The insertion scankey is built using the keys
* identified by startKeys[]. (Remaining insertion scankey fields are
* initialized after initial-positioning strategy is finalized.)
*/
Assert(keysz <= INDEX_MAX_KEYS);
for (i = 0; i < keysz; i++)
{
ScanKey cur = startKeys[i];
Assert(cur->sk_attno == i + 1);
if (cur->sk_flags & SK_ROW_HEADER)
{
/*
* Row comparison header: look to the first row member instead.
*
* The member scankeys are already in insertion format (ie, they
* have sk_func = 3-way-comparison function), but we have to watch
* out for nulls, which _bt_preprocess_keys didn't check. A null
* in the first row member makes the condition unmatchable, just
* like qual_ok = false.
*/
ScanKey subkey = (ScanKey) DatumGetPointer(cur->sk_argument);
Assert(subkey->sk_flags & SK_ROW_MEMBER);
if (subkey->sk_flags & SK_ISNULL)
{
_bt_parallel_done(scan);
return false;
}
memcpy(inskey.scankeys + i, subkey, sizeof(ScanKeyData));
/*
* If the row comparison is the last positioning key we accepted,
* try to add additional keys from the lower-order row members.
* (If we accepted independent conditions on additional index
* columns, we use those instead --- doesn't seem worth trying to
* determine which is more restrictive.) Note that this is OK
* even if the row comparison is of ">" or "<" type, because the
* condition applied to all but the last row member is effectively
* ">=" or "<=", and so the extra keys don't break the positioning
* scheme. But, by the same token, if we aren't able to use all
* the row members, then the part of the row comparison that we
* did use has to be treated as just a ">=" or "<=" condition, and
* so we'd better adjust strat_total accordingly.
*/
if (i == keysz - 1)
{
bool used_all_subkeys = false;
Assert(!(subkey->sk_flags & SK_ROW_END));
for (;;)
{
subkey++;
Assert(subkey->sk_flags & SK_ROW_MEMBER);
if (subkey->sk_attno != keysz + 1)
break; /* out-of-sequence, can't use it */
if (subkey->sk_strategy != cur->sk_strategy)
break; /* wrong direction, can't use it */
if (subkey->sk_flags & SK_ISNULL)
break; /* can't use null keys */
Assert(keysz < INDEX_MAX_KEYS);
memcpy(inskey.scankeys + keysz, subkey,
sizeof(ScanKeyData));
keysz++;
if (subkey->sk_flags & SK_ROW_END)
{
used_all_subkeys = true;
break;
}
}
if (!used_all_subkeys)
{
switch (strat_total)
{
case BTLessStrategyNumber:
strat_total = BTLessEqualStrategyNumber;
break;
case BTGreaterStrategyNumber:
strat_total = BTGreaterEqualStrategyNumber;
break;
}
}
break; /* done with outer loop */
}
}
else
{
/*
* Ordinary comparison key. Transform the search-style scan key
* to an insertion scan key by replacing the sk_func with the
* appropriate btree comparison function.
*
* If scankey operator is not a cross-type comparison, we can use
* the cached comparison function; otherwise gotta look it up in
* the catalogs. (That can't lead to infinite recursion, since no
* indexscan initiated by syscache lookup will use cross-data-type
* operators.)
*
* We support the convention that sk_subtype == InvalidOid means
* the opclass input type; this is a hack to simplify life for
* ScanKeyInit().
*/
if (cur->sk_subtype == rel->rd_opcintype[i] ||
cur->sk_subtype == InvalidOid)
{
FmgrInfo *procinfo;
procinfo = index_getprocinfo(rel, cur->sk_attno, BTORDER_PROC);
ScanKeyEntryInitializeWithInfo(inskey.scankeys + i,
cur->sk_flags,
cur->sk_attno,
InvalidStrategy,
cur->sk_subtype,
cur->sk_collation,
procinfo,
cur->sk_argument);
}
else
{
RegProcedure cmp_proc;
cmp_proc = get_opfamily_proc(rel->rd_opfamily[i],
rel->rd_opcintype[i],
cur->sk_subtype,
BTORDER_PROC);
if (!RegProcedureIsValid(cmp_proc))
elog(ERROR, "missing support function %d(%u,%u) for attribute %d of index \"%s\"",
BTORDER_PROC, rel->rd_opcintype[i], cur->sk_subtype,
cur->sk_attno, RelationGetRelationName(rel));
ScanKeyEntryInitialize(inskey.scankeys + i,
cur->sk_flags,
cur->sk_attno,
InvalidStrategy,
cur->sk_subtype,
cur->sk_collation,
cmp_proc,
cur->sk_argument);
}
}
}
/*----------
* Examine the selected initial-positioning strategy to determine exactly
* where we need to start the scan, and set flag variables to control the
* initial descent by _bt_search (and our _bt_binsrch call for the leaf
* page _bt_search returns).
*----------
*/
_bt_metaversion(rel, &inskey.heapkeyspace, &inskey.allequalimage);
inskey.anynullkeys = false; /* unused */
inskey.scantid = NULL;
inskey.keysz = keysz;
switch (strat_total)
{
case BTLessStrategyNumber:
inskey.nextkey = false;
inskey.backward = true;
break;
case BTLessEqualStrategyNumber:
inskey.nextkey = true;
inskey.backward = true;
break;
case BTEqualStrategyNumber:
/*
* If a backward scan was specified, need to start with last equal
* item not first one.
