/*------------------------------------------------------------------------- * * nbtsearch.c * search code for postgres btrees. * * * Portions Copyright (c) 1996-2002, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/access/nbtree/nbtsearch.c,v 1.72 2002/06/20 20:29:25 momjian Exp $ * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/genam.h" #include "access/nbtree.h" static bool _bt_endpoint(IndexScanDesc scan, ScanDirection dir); /* * _bt_search() -- Search the tree for a particular scankey, * or more precisely for the first leaf page it could be on. * * Return value is a stack of parent-page pointers. *bufP is set to the * address of the leaf-page buffer, which is read-locked and pinned. * No locks are held on the parent pages, however! * * NOTE that the returned buffer is read-locked regardless of the access * parameter. However, 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. */ BTStack _bt_search(Relation rel, int keysz, ScanKey scankey, Buffer *bufP, int access) { BTStack stack_in = NULL; /* Get the root page to start with */ *bufP = _bt_getroot(rel, 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; BTItem btitem; IndexTuple itup; BlockNumber blkno; BlockNumber par_blkno; BTStack new_stack; /* if this is a leaf page, we're done */ page = BufferGetPage(*bufP); opaque = (BTPageOpaque) PageGetSpecialPointer(page); if (P_ISLEAF(opaque)) break; /* * Find the appropriate item on the internal page, and get the * child page that it points to. */ offnum = _bt_binsrch(rel, *bufP, keysz, scankey); itemid = PageGetItemId(page, offnum); btitem = (BTItem) PageGetItem(page, itemid); itup = &(btitem->bti_itup); blkno = ItemPointerGetBlockNumber(&(itup->t_tid)); par_blkno = BufferGetBlockNumber(*bufP); /* * We need to save the bit image of the index entry we chose in * the parent page on a stack. In case we split the tree, we'll * use this bit image to figure out what our real parent page is, * in case the parent splits while we're working lower in the * tree. See the paper by Lehman and Yao for how this is detected * and handled. (We use the child link to disambiguate duplicate * keys in the index -- Lehman and Yao disallow duplicate keys.) */ new_stack = (BTStack) palloc(sizeof(BTStackData)); new_stack->bts_blkno = par_blkno; new_stack->bts_offset = offnum; memcpy(&new_stack->bts_btitem, btitem, sizeof(BTItemData)); new_stack->bts_parent = stack_in; /* drop the read lock on the parent page, acquire one on the child */ _bt_relbuf(rel, *bufP); *bufP = _bt_getbuf(rel, blkno, BT_READ); /* * Race -- the page we just grabbed may have split since we read * its pointer in the parent. If it has, we may need to move * right to its new sibling. Do that. */ *bufP = _bt_moveright(rel, *bufP, keysz, scankey, BT_READ); /* okay, all set to move down a level */ stack_in = new_stack; } return stack_in; } /* * _bt_moveright() -- move right in the btree if necessary. * * When we drop and reacquire a pointer to 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 one we expect to be on the page, then our * picture of the page is incorrect and we need to move right. * * On entry, we have the buffer pinned and a lock of the proper type. * 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, Buffer buf, int keysz, ScanKey scankey, int access) { Page page; BTPageOpaque opaque; page = BufferGetPage(buf); opaque = (BTPageOpaque) PageGetSpecialPointer(page); /* * 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. (If the scan key is equal to the high key, we might or * might not need to move right; have to scan the page first anyway.) * It could even have split more than once, so scan as far as needed. */ while (!P_RIGHTMOST(opaque) && _bt_compare(rel, keysz, scankey, page, P_HIKEY) > 0) { /* step right