/*------------------------------------------------------------------------- * * visibilitymap.c * bitmap for tracking visibility of heap tuples * * Portions Copyright (c) 1996-2025, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/access/heap/visibilitymap.c * * INTERFACE ROUTINES * visibilitymap_clear - clear bits for one page in the visibility map * visibilitymap_pin - pin a map page for setting a bit * visibilitymap_pin_ok - check whether correct map page is already pinned * visibilitymap_set - set a bit in a previously pinned page * visibilitymap_get_status - get status of bits * visibilitymap_count - count number of bits set in visibility map * visibilitymap_prepare_truncate - * prepare for truncation of the visibility map * * NOTES * * The visibility map is a bitmap with two bits (all-visible and all-frozen) * per heap page. A set all-visible bit means that all tuples on the page are * known visible to all transactions, and therefore the page doesn't need to * be vacuumed. A set all-frozen bit means that all tuples on the page are * completely frozen, and therefore the page doesn't need to be vacuumed even * if whole table scanning vacuum is required (e.g. anti-wraparound vacuum). * The all-frozen bit must be set only when the page is already all-visible. * * The map is conservative in the sense that we make sure that whenever a bit * is set, we know the condition is true, but if a bit is not set, it might or * might not be true. * * Clearing visibility map bits is not separately WAL-logged. The callers * must make sure that whenever a bit is cleared, the bit is cleared on WAL * replay of the updating operation as well. * * When we *set* a visibility map during VACUUM, we must write WAL. This may * seem counterintuitive, since the bit is basically a hint: if it is clear, * it may still be the case that every tuple on the page is visible to all * transactions; we just don't know that for certain. The difficulty is that * there are two bits which are typically set together: the PD_ALL_VISIBLE bit * on the page itself, and the visibility map bit. If a crash occurs after the * visibility map page makes it to disk and before the updated heap page makes * it to disk, redo must set the bit on the heap page. Otherwise, the next * insert, update, or delete on the heap page will fail to realize that the * visibility map bit must be cleared, possibly causing index-only scans to * return wrong answers. * * VACUUM will normally skip pages for which the visibility map bit is set; * such pages can't contain any dead tuples and therefore don't need vacuuming. * * LOCKING * * In heapam.c, whenever a page is modified so that not all tuples on the * page are visible to everyone anymore, the corresponding bit in the * visibility map is cleared. In order to be crash-safe, we need to do this * while still holding a lock on the heap page and in the same critical * section that logs the page modification. However, we don't want to hold * the buffer lock over any I/O that may be required to read in the visibility * map page. To avoid this, we examine the heap page before locking it; * if the page-level PD_ALL_VISIBLE bit is set, we pin the visibility map * bit. Then, we lock the buffer. But this creates a race condition: there * is a possibility that in the time it takes to lock the buffer, the * PD_ALL_VISIBLE bit gets set. If that happens, we have to unlock the * buffer, pin the visibility map page, and relock the buffer. This shouldn't * happen often, because only VACUUM currently sets visibility map bits, * and the race will only occur if VACUUM processes a given page at almost * exactly the same time that someone tries to further modify it. * * To set a bit, you need to hold a lock on the heap page. That prevents * the race condition where VACUUM