*/
if (ScanDirectionIsBackward(dir))
{
/*
* This is the same as the <= strategy
*/
inskey.nextkey = true;
inskey.backward = true;
}
else
{
/*
* This is the same as the >= strategy
*/
inskey.nextkey = false;
inskey.backward = false;
}
break;
case BTGreaterEqualStrategyNumber:
/*
* Find first item >= scankey
*/
inskey.nextkey = false;
inskey.backward = false;
break;
case BTGreaterStrategyNumber:
/*
* Find first item > scankey
*/
inskey.nextkey = true;
inskey.backward = false;
break;
default:
/* can't get here, but keep compiler quiet */
elog(ERROR, "unrecognized strat_total: %d", (int) strat_total);
return false;
}
/*
* Use the manufactured insertion scan key to descend the tree and
* position ourselves on the target leaf page.
*/
Assert(ScanDirectionIsBackward(dir) == inskey.backward);
stack = _bt_search(rel, NULL, &inskey, &buf, BT_READ);
/* don't need to keep the stack around... */
_bt_freestack(stack);
if (!BufferIsValid(buf))
{
/*
* We only get here if the index is completely empty. Lock relation
* because nothing finer to lock exists. Without a buffer lock, it's
* possible for another transaction to insert data between
* _bt_search() and PredicateLockRelation(). We have to try again
* after taking the relation-level predicate lock, to close a narrow
* window where we wouldn't scan concurrently inserted tuples, but the
* writer wouldn't see our predicate lock.
*/
if (IsolationIsSerializable())
{
PredicateLockRelation(rel, scan->xs_snapshot);
stack = _bt_search(rel, NULL, &inskey, &buf, BT_READ);
_bt_freestack(stack);
}
if (!BufferIsValid(buf))
{
/*
* Mark parallel scan as done, so that all the workers can finish
* their scan.
*/
_bt_parallel_done(scan);
BTScanPosInvalidate(so->currPos);
return false;
}
}
PredicateLockPage(rel, BufferGetBlockNumber(buf), scan->xs_snapshot);
_bt_initialize_more_data(so, dir);
/* position to the precise item on the page */
offnum = _bt_binsrch(rel, &inskey, buf);
Assert(!BTScanPosIsValid(so->currPos));
so->currPos.buf = buf;
/*
* Now load data from the first page of the scan.
*
* If inskey.nextkey = false and inskey.backward = false, offnum is
* positioned at the first non-pivot tuple >= inskey.scankeys.
*
* If inskey.nextkey = false and inskey.backward = true, offnum is
* positioned at the last non-pivot tuple < inskey.scankeys.
*
* If inskey.nextkey = true and inskey.backward = false, offnum is
* positioned at the first non-pivot tuple > inskey.scankeys.
*
* If inskey.nextkey = true and inskey.backward = true, offnum is
* positioned at the last non-pivot tuple <= inskey.scankeys.
*
* It's possible that _bt_binsrch returned an offnum that is out of bounds
* for the page. For example, when inskey is both < the leaf page's high
* key and > all of its non-pivot tuples, offnum will be "maxoff + 1".
*/
if (!_bt_readpage(scan, dir, offnum, true))
{
/*
* There's no actually-matching data on this page. Try to advance to
* the next page. Return false if there's no matching data at all.
*/
_bt_unlockbuf(scan->indexRelation, so->currPos.buf);
if (!_bt_steppage(scan, dir))
return false;
}
else
{
/* We have at least one item to return as scan's first item */
_bt_drop_lock_and_maybe_pin(scan, &so->currPos);
}
readcomplete:
/* OK, itemIndex says what to return */
currItem = &so->currPos.items[so->currPos.itemIndex];
scan->xs_heaptid = currItem->heapTid;
if (scan->xs_want_itup)
scan->xs_itup = (IndexTuple) (so->currTuples + currItem->tupleOffset);
return true;
}
/*
* _bt_next() -- Get the next item in a scan.
*
* On entry, so->currPos describes the current page, which may be pinned
* but is not locked, and so->currPos.itemIndex identifies which item was
* previously returned.
*
* On successful exit, scan->xs_heaptid is set to the TID of the next
* heap tuple, and if requested, scan->xs_itup points to a copy of the
* index tuple. so->currPos is updated as needed.
*
* On failure exit (no more tuples), we release pin and set
* so->currPos.buf to InvalidBuffer.
*/
bool
_bt_next(IndexScanDesc scan, ScanDirection dir)
{
BTScanOpaque so = (BTScanOpaque) scan->opaque;
BTScanPosItem *currItem;
/*
* Advance to next tuple on current page; or if there's no more, try to
* step to the next page with data.
*/
if (ScanDirectionIsForward(dir))
{
if (++so->currPos.itemIndex > so->currPos.lastItem)
{
if (!_bt_steppage(scan, dir))
return false;
}
}
else
{
if (--so->currPos.itemIndex < so->currPos.firstItem)
{
if (!_bt_steppage(scan, dir))
return false;
}
}
/* OK, itemIndex says what to return */
currItem = &so->currPos.items[so->currPos.itemIndex];
scan->xs_heaptid = currItem->heapTid;
if (scan->xs_want_itup)
scan->xs_itup = (IndexTuple) (so->currTuples + currItem->tupleOffset);
return true;
}
/*
* _bt_readpage() -- Load data from current index page into so->currPos
*
* Caller must have pinned and read-locked so->currPos.buf; the buffer's state
* is not changed here. Also, currPos.moreLeft and moreRight must be valid;
* they are updated as appropriate. All other fields of so->currPos are
* initialized from scratch here.
*
* We scan the current page starting at offnum and moving in the indicated
* direction. All items matching the scan keys are loaded into currPos.items.
* moreLeft or moreRight (as appropriate) is cleared if _bt_checkkeys reports
* that there can be no more matching tuples in the current scan direction
* (could just be for the current primitive index scan when scan has arrays).
*
* _bt_first caller passes us an offnum returned by _bt_binsrch, which might
* be an out of bounds offnum such as "maxoff + 1" in certain corner cases.
