/*------------------------------------------------------------------------- * * nbtsearch.c * Search code for postgres btrees. * * * Portions Copyright (c) 1996-2023, 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); 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 a leaf page, _bt_binsrch() returns the OffsetNumber of the first * key >= given scankey, or > scankey if nextkey is true. (NOTE: in * particular, this means it is possible to return a value 1 greater than the * number of keys on the page, if the scankey is > all keys on the 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.) This key indicates the * right place to descend to be sure we find all leaf keys >= given scankey * (or leaf keys > given scankey when nextkey is true). * * 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 children). */ 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, but be careful: they could point * past the last slot on the page. * * On a leaf page, we always return the first key >= scan key (resp. > * scan key), which could be the last slot + 1. */ if (P_ISLEAF(opaque)) 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. */ 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) { /* * Most searches 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. * * 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', ), 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. * * However, some searches (pivotsearch searches) actually require that * we descend left when this happens. -inf is treated as a possible * match for omitted scankey attribute(s). This is needed by page * deletion, which must re-find leaf pages that are targets for * deletion using their high keys. * * Note: the heap TID part of the test ensures that scankey is being * compared to a pivot tuple with one or more truncated key * attributes. * * Note: pg_upgrade'd !heapkeyspace indexes must always descend to the * left here, since they have no heap TID attribute (and cannot have * any -inf key values in any case, since truncation can only remove * non-key attributes). !heapkeyspace searches must always be * prepared to deal with matches on both sides of the pivot once the * leaf level is reached. */ if (key->heapkeyspace && !key->pivotsearch && key->keysz == ntupatts && heapTid == NULL) 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_ctup.t_self 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; bool nextkey; bool goback; BTScanInsertData inskey; ScanKey startKeys[INDEX_MAX_KEYS]; ScanKeyData notnullkeys[INDEX_MAX_KEYS]; int keysCount = 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) { /* Notify any other workers that we're done with this scan key. */ _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. */ if (scan->parallel_scan != NULL) { status = _bt_parallel_seize(scan, &blkno); 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; } } /*---------- * 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. *---------- */ 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[keysCount] */ chosen = ¬nullkeys[keysCount]; 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[keysCount++] = 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 (keysCount == 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(keysCount <= INDEX_MAX_KEYS); for (i = 0; i < keysCount; 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 == keysCount - 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 != keysCount + 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(keysCount < INDEX_MAX_KEYS); memcpy(inskey.scankeys + keysCount, subkey, sizeof(ScanKeyData)); keysCount++; 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 * code below. * * If nextkey = false, _bt_search and _bt_binsrch will locate the first * item >= scan key. If nextkey = true, they will locate the first * item > scan key. * * If goback = true, we will then step back one item, while if * goback = false, we will start the scan on the located item. *---------- */ switch (strat_total) { case BTLessStrategyNumber: /* * Find first item >= scankey, then back up one to arrive at last * item < scankey. (Note: this positioning strategy is only used * for a backward scan, so that is always the correct starting * position.) */ nextkey = false; goback = true; break; case BTLessEqualStrategyNumber: /* * Find first item > scankey, then back up one to arrive at last * item <= scankey. (Note: this positioning strategy is only used * for a backward scan, so that is always the correct starting * position.) */ nextkey = true; goback = 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. We will check at the * end whether the found item is actually =. */ nextkey = true; goback = true; } else { /* * This is the same as the >= strategy. We will check at the * end whether the found item is actually =. */ nextkey = false; goback = false; } break; case BTGreaterEqualStrategyNumber: /* * Find first item >= scankey. (This is only used for forward * scans.) */ nextkey = false; goback = false; break; case BTGreaterStrategyNumber: /* * Find first item > scankey. (This is only used for forward * scans.) */ nextkey = true; goback = false; break; default: /* can't get here, but keep compiler quiet */ elog(ERROR, "unrecognized strat_total: %d", (int) strat_total); return false; } /* Initialize remaining insertion scan key fields */ _bt_metaversion(rel, &inskey.heapkeyspace, &inskey.allequalimage); inskey.anynullkeys = false; /* unused */ inskey.nextkey = nextkey; inskey.pivotsearch = false; inskey.scantid = NULL; inskey.keysz = keysCount; /* * Use the manufactured insertion scan key to descend the tree and * position ourselves on the target leaf page. */ 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); /* * If nextkey = false, we are positioned at the first item >= scan key, or * possibly at the end of a page on which all the existing items are less * than the scan key and we know that everything on later pages is greater * than or equal to scan key. * * If nextkey = true, we are positioned at the first item > scan key, or * possibly at the end of a page on which all the existing items are less * than or equal to the scan key and we know that everything on later * pages is greater than scan key. * * The actually desired starting point is either this item or the prior * one, or in the end-of-page case it's the first item on the next page or * the last item on this page. Adjust the starting offset if needed. (If * this results in an offset before the first item or after the last one, * _bt_readpage will report no items found, and then we'll step to the * next page as needed.) */ if (goback) offnum = OffsetNumberPrev(offnum); /* remember which buffer we have pinned, if any */ Assert(!BTScanPosIsValid(so->currPos)); so->currPos.buf = buf; so->firstPage = true; /* * Now load data from the first page of the scan. */ if (!