one page */ BlockNumber rblkno = opaque->btpo_next; _bt_relbuf(rel, buf); buf = _bt_getbuf(rel, rblkno, access); page = BufferGetPage(buf); opaque = (BTPageOpaque) PageGetSpecialPointer(page); } return buf; } /* * _bt_binsrch() -- Do a binary search for a key on a particular page. * * The scankey we get has the compare function stored in the procedure * entry of each data struct. We invoke this regproc to do the * comparison for every key in the scankey. * * On a leaf page, _bt_binsrch() returns the OffsetNumber of the first * key >= given scankey. (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. (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. * * 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. */ OffsetNumber _bt_binsrch(Relation rel, Buffer buf, int keysz, ScanKey scankey) { TupleDesc itupdesc; Page page; BTPageOpaque opaque; OffsetNumber low, high; int32 result; itupdesc = RelationGetDescr(rel); page = BufferGetPage(buf); opaque = (BTPageOpaque) PageGetSpecialPointer(page); 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 (high < low) return low; /* * Binary search to find the first key on the page >= scan key. Loop * invariant: 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 */ 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, keysz, scankey, page, mid); if (result > 0) 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 (which * could be the last slot + 1). */ if (P_ISLEAF(opaque)) return low; /* * On a non-leaf page, return the last key < scan key. There must be * one if _bt_compare() is playing by the rules. */ Assert(low > P_FIRSTDATAKEY(opaque)); return OffsetNumberPrev(low); } /*---------- * _bt_compare() -- Compare scankey to a particular tuple on the page. * * keysz: number of key conditions to be checked (might be less than the * total length of the scan key!) * 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! * * 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 (if any, which there probably isn't) * does not matter. This convention 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, int keysz, ScanKey scankey, Page page, OffsetNumber offnum) { TupleDesc itupdesc = RelationGetDescr(rel); BTPageOpaque opaque = (BTPageOpaque) PageGetSpecialPointer(page); BTItem btitem; IndexTuple itup; int i; /* * 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; btitem = (BTItem) PageGetItem(page, PageGetItemId(page, offnum)); itup = &(btitem->bti_itup); /* * 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). */ for (i = 0; i < keysz; i++) { ScanKey entry = &scankey[i]; Datum datum; bool isNull; int32 result; datum = index_getattr(itup, entry->sk_attno, itupdesc, &isNull); /* see comments about NULLs handling in btbuild */ if (entry->sk_flags & SK_ISNULL) /* key is NULL */ { if (isNull) result = 0; /* NULL "=" NULL */ else result = 1; /* NULL ">" NOT_NULL */ } else if (isNull) /* key is NOT_NULL and item is NULL */ { result = -1; /* NOT_NULL "<" NULL */ } else { result = DatumGetInt32(FunctionCall2(&entry->sk_func, entry->sk_argument, datum)); } /* if the keys are unequal, return the difference */ if (result != 0) return result; } /* if we get here, the keys are equal */ return 0; } /* * _bt_next() -- Get the next item in a scan. * * On entry, we have a valid currentItemData in the scan, and a * read lock and pin count on the page that contains that item. * We return the next item in the scan, or false if no more. * On successful exit, the page containing the new item is locked * and pinned; on failure exit, no lock or pin is held. */ bool _bt_next(IndexScanDesc scan, ScanDirection dir) { Relation rel; Buffer buf; Page page; OffsetNumber offnum; ItemPointer current; BTItem btitem; IndexTuple itup; BTScanOpaque so; bool continuescan; rel = scan->indexRelation; so = (BTScanOpaque) scan->opaque; current = &(scan->currentItemData); /* we still have the buffer pinned and locked */ buf = so->btso_curbuf; Assert(BufferIsValid(buf)); do { /* step one tuple in the appropriate direction */ if (!