* _bt_checkkeys will stop the scan as soon as an equality qual fails (when
* its scan key was marked required), so _bt_first _must_ pass us an offnum
* exactly at the beginning of where equal tuples are to be found. When we're
* passed an offnum past the end of the page, we might still manage to stop
* the scan on this page by calling _bt_checkkeys against the high key.
*
* In the case of a parallel scan, caller must have called _bt_parallel_seize
* prior to calling this function; this function will invoke
* _bt_parallel_release before returning.
*
* Returns true if any matching items found on the page, false if none.
*/
static bool
_bt_readpage(IndexScanDesc scan, ScanDirection dir, OffsetNumber offnum,
bool firstPage)
{
BTScanOpaque so = (BTScanOpaque) scan->opaque;
Page page;
BTPageOpaque opaque;
OffsetNumber minoff;
OffsetNumber maxoff;
BTReadPageState pstate;
bool arrayKeys;
int itemIndex,
indnatts;
/*
* We must have the buffer pinned and locked, but the usual macro can't be
* used here; this function is what makes it good for currPos.
*/
Assert(BufferIsValid(so->currPos.buf));
page = BufferGetPage(so->currPos.buf);
opaque = BTPageGetOpaque(page);
/* allow next page be processed by parallel worker */
if (scan->parallel_scan)
{
if (ScanDirectionIsForward(dir))
pstate.prev_scan_page = opaque->btpo_next;
else
pstate.prev_scan_page = BufferGetBlockNumber(so->currPos.buf);
_bt_parallel_release(scan, pstate.prev_scan_page);
}
indnatts = IndexRelationGetNumberOfAttributes(scan->indexRelation);
arrayKeys = so->numArrayKeys != 0;
minoff = P_FIRSTDATAKEY(opaque);
maxoff = PageGetMaxOffsetNumber(page);
/* initialize page-level state that we'll pass to _bt_checkkeys */
pstate.dir = dir;
pstate.minoff = minoff;
pstate.maxoff = maxoff;
pstate.finaltup = NULL;
pstate.page = page;
pstate.offnum = InvalidOffsetNumber;
pstate.skip = InvalidOffsetNumber;
pstate.continuescan = true; /* default assumption */
pstate.prechecked = false;
pstate.firstmatch = false;
pstate.rechecks = 0;
pstate.targetdistance = 0;
/*
* We note the buffer's block number so that we can release the pin later.
* This allows us to re-read the buffer if it is needed again for hinting.
*/
so->currPos.currPage = BufferGetBlockNumber(so->currPos.buf);
/*
* We save the LSN of the page as we read it, so that we know whether it
* safe to apply LP_DEAD hints to the page later. This allows us to drop
* the pin for MVCC scans, which allows vacuum to avoid blocking.
*/
so->currPos.lsn = BufferGetLSNAtomic(so->currPos.buf);
/*
* we must save the page's right-link while scanning it; this tells us
* where to step right to after we're done with these items. There is no
* corresponding need for the left-link, since splits always go right.
*/
so->currPos.nextPage = opaque->btpo_next;
/* initialize tuple workspace to empty */
so->currPos.nextTupleOffset = 0;
/*
* Now that the current page has been made consistent, the macro should be
* good.
*/
Assert(BTScanPosIsPinned(so->currPos));
/*
* Prechecking the value of the continuescan flag for the last item on the
* page (for backwards scan it will be the first item on a page). If we
* observe it to be true, then it should be true for all other items. This
* allows us to do significant optimizations in the _bt_checkkeys()
* function for all the items on the page.
*
* With the forward scan, we do this check for the last item on the page
* instead of the high key. It's relatively likely that the most
* significant column in the high key will be different from the
* corresponding value from the last item on the page. So checking with
* the last item on the page would give a more precise answer.
*
* We skip this for the first page read by each (primitive) scan, to avoid
* slowing down point queries. They typically don't stand to gain much
* when the optimization can be applied, and are more likely to notice the
* overhead of the precheck.
*
* The optimization is unsafe and must be avoided whenever _bt_checkkeys
* just set a low-order required array's key to the best available match
* for a truncated -inf attribute value from the prior page's high key
* (array element 0 is always the best available match in this scenario).
* It's quite likely that matches for array element 0 begin on this page,
* but the start of matches won't necessarily align with page boundaries.
* When the start of matches is somewhere in the middle of this page, it
* would be wrong to treat page's final non-pivot tuple as representative.
* Doing so might lead us to treat some of the page's earlier tuples as
* being part of a group of tuples thought to satisfy the required keys.
*
* Note: Conversely, in the case where the scan's arrays just advanced
* using the prior page's HIKEY _without_ advancement setting scanBehind,
* the start of matches must be aligned with page boundaries, which makes
* it safe to attempt the optimization here now. It's also safe when the
* prior page's HIKEY simply didn't need to advance any required array. In
* both cases we can safely assume that the _first_ tuple from this page
* must be >= the current set of array keys/equality constraints. And so
* if the final tuple is == those same keys (and also satisfies any
* required < or <= strategy scan keys) during the precheck, we can safely
* assume that this must also be true of all earlier tuples from the page.