sees that all tuples on the page are * visible to everyone, but another backend modifies the page before VACUUM * sets the bit in the visibility map. * * When a bit is set, the LSN of the visibility map page is updated to make * sure that the visibility map update doesn't get written to disk before the * WAL record of the changes that made it possible to set the bit is flushed. * But when a bit is cleared, we don't have to do that because it's always * safe to clear a bit in the map from correctness point of view. * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/heapam_xlog.h" #include "access/visibilitymap.h" #include "access/xloginsert.h" #include "access/xlogutils.h" #include "miscadmin.h" #include "port/pg_bitutils.h" #include "storage/bufmgr.h" #include "storage/smgr.h" #include "utils/inval.h" #include "utils/rel.h" /*#define TRACE_VISIBILITYMAP */ /* * Size of the bitmap on each visibility map page, in bytes. There's no * extra headers, so the whole page minus the standard page header is * used for the bitmap. */ #define MAPSIZE (BLCKSZ - MAXALIGN(SizeOfPageHeaderData)) /* Number of heap blocks we can represent in one byte */ #define HEAPBLOCKS_PER_BYTE (BITS_PER_BYTE / BITS_PER_HEAPBLOCK) /* Number of heap blocks we can represent in one visibility map page. */ #define HEAPBLOCKS_PER_PAGE (MAPSIZE * HEAPBLOCKS_PER_BYTE) /* Mapping from heap block number to the right bit in the visibility map */ #define HEAPBLK_TO_MAPBLOCK(x) ((x) / HEAPBLOCKS_PER_PAGE) #define HEAPBLK_TO_MAPBYTE(x) (((x) % HEAPBLOCKS_PER_PAGE) / HEAPBLOCKS_PER_BYTE) #define HEAPBLK_TO_OFFSET(x) (((x) % HEAPBLOCKS_PER_BYTE) * BITS_PER_HEAPBLOCK) /* Masks for counting subsets of bits in the visibility map. */ #define VISIBLE_MASK8 (0x55) /* The lower bit of each bit pair */ #define FROZEN_MASK8 (0xaa) /* The upper bit of each bit pair */ /* prototypes for internal routines */ static Buffer vm_readbuf(Relation rel, BlockNumber blkno, bool extend); static Buffer vm_extend(Relation rel, BlockNumber vm_nblocks); /* * visibilitymap_clear - clear specified bits for one page in visibility map * * You must pass a buffer containing the correct map page to this function. * Call visibilitymap_pin first to pin the right one. This function doesn't do * any I/O. Returns true if any bits have been cleared and false otherwise. */ bool visibilitymap_clear(Relation rel, BlockNumber heapBlk, Buffer vmbuf, uint8 flags) { BlockNumber mapBlock = HEAPBLK_TO_MAPBLOCK(heapBlk); int mapByte = HEAPBLK_TO_MAPBYTE(heapBlk); int mapOffset = HEAPBLK_TO_OFFSET(heapBlk); uint8 mask = flags << mapOffset; char *map; bool cleared = false; /* Must never clear all_visible bit while leaving all_frozen bit set */ Assert(flags & VISIBILITYMAP_VALID_BITS); Assert(flags != VISIBILITYMAP_ALL_VISIBLE); #ifdef TRACE_VISIBILITYMAP elog(DEBUG1, "vm_clear %s %d", RelationGetRelationName(rel), heapBlk); #endif if (!BufferIsValid(vmbuf) || BufferGetBlockNumber(vmbuf) != mapBlock) elog(ERROR, "wrong buffer passed to visibilitymap_clear"); LockBuffer(vmbuf, BUFFER_LOCK_EXCLUSIVE); map = PageGetContents(BufferGetPage(vmbuf)); if (map[mapByte] & mask) { map[mapByte] &= ~mask; MarkBufferDirty(vmbuf); cleared = true; } LockBuffer(vmbuf, BUFFER_LOCK_UNLOCK); return cleared; } /* * visibilitymap_pin - pin a map page for setting a bit * * Setting a bit in the visibility map is a two-phase operation. First, call * visibilitymap_pin, to pin the visibility map page containing the bit for * the heap page. Because that can require I/O to read the map page, you * shouldn't hold a lock on the heap page while doing that. Then, call * visibilitymap_set to actually set the bit. * * On entry, *vmbuf should be InvalidBuffer or a valid buffer returned by * an earlier call to visibilitymap_pin or visibilitymap_get_status on the