_bt_step(scan, &buf, dir)) return false; /* current is the next candidate tuple to return */ offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); btitem = (BTItem) PageGetItem(page, PageGetItemId(page, offnum)); itup = &btitem->bti_itup; if (_bt_checkkeys(scan, itup, dir, &continuescan)) { /* tuple passes all scan key conditions, so return it */ scan->xs_ctup.t_self = itup->t_tid; return true; } /* This tuple doesn't pass, but there might be more that do */ } while (continuescan); /* No more items, so close down the current-item info */ ItemPointerSetInvalid(current); so->btso_curbuf = InvalidBuffer; _bt_relbuf(rel, buf); return false; } /* * _bt_first() -- Find the first item in a scan. * * We need to be clever about the type of scan, the operation it's * performing, and the tree ordering. We find the * first item in the tree that satisfies the qualification * associated with the scan descriptor. On exit, the page containing * the current index tuple is read locked and pinned, and the scan's * opaque data entry is updated to include the buffer. */ bool _bt_first(IndexScanDesc scan, ScanDirection dir) { Relation rel = scan->indexRelation; BTScanOpaque so = (BTScanOpaque) scan->opaque; Buffer buf; Page page; BTStack stack; OffsetNumber offnum; BTItem btitem; IndexTuple itup; ItemPointer current; BlockNumber blkno; StrategyNumber strat; bool res; int32 result; bool scanFromEnd; bool continuescan; ScanKey scankeys = NULL; int keysCount = 0; int *nKeyIs = NULL; int i, j; StrategyNumber strat_total; /* * Order the scan keys in our canonical fashion and eliminate any * redundant keys. */ _bt_orderkeys(scan); /* * Quit now if _bt_orderkeys() discovered that the scan keys can never * be satisfied (eg, x == 1 AND x > 2). */ if (!so->qual_ok) return false; /* * Examine the scan keys to discover where we need to start the scan. */ scanFromEnd = false; strat_total = BTEqualStrategyNumber; if (so->numberOfKeys > 0) { nKeyIs = (int *) palloc(so->numberOfKeys * sizeof(int)); for (i = 0; i < so->numberOfKeys; i++) { AttrNumber attno = so->keyData[i].sk_attno; /* ignore keys for already-determined attrs */ if (attno <= keysCount) continue; /* if we didn't find a boundary for the preceding attr, quit */ if (attno > keysCount + 1) break; strat = _bt_getstrat(rel, attno, so->keyData[i].sk_procedure); /* * Can we use this key as a starting boundary for this attr? * * We can use multiple keys if they look like, say, = >= = but we * have to stop after accepting a > or < boundary. */ if (strat == strat_total || strat == BTEqualStrategyNumber) nKeyIs[keysCount++] = i; else if (ScanDirectionIsBackward(dir) && (strat == BTLessStrategyNumber || strat == BTLessEqualStrategyNumber)) { nKeyIs[keysCount++] = i; strat_total = strat; if (strat == BTLessStrategyNumber) break; } else if (ScanDirectionIsForward(dir) && (strat == BTGreaterStrategyNumber || strat == BTGreaterEqualStrategyNumber)) { nKeyIs[keysCount++] = i; strat_total = strat; if (strat == BTGreaterStrategyNumber) break; } } if (keysCount == 0) scanFromEnd = true; } else scanFromEnd = true; /* if we just need to walk down one edge of the tree, do that */ if (scanFromEnd) { if (nKeyIs) pfree(nKeyIs); return _bt_endpoint(scan, dir); } /* * We want to start the scan somewhere within the index. Set up a * scankey we can use to search for the correct starting point. */ scankeys = (ScanKey) palloc(keysCount * sizeof(ScanKeyData)); for (i = 0; i < keysCount; i++) { FmgrInfo *procinfo; j = nKeyIs[i]; /* * _bt_orderkeys