*/
if (!firstPage && !so->scanBehind && minoff < maxoff)
{
ItemId iid;
IndexTuple itup;
iid = PageGetItemId(page, ScanDirectionIsForward(dir) ? maxoff : minoff);
itup = (IndexTuple) PageGetItem(page, iid);
/* Call with arrayKeys=false to avoid undesirable side-effects */
_bt_checkkeys(scan, &pstate, false, itup, indnatts);
pstate.prechecked = pstate.continuescan;
pstate.continuescan = true; /* reset */
}
if (ScanDirectionIsForward(dir))
{
/* SK_SEARCHARRAY forward scans must provide high key up front */
if (arrayKeys && !P_RIGHTMOST(opaque))
{
ItemId iid = PageGetItemId(page, P_HIKEY);
pstate.finaltup = (IndexTuple) PageGetItem(page, iid);
}
/* load items[] in ascending order */
itemIndex = 0;
offnum = Max(offnum, minoff);
while (offnum <= maxoff)
{
ItemId iid = PageGetItemId(page, offnum);
IndexTuple itup;
bool passes_quals;
/*
* If the scan specifies not to return killed tuples, then we
* treat a killed tuple as not passing the qual
*/
if (scan->ignore_killed_tuples && ItemIdIsDead(iid))
{
offnum = OffsetNumberNext(offnum);
continue;
}
itup = (IndexTuple) PageGetItem(page, iid);
Assert(!BTreeTupleIsPivot(itup));
pstate.offnum = offnum;
passes_quals = _bt_checkkeys(scan, &pstate, arrayKeys,
itup, indnatts);
/*
* Check if we need to skip ahead to a later tuple (only possible
* when the scan uses array keys)
*/
if (arrayKeys && OffsetNumberIsValid(pstate.skip))
{
Assert(!passes_quals && pstate.continuescan);
Assert(offnum < pstate.skip);
offnum = pstate.skip;
pstate.skip = InvalidOffsetNumber;
continue;
}
if (passes_quals)
{
/* tuple passes all scan key conditions */
pstate.firstmatch = true;
if (!BTreeTupleIsPosting(itup))
{
/* Remember it */
_bt_saveitem(so, itemIndex, offnum, itup);
itemIndex++;
}
else
{
int tupleOffset;
/*
* Set up state to return posting list, and remember first
* TID
*/
tupleOffset =
_bt_setuppostingitems(so, itemIndex, offnum,
BTreeTupleGetPostingN(itup, 0),
itup);
itemIndex++;
/* Remember additional TIDs */
for (int i = 1; i < BTreeTupleGetNPosting(itup); i++)
{
_bt_savepostingitem(so, itemIndex, offnum,
BTreeTupleGetPostingN(itup, i),
tupleOffset);
itemIndex++;
}
}
}
/* When !continuescan, there can't be any more matches, so stop */
if (!pstate.continuescan)
break;
offnum = OffsetNumberNext(offnum);
}
/*
* We don't need to visit page to the right when the high key
* indicates that no more matches will be found there.
*
* Checking the high key like this works out more often than you might
* think. Leaf page splits pick a split point between the two most
* dissimilar tuples (this is weighed against the need to evenly share
* free space). Leaf pages with high key attribute values that can
* only appear on non-pivot tuples on the right sibling page are
* common.
*/
if (pstate.continuescan && !P_RIGHTMOST(opaque))
{
ItemId iid = PageGetItemId(page, P_HIKEY);
IndexTuple itup = (IndexTuple) PageGetItem(page, iid);
int truncatt;
truncatt = BTreeTupleGetNAtts(itup, scan->indexRelation);
pstate.prechecked = false; /* precheck didn't cover HIKEY */
_bt_checkkeys(scan, &pstate, arrayKeys, itup, truncatt);
}
if (!pstate.continuescan)
so->currPos.moreRight = false;
Assert(itemIndex <= MaxTIDsPerBTreePage);
so->currPos.firstItem = 0;
so->currPos.lastItem = itemIndex - 1;
so->currPos.itemIndex = 0;
}
else
{
/* SK_SEARCHARRAY backward scans must provide final tuple up front */
if (arrayKeys && minoff <= maxoff && !P_LEFTMOST(opaque))
{
ItemId iid = PageGetItemId(page, minoff);
pstate.finaltup = (IndexTuple) PageGetItem(page, iid);
}
/* load items[] in descending order */
itemIndex = MaxTIDsPerBTreePage;
offnum = Min(offnum, maxoff);
while (offnum >= minoff)
{
ItemId iid = PageGetItemId(page, offnum);
IndexTuple itup;
bool tuple_alive;
bool passes_quals;
/*
* If the scan specifies not to return killed tuples, then we
* treat a killed tuple as not passing the qual. Most of the
* time, it's a win to not bother examining the tuple's index
* keys, but just skip to the next tuple (previous, actually,
* since we're scanning backwards). However, if this is the first
* tuple on the page, we do check the index keys, to prevent
* uselessly advancing to the page to the left. This is similar
* to the high key optimization used by forward scans.
*/
if (scan->ignore_killed_tuples && ItemIdIsDead(iid))
{
Assert(offnum >= P_FIRSTDATAKEY(opaque));
if (offnum > P_FIRSTDATAKEY(opaque))
{
offnum = OffsetNumberPrev(offnum);
continue;
}
tuple_alive = false;
}
else
tuple_alive = true;
itup = (IndexTuple) PageGetItem(page, iid);
Assert(!BTreeTupleIsPivot(itup));
pstate.offnum = offnum;
passes_quals = _bt_checkkeys(scan, &pstate, arrayKeys,
itup, indnatts);
/*
* Check if we need to skip ahead to a later tuple (only possible
* when the scan uses array keys)
*/
if (arrayKeys && OffsetNumberIsValid(pstate.skip))
{
Assert(!passes_quals && pstate.continuescan);
Assert(offnum > pstate.skip);
offnum = pstate.skip;
pstate.skip = InvalidOffsetNumber;
continue;
}
if (passes_quals && tuple_alive)
{
/* tuple passes all scan key conditions */
pstate.firstmatch = true;
if (!BTreeTupleIsPosting(itup))
{
/* Remember it */
itemIndex--;
_bt_saveitem(so, itemIndex, offnum, itup);
}
else
{
int tupleOffset;
/*
* Set up state to return posting list, and remember first
* TID.