same * relation. On return, *vmbuf is a valid buffer with the map page containing * the bit for heapBlk. * * If the page doesn't exist in the map file yet, it is extended. */ void visibilitymap_pin(Relation rel, BlockNumber heapBlk, Buffer *vmbuf) { BlockNumber mapBlock = HEAPBLK_TO_MAPBLOCK(heapBlk); /* Reuse the old pinned buffer if possible */ if (BufferIsValid(*vmbuf)) { if (BufferGetBlockNumber(*vmbuf) == mapBlock) return; ReleaseBuffer(*vmbuf); } *vmbuf = vm_readbuf(rel, mapBlock, true); } /* * visibilitymap_pin_ok - do we already have the correct page pinned? * * On entry, vmbuf should be InvalidBuffer or a valid buffer returned by * an earlier call to visibilitymap_pin or visibilitymap_get_status on the same * relation. The return value indicates whether the buffer covers the * given heapBlk. */ bool visibilitymap_pin_ok(BlockNumber heapBlk, Buffer vmbuf) { BlockNumber mapBlock = HEAPBLK_TO_MAPBLOCK(heapBlk); return BufferIsValid(vmbuf) && BufferGetBlockNumber(vmbuf) == mapBlock; } /* * visibilitymap_set - set bit(s) on a previously pinned page * * recptr is the LSN of the XLOG record we're replaying, if we're in recovery, * or InvalidXLogRecPtr in normal running. The VM page LSN is advanced to the * one provided; in normal running, we generate a new XLOG record and set the * page LSN to that value (though the heap page's LSN may *not* be updated; * see below). cutoff_xid is the largest xmin on the page being marked * all-visible; it is needed for Hot Standby, and can be InvalidTransactionId * if the page contains no tuples. It can also be set to InvalidTransactionId * when a page that is already all-visible is being marked all-frozen. * * Caller is expected to set the heap page's PD_ALL_VISIBLE bit before calling * this function. Except in recovery, caller should also pass the heap * buffer. When checksums are enabled and we're not in recovery, we must add * the heap buffer to the WAL chain to protect it from being torn. * * You must pass a buffer containing the correct map page to this function. * Call visibilitymap_pin first to pin the right one. This function doesn't do * any I/O. * * Returns the state of the page's VM bits before setting flags. */ uint8 visibilitymap_set(Relation rel, BlockNumber heapBlk, Buffer heapBuf, XLogRecPtr recptr, Buffer vmBuf, TransactionId cutoff_xid, uint8 flags) { BlockNumber mapBlock = HEAPBLK_TO_MAPBLOCK(heapBlk); uint32 mapByte = HEAPBLK_TO_MAPBYTE(heapBlk); uint8 mapOffset = HEAPBLK_TO_OFFSET(heapBlk); Page page; uint8 *map; uint8 status; #ifdef TRACE_VISIBILITYMAP elog(DEBUG1, "vm_set %s %d", RelationGetRelationName(rel), heapBlk); #endif Assert(InRecovery || XLogRecPtrIsInvalid(recptr)); Assert(InRecovery || PageIsAllVisible((Page) BufferGetPage(heapBuf))); Assert((flags & VISIBILITYMAP_VALID_BITS) == flags); /* Must never set all_frozen bit without also setting all_visible bit */ Assert(flags != VISIBILITYMAP_ALL_FROZEN); /* Check that we have the right heap page pinned, if present */ if (BufferIsValid(heapBuf) && BufferGetBlockNumber(heapBuf) != heapBlk) elog(ERROR, "wrong heap buffer passed to visibilitymap_set"); /* Check that we have the right VM page pinned */ if (!BufferIsValid(vmBuf) || BufferGetBlockNumber(vmBuf) != mapBlock) elog(ERROR, "wrong VM buffer passed to visibilitymap_set"); page = BufferGetPage(vmBuf); map = (uint8 *) PageGetContents(page); LockBuffer(vmBuf, BUFFER_LOCK_EXCLUSIVE); status = (map[mapByte] >> mapOffset) & VISIBILITYMAP_VALID_BITS; if (flags != status) { START_CRIT_SECTION(); map[mapByte] |= (flags << mapOffset); MarkBufferDirty(vmBuf); if (RelationNeedsWAL(rel)) { if (XLogRecPtrIsInvalid(recptr)) { Assert(!InRecovery); recptr = log_heap_visible(rel, heapBuf, vmBuf, cutoff_xid, flags); /* * If data checksums are enabled (or wal_log_hints=on), we * need