disallows it, but it's place to add some code * later */ if (so->keyData[j].sk_flags & SK_ISNULL) { pfree(nKeyIs); pfree(scankeys); elog(ERROR, "_bt_first: btree doesn't support is(not)null, yet"); return false; } procinfo = index_getprocinfo(rel, i + 1, BTORDER_PROC); ScanKeyEntryInitializeWithInfo(scankeys + i, so->keyData[j].sk_flags, i + 1, procinfo, CurrentMemoryContext, so->keyData[j].sk_argument); } if (nKeyIs) pfree(nKeyIs); current = &(scan->currentItemData); /* * Use the manufactured scan key to descend the tree and position * ourselves on the target leaf page. */ stack = _bt_search(rel, keysCount, scankeys, &buf, BT_READ); /* don't need to keep the stack around... */ _bt_freestack(stack); if (!BufferIsValid(buf)) { /* Only get here if index is completely empty */ ItemPointerSetInvalid(current); so->btso_curbuf = InvalidBuffer; pfree(scankeys); return false; } /* remember which buffer we have pinned */ so->btso_curbuf = buf; blkno = BufferGetBlockNumber(buf); page = BufferGetPage(buf); /* position to the precise item on the page */ offnum = _bt_binsrch(rel, buf, keysCount, scankeys); ItemPointerSet(current, blkno, offnum); /* * At this point we are positioned at the first item >= scan key, or * possibly at the end of a page on which all the existing items are * greater than the scan key and we know that everything on later * pages is less than or equal to scan key. * * We could step forward in the latter case, but that'd be a waste of * time if we want to scan backwards. So, it's now time to examine * the scan strategy to find the exact place to start the scan. * * Note: if _bt_step fails (meaning we fell off the end of the index in * one direction or the other), we either return false (no matches) or * call _bt_endpoint() to set up a scan starting at that index * endpoint, as appropriate for the desired scan type. * * it's yet other place to add some code later for is(not)null ... */ switch (strat_total) { case BTLessStrategyNumber: /* * Back up one to arrive at last item < scankey */ if (!_bt_step(scan, &buf, BackwardScanDirection)) { pfree(scankeys); return false; } break; case BTLessEqualStrategyNumber: /* * We need to find the last item <= scankey, so step forward * till we find one > scankey, then step back one. */ if (offnum > PageGetMaxOffsetNumber(page)) { if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return _bt_endpoint(scan, dir); } } for (;;) { offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); result = _bt_compare(rel, keysCount, scankeys, page, offnum); if (result < 0) break; if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return _bt_endpoint(scan, dir); } } if (!_bt_step(scan, &buf, BackwardScanDirection)) { pfree(scankeys); return false; } break; case BTEqualStrategyNumber: /* * Make sure we are on the first equal item; might have to * step forward if currently at end of page. */ if (offnum > PageGetMaxOffsetNumber(page)) { if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return false; } offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); } result = _bt_compare(rel, keysCount, scankeys, page, offnum); if (result != 0) goto nomatches; /* no equal items! */ /* * If a backward scan was specified, need to start with last * equal item not first one. */ if (ScanDirectionIsBackward(dir)) { do { if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return _bt_endpoint(scan, dir); } offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); result = _bt_compare(rel, keysCount, scankeys, page, offnum); } while (result == 0); if (!