*
* Note that we deliberately save/return items from
* posting lists in ascending heap TID order for backwards
* scans. This allows _bt_killitems() to make a
* consistent assumption about the order of items
* associated with the same posting list tuple.
*/
itemIndex--;
tupleOffset =
_bt_setuppostingitems(so, itemIndex, offnum,
BTreeTupleGetPostingN(itup, 0),
itup);
/* Remember additional TIDs */
for (int i = 1; i < BTreeTupleGetNPosting(itup); i++)
{
itemIndex--;
_bt_savepostingitem(so, itemIndex, offnum,
BTreeTupleGetPostingN(itup, i),
tupleOffset);
}
}
}
/* When !continuescan, there can't be any more matches, so stop */
if (!pstate.continuescan)
break;
offnum = OffsetNumberPrev(offnum);
}
/*
* We don't need to visit page to the left when no more matches will
* be found there
*/
if (!pstate.continuescan || P_LEFTMOST(opaque))
so->currPos.moreLeft = false;
Assert(itemIndex >= 0);
so->currPos.firstItem = itemIndex;
so->currPos.lastItem = MaxTIDsPerBTreePage - 1;
so->currPos.itemIndex = MaxTIDsPerBTreePage - 1;
}
return (so->currPos.firstItem <= so->currPos.lastItem);
}
/* Save an index item into so->currPos.items[itemIndex] */
static void
_bt_saveitem(BTScanOpaque so, int itemIndex,
OffsetNumber offnum, IndexTuple itup)
{
BTScanPosItem *currItem = &so->currPos.items[itemIndex];
Assert(!BTreeTupleIsPivot(itup) && !BTreeTupleIsPosting(itup));
currItem->heapTid = itup->t_tid;
currItem->indexOffset = offnum;
if (so->currTuples)
{
Size itupsz = IndexTupleSize(itup);
currItem->tupleOffset = so->currPos.nextTupleOffset;
memcpy(so->currTuples + so->currPos.nextTupleOffset, itup, itupsz);
so->currPos.nextTupleOffset += MAXALIGN(itupsz);
}
}
/*
* Setup state to save TIDs/items from a single posting list tuple.
*
* Saves an index item into so->currPos.items[itemIndex] for TID that is
* returned to scan first. Second or subsequent TIDs for posting list should
* be saved by calling _bt_savepostingitem().
*
* Returns an offset into tuple storage space that main tuple is stored at if
* needed.
*/
static int
_bt_setuppostingitems(BTScanOpaque so, int itemIndex, OffsetNumber offnum,
ItemPointer heapTid, IndexTuple itup)
{
BTScanPosItem *currItem = &so->currPos.items[itemIndex];
Assert(BTreeTupleIsPosting(itup));
currItem->heapTid = *heapTid;
currItem->indexOffset = offnum;
if (so->currTuples)
{
/* Save base IndexTuple (truncate posting list) */
IndexTuple base;
Size itupsz = BTreeTupleGetPostingOffset(itup);
itupsz = MAXALIGN(itupsz);
currItem->tupleOffset = so->currPos.nextTupleOffset;
base = (IndexTuple) (so->currTuples + so->currPos.nextTupleOffset);
memcpy(base, itup, itupsz);
/* Defensively reduce work area index tuple header size */
base->t_info &= ~INDEX_SIZE_MASK;
base->t_info |= itupsz;
so->currPos.nextTupleOffset += itupsz;
return currItem->tupleOffset;
}
return 0;
}
/*
* Save an index item into so->currPos.items[itemIndex] for current posting
* tuple.
*
* Assumes that _bt_setuppostingitems() has already been called for current
* posting list tuple. Caller passes its return value as tupleOffset.
*/
static inline void
_bt_savepostingitem(BTScanOpaque so, int itemIndex, OffsetNumber offnum,
ItemPointer heapTid, int tupleOffset)
{
BTScanPosItem *currItem = &so->currPos.items[itemIndex];
currItem->heapTid = *heapTid;
currItem->indexOffset = offnum;
/*
* Have index-only scans return the same base IndexTuple for every TID
* that originates from the same posting list
*/
if (so->currTuples)
currItem->tupleOffset = tupleOffset;
}
/*
* _bt_steppage() -- Step to next page containing valid data for scan
*
* On entry, if so->currPos.buf is valid the buffer is pinned but not locked;
* if pinned, we'll drop the pin before moving to next page. The buffer is
* not locked on entry.
*
* For success on a scan using a non-MVCC snapshot we hold a pin, but not a
* read lock, on that page. If we do not hold the pin, we set so->currPos.buf
* to InvalidBuffer. We return true to indicate success.
*/
static bool
_bt_steppage(IndexScanDesc scan, ScanDirection dir)
{
BTScanOpaque so = (BTScanOpaque) scan->opaque;
BlockNumber blkno = InvalidBlockNumber;
bool status;
Assert(BTScanPosIsValid(so->currPos));
/* Before leaving current page, deal with any killed items */
if (so->numKilled > 0)
_bt_killitems(scan);
/*
* Before we modify currPos, make a copy of the page data if there was a
* mark position that needs it.
*/
if (so->markItemIndex >= 0)
{
/* bump pin on current buffer for assignment to mark buffer */
if (BTScanPosIsPinned(so->currPos))
IncrBufferRefCount(so->currPos.buf);
memcpy(&so->markPos, &so->currPos,
offsetof(BTScanPosData, items[1]) +
so->currPos.lastItem * sizeof(BTScanPosItem));
if (so->markTuples)
memcpy(so->markTuples, so->currTuples,
so->currPos.nextTupleOffset);
so->markPos.itemIndex = so->markItemIndex;
so->markItemIndex = -1;
/*
* If we're just about to start the next primitive index scan
* (possible with a scan that has arrays keys, and needs to skip to
* continue in the current scan direction), moreLeft/moreRight only
* indicate the end of the current primitive index scan. They must
* never be taken to indicate that the top-level index scan has ended
* (that would be wrong).
