/*------------------------------------------------------------------------- * * bufpage.c * POSTGRES standard buffer page code. * * Portions Copyright (c) 1996-2001, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/storage/page/bufpage.c,v 1.37 2001/03/22 03:59:47 momjian Exp $ * *------------------------------------------------------------------------- */ #include #include #include "postgres.h" #include "storage/bufpage.h" static void PageIndexTupleDeleteAdjustLinePointers(PageHeader phdr, char *location, Size size); /* ---------------------------------------------------------------- * Page support functions * ---------------------------------------------------------------- */ /* * PageInit * Initializes the contents of a page. */ void PageInit(Page page, Size pageSize, Size specialSize) { PageHeader p = (PageHeader) page; Assert(pageSize == BLCKSZ); Assert(pageSize > specialSize + sizeof(PageHeaderData) - sizeof(ItemIdData)); specialSize = MAXALIGN(specialSize); p->pd_lower = sizeof(PageHeaderData) - sizeof(ItemIdData); p->pd_upper = pageSize - specialSize; p->pd_special = pageSize - specialSize; PageSetPageSize(page, pageSize); p->pd_lsn.xlogid = p->pd_lsn.xrecoff = 0; p->pd_sui = 0; } /* * WAL needs in zero-ed page data content */ void PageZero(Page page) { MemSet((char *) page + ((PageHeader) page)->pd_lower, 0, ((PageHeader) page)->pd_special - ((PageHeader) page)->pd_lower); } /* ---------------- * PageAddItem * * Add an item to a page. Return value is offset at which it was * inserted, or InvalidOffsetNumber if there's not room to insert. * * If offsetNumber is valid and <= current max offset in the page, * insert item into the array at that position by shuffling ItemId's * down to make room. * If offsetNumber is not valid, then assign one by finding the first * one that is both unused and deallocated. * * !!! ELOG(ERROR) IS DISALLOWED HERE !!! * * ---------------- */ OffsetNumber PageAddItem(Page page, Item item, Size size, OffsetNumber offsetNumber, ItemIdFlags flags) { int i; Size alignedSize; Offset lower; Offset upper; ItemId itemId; OffsetNumber limit; bool needshuffle = false; bool overwritemode = flags & OverwritePageMode; flags &= ~OverwritePageMode; /* * Find first unallocated offsetNumber */ limit = OffsetNumberNext(PageGetMaxOffsetNumber(page)); /* was offsetNumber passed in? */ if (OffsetNumberIsValid(offsetNumber)) { if (overwritemode) { if (offsetNumber > limit) { elog(NOTICE, "PageAddItem: tried overwrite after maxoff"); return InvalidOffsetNumber; } if (offsetNumber < limit) { itemId = &((PageHeader) page)->pd_linp[offsetNumber - 1]; if (((*itemId).lp_flags & LP_USED) || ((*itemId).lp_len != 0)) { elog(NOTICE, "PageAddItem: tried overwrite of used ItemId"); return InvalidOffsetNumber; } } } else { /* * Don't actually do the shuffle till we've checked free * space! */ needshuffle = true; /* need to increase "lower" */ } } else { /* offsetNumber was not passed in, so find one */ /* look for "recyclable" (unused & deallocated) ItemId */ for (offsetNumber = 1; offsetNumber < limit; offsetNumber++) { itemId = &((PageHeader) page)->pd_linp[offsetNumber - 1]; if ((((*itemId).lp_flags & LP_USED) == 0) && ((*itemId).lp_len == 0)) break; } } /* * Compute new lower and upper pointers for page, see if it'll fit */ if (offsetNumber > limit) lower = (Offset) (((char *) (&((PageHeader) page)->pd_linp[offsetNumber])) - ((char *) page)); else if (offsetNumber == limit || needshuffle) lower = ((PageHeader) page)->pd_lower + sizeof(ItemIdData); else lower = ((PageHeader) page)->pd_lower; alignedSize = MAXALIGN(size); upper = ((PageHeader) page)->pd_upper - alignedSize; if (lower > upper) return InvalidOffsetNumber; /* * OK to insert the item. First, shuffle the existing pointers if * needed. */ if (needshuffle) { /* shuffle ItemId's (Do the PageManager Shuffle...) */ for (i = (limit - 1); i >= offsetNumber; i--) { ItemId fromitemId, toitemId; fromitemId = &((PageHeader) page)->pd_linp[i - 1]; toitemId = &((PageHeader) page)->pd_linp[i]; *toitemId = *fromitemId; } } itemId = &((PageHeader) page)->pd_linp[offsetNumber - 1]; (*itemId).lp_off = upper; (*itemId).lp_len = size; (*itemId).lp_flags = flags; memmove((char *) page + upper, item, size); ((PageHeader) page)->pd_lower = lower; ((PageHeader) page)->pd_upper = upper; return offsetNumber; } /* * PageGetTempPage * Get a temporary page in local memory for special processing */ Page PageGetTempPage(Page page, Size specialSize) { Size pageSize; Size size; Page temp; PageHeader thdr; pageSize = PageGetPageSize(page); temp = (Page) palloc(pageSize); thdr = (PageHeader) temp; /* copy old page in */ memmove(temp, page, pageSize); /* clear out the middle */ size = (pageSize - sizeof(PageHeaderData)) + sizeof(ItemIdData); size -= MAXALIGN(specialSize); MemSet((char *) &(thdr->pd_linp[0]), 0, size); /* set high, low water marks */ thdr->pd_lower = sizeof(PageHeaderData) - sizeof(ItemIdData); thdr->pd_upper = pageSize - MAXALIGN(specialSize); return temp; } /* * PageRestoreTempPage * Copy temporary page back to permanent page after special processing * and release the temporary page. */ void PageRestoreTempPage(Page tempPage, Page oldPage) { Size pageSize; pageSize = PageGetPageSize(tempPage); memmove((char *) oldPage, (char *) tempPage, pageSize); pfree(tempPage); } /* ---------------- * itemid stuff for PageRepairFragmentation * ---------------- */ struct itemIdSortData { int offsetindex; /* linp array index */ ItemIdData itemiddata; }; static int itemidcompare(const void *itemidp1, const void *itemidp2) { if (((struct itemIdSortData *) itemidp1)->itemiddata.lp_off == ((struct itemIdSortData *) itemidp2)->itemiddata.lp_off) return 0; else if (((struct itemIdSortData *) itemidp1)->itemiddata.lp_off < ((struct itemIdSortData *) itemidp2)->itemiddata.lp_off) return 1; else return -1; } /* * PageRepairFragmentation * * Frees fragmented space on a page. * It doesn't remove unused line pointers! Please don't change this. * This routine is usable for heap pages only. * */ int PageRepairFragmentation(Page page, OffsetNumber *unused) { int i; struct itemIdSortData *itemidbase, *itemidptr; ItemId lp; int nline, nused; Offset upper; Size alignedSize; nline = (int16) PageGetMaxOffsetNumber(page); nused = 0; for (i = 0; i < nline; i++) { lp = ((PageHeader) page)->pd_linp + i; if ((*lp).lp_flags & LP_DELETE) /* marked for deletion */ (*lp).lp_flags &= ~(LP_USED | LP_DELETE); if ((*lp).lp_flags & LP_USED) nused++; else if (unused) unused[i - nused] = (OffsetNumber) i; } if (nused == 0) { for (i = 0; i < nline; i++) { lp = ((PageHeader) page)->pd_linp + i; if ((*lp).lp_len > 0) /* unused, but allocated */ (*lp).lp_len = 0; /* indicate unused & deallocated */ } ((PageHeader) page)->pd_upper = ((PageHeader) page)->pd_special; } else { /* nused != 0 */ itemidbase = (struct itemIdSortData *) palloc(sizeof(struct itemIdSortData) * nused); MemSet((char *) itemidbase, 0, sizeof(struct itemIdSortData) * nused); itemidptr = itemidbase; for (i = 0; i < nline; i++) { lp = ((PageHeader) page)->pd_linp + i; if ((*lp).lp_flags & LP_USED) { itemidptr->offsetindex = i; itemidptr->itemiddata = *lp; itemidptr++; } else { if ((*lp).lp_len > 0) /* unused, but allocated */ (*lp).lp_len = 0; /* indicate unused & deallocated */ } } /* sort itemIdSortData array... */ qsort((char *) itemidbase, nused, sizeof(struct itemIdSortData), itemidcompare); /* compactify page */ ((PageHeader) page)->pd_upper = ((PageHeader) page)->pd_special; for (i = 0, itemidptr = itemidbase; i < nused; i++, itemidptr++) { lp = ((PageHeader) page)->pd_linp + itemidptr->offsetindex; alignedSize = MAXALIGN((*lp).lp_len); upper = ((PageHeader) page)->pd_upper - alignedSize; memmove((char *) page + upper, (char *) page + (*lp).lp_off, (*lp).lp_len); (*lp).lp_off = upper; ((PageHeader) page)->pd_upper = upper; } pfree(itemidbase); } return (nline - nused); } /* * PageGetFreeSpace * Returns the size of the free (allocatable) space on a page. */ Size PageGetFreeSpace(Page page) { Size space; space = ((PageHeader) page)->pd_upper - ((PageHeader) page)->pd_lower; if (space < sizeof(ItemIdData)) return 0; space -= sizeof(ItemIdData);/* XXX not always true */ return space; } /* * PageRepairFragmentation un-useful for index page cleanup because * of it doesn't remove line pointers. This routine could be more * effective but ... no time -:) */ void IndexPageCleanup(Buffer buffer) { Page page = (Page) BufferGetPage(buffer); ItemId lp; OffsetNumber maxoff; OffsetNumber i; maxoff = PageGetMaxOffsetNumber(page); for (i = 0; i < maxoff; i++) { lp = ((PageHeader) page)->pd_linp + i; if ((*lp).lp_flags & LP_DELETE) /* marked for deletion */ { PageIndexTupleDelete(page, i + 1); maxoff--; } } } /* *---------------------------------------------------------------- * PageIndexTupleDelete *---------------------------------------------------------------- * * This routine does the work of removing a tuple from an index page. */ void PageIndexTupleDelete(Page page, OffsetNumber offnum) { PageHeader phdr; char *addr; ItemId tup; Size size; char *locn; int nbytes; int offidx; phdr = (PageHeader) page; /* change offset number to offset index */ offidx = offnum - 1; tup = PageGetItemId(page, offnum); size = ItemIdGetLength(tup); size = MAXALIGN(size); /* location of deleted tuple data */ locn = (char *) (page + ItemIdGetOffset(tup)); /* * First, we want to get rid of the pd_linp entry for the index tuple. * We copy all subsequent linp's back one slot in the array. */ nbytes = phdr->pd_lower - ((char *) &phdr->pd_linp[offidx + 1] - (char *) phdr); memmove((char *) &(phdr->pd_linp[offidx]), (char *) &(phdr->pd_linp[offidx + 1]), nbytes); /* * Now move everything between the old upper bound (beginning of tuple * space) and the beginning of the deleted tuple forward, so that * space in the middle of the page is left free. If we've just * deleted the tuple at the beginning of tuple space, then there's no * need to do the copy (and bcopy on some architectures SEGV's if * asked to move zero bytes). */ /* beginning of tuple space */ addr = (char *) (page + phdr->pd_upper); if (locn != addr) memmove(addr + size, addr, (int) (locn - addr)); /* adjust free space boundary pointers */ phdr->pd_upper += size; phdr->pd_lower -= sizeof(ItemIdData); /* finally, we need to adjust the linp entries that remain */ if (!PageIsEmpty(page)) PageIndexTupleDeleteAdjustLinePointers(phdr, locn, size); } /* *---------------------------------------------------------------- * PageIndexTupleDeleteAdjustLinePointers *---------------------------------------------------------------- * * Once the line pointers and tuple data have been shifted around * on the page, we need to go down the line pointer vector and * adjust pointers to reflect new locations. Anything that used * to be before the deleted tuple's data was moved forward by the * size of the deleted tuple. * * This routine does the work of adjusting the line pointers. * Location is where the tuple data used to lie; size is how * much space it occupied. We assume that size has been aligned * as required by the time we get here. * * This routine should never be called on an empty page. */ static void PageIndexTupleDeleteAdjustLinePointers(PageHeader phdr, char *location, Size size) { int i; unsigned offset; /* location is an index into the page... */ offset = (unsigned) (location - (char *) phdr); for (i = PageGetMaxOffsetNumber((Page) phdr) - 1; i >= 0; i--) { if (phdr->pd_linp[i].lp_off <= offset) phdr->pd_linp[i].lp_off += size; } }