_bt_step(scan, &buf, BackwardScanDirection)) elog(ERROR, "_bt_first: equal items disappeared?"); } break; case BTGreaterEqualStrategyNumber: /* * We want the first item >= scankey, which is where we are... * unless we're not anywhere at all... */ if (offnum > PageGetMaxOffsetNumber(page)) { if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return false; } } break; case BTGreaterStrategyNumber: /* * We want the first item > scankey, so make sure we are on an * item and then step over any equal items. */ if (offnum > PageGetMaxOffsetNumber(page)) { if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return false; } offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); } result = _bt_compare(rel, keysCount, scankeys, page, offnum); while (result == 0) { if (!_bt_step(scan, &buf, ForwardScanDirection)) { pfree(scankeys); return false; } offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); result = _bt_compare(rel, keysCount, scankeys, page, offnum); } break; } /* okay, current item pointer for the scan is right */ offnum = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); btitem = (BTItem) PageGetItem(page, PageGetItemId(page, offnum)); itup = &btitem->bti_itup; /* is the first item actually acceptable? */ if (_bt_checkkeys(scan, itup, dir, &continuescan)) { /* yes, return it */ scan->xs_ctup.t_self = itup->t_tid; res = true; } else if (continuescan) { /* no, but there might be another one that is */ res = _bt_next(scan, dir); } else { /* no tuples in the index match this scan key */ nomatches: ItemPointerSetInvalid(current); so->btso_curbuf = InvalidBuffer; _bt_relbuf(rel, buf); res = false; } pfree(scankeys); return res; } /* * _bt_step() -- Step one item in the requested direction in a scan on * the tree. * * *bufP is the current buffer (read-locked and pinned). If we change * pages, it's updated appropriately. * * If successful, update scan's currentItemData and return true. * If no adjacent record exists in the requested direction, * release buffer pin/locks and return false. */ bool _bt_step(IndexScanDesc scan, Buffer *bufP, ScanDirection dir) { Relation rel = scan->indexRelation; ItemPointer current = &(scan->currentItemData); BTScanOpaque so = (BTScanOpaque) scan->opaque; Page page; BTPageOpaque opaque; OffsetNumber offnum, maxoff; BlockNumber blkno; BlockNumber obknum; /* * Don't use ItemPointerGetOffsetNumber or you risk to get assertion * due to ability of ip_posid to be equal 0. */ offnum = current->ip_posid; page = BufferGetPage(*bufP); opaque = (BTPageOpaque) PageGetSpecialPointer(page); maxoff = PageGetMaxOffsetNumber(page); if (ScanDirectionIsForward(dir)) { if (!PageIsEmpty(page) && offnum < maxoff) offnum = OffsetNumberNext(offnum); else { /* walk right to the next page with data */ for (;;) { /* if we're at end of scan, release the buffer and return */ if (P_RIGHTMOST(opaque)) { _bt_relbuf(rel, *bufP); ItemPointerSetInvalid(current); *bufP = so->btso_curbuf = InvalidBuffer; return false; } /* step right one page */ blkno = opaque->btpo_next; _bt_relbuf(rel, *bufP); *bufP = _bt_getbuf(rel, blkno, BT_READ); page = BufferGetPage(*bufP); opaque = (BTPageOpaque) PageGetSpecialPointer(page); maxoff = PageGetMaxOffsetNumber(page); /* done if it's not empty */ offnum = P_FIRSTDATAKEY(opaque); if (!PageIsEmpty(page) && offnum <= maxoff) break; } } } else { if (offnum > P_FIRSTDATAKEY(opaque)) offnum = OffsetNumberPrev(offnum); else { /* walk left to the next page with data */ for (;;) { /* if we're at end of scan, release the buffer and return */ if (P_LEFTMOST(opaque)) { _bt_relbuf(rel, *bufP); ItemPointerSetInvalid(current); *bufP = so->btso_curbuf = InvalidBuffer; return false; } /* step left */ obknum = BufferGetBlockNumber(*bufP); blkno = opaque->btpo_prev; _bt_relbuf(rel, *bufP); *bufP = _bt_getbuf(rel, blkno, BT_READ); page = BufferGetPage(*bufP); opaque = (BTPageOpaque) PageGetSpecialPointer(page); /* * If the adjacent page just split, then we have to walk * right to find