*
* We could handle this case by treating the current array keys as
* markPos state. But depending on the current array state like this
* would add complexity. Instead, we just unset markPos's copy of
* moreRight or moreLeft (whichever might be affected), while making
* btrestpos reset the scan's arrays to their initial scan positions.
* In effect, btrestpos leaves advancing the arrays up to the first
* _bt_readpage call (that takes place after it has restored markPos).
*/
Assert(so->markPos.dir == dir);
if (so->needPrimScan)
{
if (ScanDirectionIsForward(dir))
so->markPos.moreRight = true;
else
so->markPos.moreLeft = true;
}
}
if (ScanDirectionIsForward(dir))
{
/* Walk right to the next page with data */
if (scan->parallel_scan != NULL)
{
/*
* Seize the scan to get the next block number; if the scan has
* ended already, bail out.
*/
status = _bt_parallel_seize(scan, &blkno, false);
if (!status)
{
/* release the previous buffer, if pinned */
BTScanPosUnpinIfPinned(so->currPos);
BTScanPosInvalidate(so->currPos);
return false;
}
}
else
{
/* Not parallel, so use the previously-saved nextPage link. */
blkno = so->currPos.nextPage;
}
/* Remember we left a page with data */
so->currPos.moreLeft = true;
/* release the previous buffer, if pinned */
BTScanPosUnpinIfPinned(so->currPos);
}
else
{
/* Remember we left a page with data */
so->currPos.moreRight = true;
if (scan->parallel_scan != NULL)
{
/*
* Seize the scan to get the current block number; if the scan has
* ended already, bail out.
*/
status = _bt_parallel_seize(scan, &blkno, false);
BTScanPosUnpinIfPinned(so->currPos);
if (!status)
{
BTScanPosInvalidate(so->currPos);
return false;
}
}
else
{
/* Not parallel, so just use our own notion of the current page */
blkno = so->currPos.currPage;
}
}
if (!_bt_readnextpage(scan, blkno, dir))
return false;
/* We have at least one item to return as scan's next item */
_bt_drop_lock_and_maybe_pin(scan, &so->currPos);
return true;
}
/*
* _bt_readnextpage() -- Read next page containing valid data for scan
*
* On success exit, so->currPos is updated to contain data from the next
* interesting page, and we return true. Caller must release the lock (and
* maybe the pin) on the buffer on success exit.
*
* If there are no more matching records in the given direction, we drop all
* locks and pins, set so->currPos.buf to InvalidBuffer, and return false.
*/
static bool
_bt_readnextpage(IndexScanDesc scan, BlockNumber blkno, ScanDirection dir)
{
BTScanOpaque so = (BTScanOpaque) scan->opaque;
Relation rel;
Page page;
BTPageOpaque opaque;
bool status;
rel = scan->indexRelation;
if (ScanDirectionIsForward(dir))
{
for (;;)
{
/*
* if we're at end of scan, give up and mark parallel scan as
* done, so that all the workers can finish their scan
*/
if (blkno == P_NONE || !so->currPos.moreRight)
{
_bt_parallel_done(scan);
BTScanPosInvalidate(so->currPos);
return false;
}
/* check for interrupts while we're not holding any buffer lock */
CHECK_FOR_INTERRUPTS();
/* step right one page */
so->currPos.buf = _bt_getbuf(rel, blkno, BT_READ);
page = BufferGetPage(so->currPos.buf);
opaque = BTPageGetOpaque(page);
/* check for deleted page */
if (!P_IGNORE(opaque))
{
PredicateLockPage(rel, blkno, scan->xs_snapshot);
/* see if there are any matches on this page */
/* note that this will clear moreRight if we can stop */
if (_bt_readpage(scan, dir, P_FIRSTDATAKEY(opaque), false))
break;
}
else if (scan->parallel_scan != NULL)
{
/* allow next page be processed by parallel worker */
_bt_parallel_release(scan, opaque->btpo_next);
}
/* nope, keep going */
if (scan->parallel_scan != NULL)
{
_bt_relbuf(rel, so->currPos.buf);
status = _bt_parallel_seize(scan, &blkno, false);
if (!status)
{
BTScanPosInvalidate(so->currPos);
return false;
}
}
else
{
blkno = opaque->btpo_next;
_bt_relbuf(rel, so->currPos.buf);
}
}
}
else
{
/*
* Should only happen in parallel cases, when some other backend
* advanced the scan.
*/
if (so->currPos.currPage != blkno)
{
BTScanPosUnpinIfPinned(so->currPos);
so->currPos.currPage = blkno;
}
/* Done if we know that the left sibling link isn't of interest */
if (!so->currPos.moreLeft)
{
BTScanPosUnpinIfPinned(so->currPos);
_bt_parallel_done(scan);
BTScanPosInvalidate(so->currPos);
return false;
}
/*
* Walk left to the next page with data. This is much more complex
* than the walk-right case because of the possibility that the page
* to our left splits while we are in flight to it, plus the
* possibility that the page we were on gets deleted after we leave
* it. See nbtree/README for details.
*
* It might be possible to rearrange this code to have less overhead
* in pinning and locking, but that would require capturing the left
* sibling block number when the page is initially read, and then
* optimistically starting there (rather than pinning the page twice).
* It is not clear that this would be worth the complexity.