_bt_readpage(scan, dir, offnum)) { /* * 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 { /* Drop the lock, and maybe the pin, on the current page */ _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_ctup.t_self 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. * * 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) { BTScanOpaque so = (BTScanOpaque) scan->opaque; Page page; BTPageOpaque opaque; OffsetNumber minoff; OffsetNumber maxoff; int itemIndex; bool continuescan; int indnatts; bool requiredMatchedByPrecheck; /* * 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)) _bt_parallel_release(scan, opaque->btpo_next); else _bt_parallel_release(scan, BufferGetBlockNumber(so->currPos.buf)); } continuescan = true; /* default assumption */ indnatts = IndexRelationGetNumberOfAttributes(scan->indexRelation); minoff = P_FIRSTDATAKEY(opaque); maxoff = PageGetMaxOffsetNumber(page); /* * 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 page with scan keys required for direction scan. We * check these keys with the last item on the page (according to our scan * direction). If these keys are matched, we can skip checking them with * every item on the page. Scan keys for our scan direction would * necessarily match the previous items. Scan keys required for opposite * direction scan are already matched by the _bt_first() call. * * 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 in the scan to evade the possible * slowdown of the point queries. */ if (!so->firstPage && minoff < maxoff) { ItemId iid; IndexTuple itup; iid = PageGetItemId(page, ScanDirectionIsForward(dir) ? maxoff : minoff); itup = (IndexTuple) PageGetItem(page, iid); /* * Do the precheck. Note that we pass the pointer to * 'requiredMatchedByPrecheck' to 'continuescan' argument. That will * set flag to true if all required keys are satisfied and false * otherwise. */ (void) _bt_checkkeys(scan, itup, indnatts, dir, &requiredMatchedByPrecheck, false); } else { so->firstPage = false; requiredMatchedByPrecheck = false; } if (ScanDirectionIsForward(dir)) { /* 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); passes_quals = _bt_checkkeys(scan, itup, indnatts, dir, &continuescan, requiredMatchedByPrecheck); /* * If the result of prechecking required keys was true, then in * assert-enabled builds we also recheck that the _bt_checkkeys() * result is the same. */ Assert(!requiredMatchedByPrecheck || passes_quals == _bt_checkkeys(scan, itup, indnatts, dir, &continuescan, false)); if (passes_quals) { /* tuple passes all scan key conditions */ 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 (!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 (continuescan && !P_RIGHTMOST(opaque)) { ItemId iid = PageGetItemId(page, P_HIKEY); IndexTuple itup = (IndexTuple) PageGetItem(page, iid); int truncatt; truncatt = BTreeTupleGetNAtts(itup, scan->indexRelation); _bt_checkkeys(scan, itup, truncatt, dir, &continuescan, false); } if (!continuescan) so->currPos.moreRight = false; Assert(itemIndex <= MaxTIDsPerBTreePage); so->currPos.firstItem = 0; so->currPos.lastItem = itemIndex - 1; so->currPos.itemIndex = 0; } else { /* 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); passes_quals = _bt_checkkeys(scan, itup, indnatts, dir, &continuescan, requiredMatchedByPrecheck); /* * If the result of prechecking required keys was true, then in * assert-enabled builds we also recheck that the _bt_checkkeys() * result is the same. */ Assert(!requiredMatchedByPrecheck || passes_quals == _bt_checkkeys(scan, itup, indnatts, dir, &continuescan, false)); if (passes_quals && tuple_alive) { /* tuple passes all scan key conditions */ 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); } } } if (!continuescan) { /* there can't be any more matches, so stop */ so->currPos.moreLeft = false; break; } offnum = OffsetNumberPrev(offnum); } 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 (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); 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); 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; /* Drop the lock, and maybe the pin, on the current page */ _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. Caller is responsible to release lock and pin on * buffer on success. We return true to indicate success. * * 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))) 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); 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; } /* * 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 * pointer when the page is initially read, and using it here, along * with big changes to _bt_walk_left() and the code below. It is not * clear whether this would be a win, since if the page immediately to * the left splits after we read this page and before we step left, we * would need to visit more pages than with the current code. * * Note that if we change the code so that we drop the pin for a scan * which uses a non-MVCC snapshot, we will need to modify the code for * walking left, to allow for the possibility that a referenced page * has been deleted. As long as the buffer is pinned or the snapshot * is MVCC the page cannot move past the half-dead state to fully * deleted. */ 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 there are no matching keys to the left */ 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))) 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); 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; _bt_initialize_more_data(so, dir); if (!_bt_readnextpage(scan, blkno, dir)) return false; /* Drop the lock, and maybe the pin, on the current page */ _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). * * When working on a non-leaf level, it is possible for the returned page * to be half-dead; the caller should check that condition and step left * again if it's important. */ 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. Caller * must reject half-dead pages if wanted. */ 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; so->firstPage = true; _bt_initialize_more_data(so, dir); /* * Now load data from the first page of the scan. */ if (!_bt_readpage(scan, dir, start)) { /* * 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 { /* Drop the lock, and maybe the pin, on the current page */ _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 appropriately * for scan direction */ static inline void _bt_initialize_more_data(BTScanOpaque so, ScanDirection dir) { /* initialize moreLeft/moreRight appropriately for scan direction */ 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 */ }