the block that's now adjacent to where we * were. Because pages only split right, we don't have to * worry about this failing to terminate. */ while (opaque->btpo_next != obknum) { blkno = opaque->btpo_next; _bt_relbuf(rel, *bufP); *bufP = _bt_getbuf(rel, blkno, BT_READ); page = BufferGetPage(*bufP); opaque = (BTPageOpaque) PageGetSpecialPointer(page); } /* done if it's not empty */ maxoff = PageGetMaxOffsetNumber(page); offnum = maxoff; if (!PageIsEmpty(page) && maxoff >= P_FIRSTDATAKEY(opaque)) break; } } } /* Update scan state */ so->btso_curbuf = *bufP; blkno = BufferGetBlockNumber(*bufP); ItemPointerSet(current, blkno, offnum); return true; } /* * _bt_endpoint() -- Find the first or last key in the index. * * 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). */ static bool _bt_endpoint(IndexScanDesc scan, ScanDirection dir) { Relation rel; Buffer buf; Page page; BTPageOpaque opaque; ItemPointer current; OffsetNumber offnum, maxoff; OffsetNumber start; BlockNumber blkno; BTItem btitem; IndexTuple itup; BTScanOpaque so; bool res; bool continuescan; rel = scan->indexRelation; current = &(scan->currentItemData); so = (BTScanOpaque) scan->opaque; /* * 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_getroot(rel, BT_READ); if (!BufferIsValid(buf)) { /* empty index... */ ItemPointerSetInvalid(current); so->btso_curbuf = InvalidBuffer; return false; } blkno = BufferGetBlockNumber(buf); page = BufferGetPage(buf); opaque = (BTPageOpaque) PageGetSpecialPointer(page); for (;;) { if (P_ISLEAF(opaque)) break; if (ScanDirectionIsForward(dir)) offnum = P_FIRSTDATAKEY(opaque); else offnum = PageGetMaxOffsetNumber(page); btitem = (BTItem) PageGetItem(page, PageGetItemId(page, offnum)); itup = &(btitem->bti_itup); blkno = ItemPointerGetBlockNumber(&(itup->t_tid)); _bt_relbuf(rel, buf); buf = _bt_getbuf(rel, blkno, BT_READ); page = BufferGetPage(buf); opaque = (BTPageOpaque) PageGetSpecialPointer(page); /* * Race condition: If the child page we just stepped onto was just * split, we need to make sure we're all the way at the right edge * of the tree. See the paper by Lehman and Yao. */ if (ScanDirectionIsBackward(dir) && !P_RIGHTMOST(opaque)) { do { blkno = opaque->btpo_next; _bt_relbuf(rel, buf); buf = _bt_getbuf(rel, blkno, BT_READ); page = BufferGetPage(buf); opaque = (BTPageOpaque) PageGetSpecialPointer(page); } while (!P_RIGHTMOST(opaque)); } } /* okay, we've got the {left,right}-most page in the tree */ maxoff = PageGetMaxOffsetNumber(page); if (ScanDirectionIsForward(dir)) { Assert(P_LEFTMOST(opaque)); start = P_FIRSTDATAKEY(opaque); } else if (ScanDirectionIsBackward(dir)) { Assert(P_RIGHTMOST(opaque)); start = PageGetMaxOffsetNumber(page); if (start < P_FIRSTDATAKEY(opaque)) /* watch out for empty * page */ start = P_FIRSTDATAKEY(opaque); } else { elog(ERROR, "Illegal scan direction %d", dir); start = 0; /* keep compiler quiet */ } ItemPointerSet(current, blkno, start); /* remember which buffer we have pinned */ so->btso_curbuf = buf; /* * Left/rightmost page could be empty due to deletions, if so step * till we find a nonempty page. */ if (start > maxoff) { if (!_bt_step(scan, &buf, dir)) return false; start = ItemPointerGetOffsetNumber(current); page = BufferGetPage(buf); } btitem = (BTItem) PageGetItem(page, PageGetItemId(page, start)); itup = &(btitem->bti_itup); /* see if we picked a winner */ if (_bt_checkkeys(scan, itup, dir, &continuescan)) { /* yes, return it */ scan->xs_ctup.t_self = itup->t_tid; res = true; } else if (continuescan) { /* no, but there might be another one that is */ res = _bt_next(scan, dir); } else { /* no tuples in the index match this scan key */ ItemPointerSetInvalid(current); so->btso_curbuf = InvalidBuffer; _bt_relbuf(rel, buf); res = false; } return res; }