*/
if (BTScanPosIsPinned(so->currPos))
_bt_lockbuf(rel, so->currPos.buf, BT_READ);
else
so->currPos.buf = _bt_getbuf(rel, so->currPos.currPage, BT_READ);
for (;;)
{
/* Done if we know that the left sibling link isn't of interest */
if (!so->currPos.moreLeft)
{
_bt_relbuf(rel, so->currPos.buf);
_bt_parallel_done(scan);
BTScanPosInvalidate(so->currPos);
return false;
}
/* Step to next physical page */
so->currPos.buf = _bt_walk_left(rel, so->currPos.buf);
/* if we're physically at end of index, return failure */
if (so->currPos.buf == InvalidBuffer)
{
_bt_parallel_done(scan);
BTScanPosInvalidate(so->currPos);
return false;
}
/*
* Okay, we managed to move left to a non-deleted page. Done if
* it's not half-dead and contains matching tuples. Else loop back
* and do it all again.
*/
page = BufferGetPage(so->currPos.buf);
opaque = BTPageGetOpaque(page);
if (!P_IGNORE(opaque))
{
PredicateLockPage(rel, BufferGetBlockNumber(so->currPos.buf), scan->xs_snapshot);
/* see if there are any matches on this page */
/* note that this will clear moreLeft if we can stop */
if (_bt_readpage(scan, dir, PageGetMaxOffsetNumber(page), false))
break;
}
else if (scan->parallel_scan != NULL)
{
/* allow next page be processed by parallel worker */
_bt_parallel_release(scan, BufferGetBlockNumber(so->currPos.buf));
}
/*
* For parallel scans, get the last page scanned as it is quite
* possible that by the time we try to seize the scan, some other
* worker has already advanced the scan to a different page. We
* must continue based on the latest page scanned by any worker.
*/
if (scan->parallel_scan != NULL)
{
_bt_relbuf(rel, so->currPos.buf);
status = _bt_parallel_seize(scan, &blkno, false);
if (!status)
{
BTScanPosInvalidate(so->currPos);
return false;
}
so->currPos.buf = _bt_getbuf(rel, blkno, BT_READ);
}
}
}
return true;
}
/*
* _bt_parallel_readpage() -- Read current page containing valid data for scan
*
* On success, release lock and maybe pin on buffer. We return true to
* indicate success.
*/
static bool
_bt_parallel_readpage(IndexScanDesc scan, BlockNumber blkno, ScanDirection dir)
{
BTScanOpaque so = (BTScanOpaque) scan->opaque;
Assert(!so->needPrimScan);
_bt_initialize_more_data(so, dir);
if (!_bt_readnextpage(scan, blkno, dir))
return false;
/* We have at least one item to return as scan's next item */
_bt_drop_lock_and_maybe_pin(scan, &so->currPos);
return true;
}
/*
* _bt_walk_left() -- step left one page, if possible
*
* The given buffer must be pinned and read-locked. This will be dropped
* before stepping left. On return, we have pin and read lock on the
* returned page, instead.
*
* Returns InvalidBuffer if there is no page to the left (no lock is held
* in that case).
*
* It is possible for the returned leaf page to be half-dead; caller must
* check that condition and step left again when required.
*/
static Buffer
_bt_walk_left(Relation rel, Buffer buf)
{
Page page;
BTPageOpaque opaque;
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
for (;;)
{
BlockNumber obknum;
BlockNumber lblkno;
BlockNumber blkno;
int tries;
/* if we're at end of tree, release buf and return failure */
if (P_LEFTMOST(opaque))
{
_bt_relbuf(rel, buf);
break;
}
/* remember original page we are stepping left from */
obknum = BufferGetBlockNumber(buf);
/* step left */
blkno = lblkno = opaque->btpo_prev;
_bt_relbuf(rel, buf);
/* check for interrupts while we're not holding any buffer lock */
CHECK_FOR_INTERRUPTS();
buf = _bt_getbuf(rel, blkno, BT_READ);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
/*
* If this isn't the page we want, walk right till we find what we
* want --- but go no more than four hops (an arbitrary limit). If we
* don't find the correct page by then, the most likely bet is that
* the original page got deleted and isn't in the sibling chain at all
* anymore, not that its left sibling got split more than four times.
*
* Note that it is correct to test P_ISDELETED not P_IGNORE here,
* because half-dead pages are still in the sibling chain.
*/
tries = 0;
for (;;)
{
if (!P_ISDELETED(opaque) && opaque->btpo_next == obknum)
{
/* Found desired page, return it */
return buf;
}
if (P_RIGHTMOST(opaque) || ++tries > 4)
break;
blkno = opaque->btpo_next;
buf = _bt_relandgetbuf(rel, buf, blkno, BT_READ);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
}
/* Return to the original page to see what's up */
buf = _bt_relandgetbuf(rel, buf, obknum, BT_READ);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
if (P_ISDELETED(opaque))
{
/*
* It was deleted. Move right to first nondeleted page (there
* must be one); that is the page that has acquired the deleted
* one's keyspace, so stepping left from it will take us where we
* want to be.
*/
for (;;)
{
if (P_RIGHTMOST(opaque))
elog(ERROR, "fell off the end of index \"%s\"",
RelationGetRelationName(rel));
blkno = opaque->btpo_next;
buf = _bt_relandgetbuf(rel, buf, blkno, BT_READ);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
if (!P_ISDELETED(opaque))
break;
}
/*
* Now return to top of loop, resetting obknum to point to this
* nondeleted page, and try again.
*/
}
else
{
/*
* It wasn't deleted; the explanation had better be that the page
* to the left got split or deleted. Without this check, we'd go
* into an infinite loop if there's anything wrong.
*/
if (opaque->btpo_prev == lblkno)
elog(ERROR, "could not find left sibling of block %u in index \"%s\"",
obknum, RelationGetRelationName(rel));
/* Okay to try again with new lblkno value */
}
}
return InvalidBuffer;
}
/*
* _bt_get_endpoint() -- Find the first or last page on a given tree level
*
* If the index is empty, we will return InvalidBuffer; any other failure
* condition causes ereport(). We will not return a dead page.
*
* The returned buffer is pinned and read-locked.
*/
Buffer
_bt_get_endpoint(Relation rel, uint32 level, bool rightmost)
{
Buffer buf;
Page page;
BTPageOpaque opaque;
OffsetNumber offnum;
BlockNumber blkno;
IndexTuple itup;
/*
* If we are looking for a leaf page, okay to descend from fast root;
* otherwise better descend from true root. (There is no point in being
* smarter about intermediate levels.)
*/
if (level == 0)
buf = _bt_getroot(rel, NULL, BT_READ);
else
buf = _bt_gettrueroot(rel);
if (!BufferIsValid(buf))
return InvalidBuffer;
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
for (;;)
{
/*
* If we landed on a deleted page, step right to find a live page
* (there must be one). Also, if we want the rightmost page, step
* right if needed to get to it (this could happen if the page split
* since we obtained a pointer to it).
*/
while (P_IGNORE(opaque) ||
(rightmost && !P_RIGHTMOST(opaque)))
{
blkno = opaque->btpo_next;
if (blkno == P_NONE)
elog(ERROR, "fell off the end of index \"%s\"",
RelationGetRelationName(rel));
buf = _bt_relandgetbuf(rel, buf, blkno, BT_READ);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
}
/* Done? */
if (opaque->btpo_level == level)
break;
if (opaque->btpo_level < level)
ereport(ERROR,
(errcode(ERRCODE_INDEX_CORRUPTED),
errmsg_internal("btree level %u not found in index \"%s\"",
level, RelationGetRelationName(rel))));
/* Descend to leftmost or rightmost child page */
if (rightmost)
offnum = PageGetMaxOffsetNumber(page);
else
offnum = P_FIRSTDATAKEY(opaque);
itup = (IndexTuple) PageGetItem(page, PageGetItemId(page, offnum));
blkno = BTreeTupleGetDownLink(itup);
buf = _bt_relandgetbuf(rel, buf, blkno, BT_READ);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
}
return buf;
}
/*
* _bt_endpoint() -- Find the first or last page in the index, and scan
* from there to the first key satisfying all the quals.
*
* This is used by _bt_first() to set up a scan when we've determined
* that the scan must start at the beginning or end of the index (for
* a forward or backward scan respectively). Exit conditions are the
* same as for _bt_first().
*/
static bool
_bt_endpoint(IndexScanDesc scan, ScanDirection dir)
{
Relation rel = scan->indexRelation;
BTScanOpaque so = (BTScanOpaque) scan->opaque;
Buffer buf;
Page page;
BTPageOpaque opaque;
OffsetNumber start;
BTScanPosItem *currItem;
/*
* Scan down to the leftmost or rightmost leaf page. This is a simplified
* version of _bt_search(). We don't maintain a stack since we know we
* won't need it.
*/
buf = _bt_get_endpoint(rel, 0, ScanDirectionIsBackward(dir));
if (!BufferIsValid(buf))
{
/*
* Empty index. Lock the whole relation, as nothing finer to lock
* exists.
*/
PredicateLockRelation(rel, scan->xs_snapshot);
BTScanPosInvalidate(so->currPos);
return false;
}
PredicateLockPage(rel, BufferGetBlockNumber(buf), scan->xs_snapshot);
page = BufferGetPage(buf);
opaque = BTPageGetOpaque(page);
Assert(P_ISLEAF(opaque));
if (ScanDirectionIsForward(dir))
{
/* There could be dead pages to the left, so not this: */
/* Assert(P_LEFTMOST(opaque)); */
start = P_FIRSTDATAKEY(opaque);
}
else if (ScanDirectionIsBackward(dir))
{
Assert(P_RIGHTMOST(opaque));
start = PageGetMaxOffsetNumber(page);
}
else
{
elog(ERROR, "invalid scan direction: %d", (int) dir);
start = 0; /* keep compiler quiet */
}
/* remember which buffer we have pinned */
so->currPos.buf = buf;
_bt_initialize_more_data(so, dir);
/*
* Now load data from the first page of the scan.
*/
if (!_bt_readpage(scan, dir, start, true))
{
/*
* There's no actually-matching data on this page. Try to advance to
* the next page. Return false if there's no matching data at all.
*/
_bt_unlockbuf(scan->indexRelation, so->currPos.buf);
if (!_bt_steppage(scan, dir))
return false;
}
else
{
/* We have at least one item to return as scan's first item */
_bt_drop_lock_and_maybe_pin(scan, &so->currPos);
}
/* OK, itemIndex says what to return */
currItem = &so->currPos.items[so->currPos.itemIndex];
scan->xs_heaptid = currItem->heapTid;
if (scan->xs_want_itup)
scan->xs_itup = (IndexTuple) (so->currTuples + currItem->tupleOffset);
return true;
}
/*
* _bt_initialize_more_data() -- initialize moreLeft, moreRight and scan dir
* from currPos
*/
static inline void
_bt_initialize_more_data(BTScanOpaque so, ScanDirection dir)
{
so->currPos.dir = dir;
if (so->needPrimScan)
{
Assert(so->numArrayKeys);
so->currPos.moreLeft = true;
so->currPos.moreRight = true;
so->needPrimScan = false;
}
else if (ScanDirectionIsForward(dir))
{
so->currPos.moreLeft = false;
so->currPos.moreRight = true;
}
else
{
so->currPos.moreLeft = true;
so->currPos.moreRight = false;
}
so->numKilled = 0; /* just paranoia */
so->markItemIndex = -1; /* ditto */
}
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