to protect the heap page from being torn. * * If not, then we must *not* update the heap page's LSN. In * this case, the FPI for the heap page was omitted from the * WAL record inserted above, so it would be incorrect to * update the heap page's LSN. */ if (XLogHintBitIsNeeded()) { Page heapPage = BufferGetPage(heapBuf); PageSetLSN(heapPage, recptr); } } PageSetLSN(page, recptr); } END_CRIT_SECTION(); } LockBuffer(vmBuf, BUFFER_LOCK_UNLOCK); return status; } /* * visibilitymap_get_status - get status of bits * * Are all tuples on heapBlk visible to all or are marked frozen, according * to the visibility map? * * On entry, *vmbuf should be InvalidBuffer or a valid buffer returned by an * earlier call to visibilitymap_pin or visibilitymap_get_status on the same * relation. On return, *vmbuf is a valid buffer with the map page containing * the bit for heapBlk, or InvalidBuffer. The caller is responsible for * releasing *vmbuf after it's done testing and setting bits. * * NOTE: This function is typically called without a lock on the heap page, * so somebody else could change the bit just after we look at it. In fact, * since we don't lock the visibility map page either, it's even possible that * someone else could have changed the bit just before we look at it, but yet * we might see the old value. It is the caller's responsibility to deal with * all concurrency issues! */ uint8 visibilitymap_get_status(Relation rel, BlockNumber heapBlk, Buffer *vmbuf) { BlockNumber mapBlock = HEAPBLK_TO_MAPBLOCK(heapBlk); uint32 mapByte = HEAPBLK_TO_MAPBYTE(heapBlk); uint8 mapOffset = HEAPBLK_TO_OFFSET(heapBlk); char *map; uint8 result; #ifdef TRACE_VISIBILITYMAP elog(DEBUG1, "vm_get_status %s %d", RelationGetRelationName(rel), heapBlk); #endif /* Reuse the old pinned buffer if possible */ if (BufferIsValid(*vmbuf)) { if (BufferGetBlockNumber(*vmbuf) != mapBlock) { ReleaseBuffer(*vmbuf); *vmbuf = InvalidBuffer; } } if (!BufferIsValid(*vmbuf)) { *vmbuf = vm_readbuf(rel, mapBlock, false); if (!BufferIsValid(*vmbuf)) return false; } map = PageGetContents(BufferGetPage(*vmbuf)); /* * A single byte read is atomic. There could be memory-ordering effects * here, but for performance reasons we make it the caller's job to worry * about that. */ result = ((map[mapByte] >> mapOffset) & VISIBILITYMAP_VALID_BITS); return result; } /* * visibilitymap_count - count number of bits set in visibility map * * Note: we ignore the possibility of race conditions when the table is being * extended concurrently with the call. New pages added to the table aren't * going to be marked all-visible or all-frozen, so they won't affect the result. */ void visibilitymap_count(Relation rel, BlockNumber *all_visible, BlockNumber *all_frozen) { BlockNumber mapBlock; BlockNumber nvisible = 0; BlockNumber nfrozen = 0; /* all_visible must be specified */ Assert(all_visible); for (mapBlock = 0;; mapBlock++) { Buffer mapBuffer; uint64 *map; /* * Read till we fall off the end of the map. We assume that any extra * bytes in the last page are zeroed, so we don't bother excluding * them from the count. */ mapBuffer = vm_readbuf(rel, mapBlock, false); if (!BufferIsValid(mapBuffer)) break; /* * We choose not to lock the page, since the result is going to be * immediately stale anyway if anyone is concurrently setting or * clearing bits, and we only really need an approximate value. */ map = (uint64 *) PageGetContents(BufferGetPage(mapBuffer)); nvisible += pg_popcount_masked((const char *) map, MAPSIZE, VISIBLE_MASK8); if (all_frozen) nfrozen += pg_popcount_masked((const char *) map, MAPSIZE, FROZEN_MASK8); ReleaseBuffer(mapBuffer); } *all_visible = nvisible; if (all_frozen) *all_frozen = nfrozen; } /* * visibilitymap_prepare_truncate - * prepare for truncation of the visibility map * * nheapblocks is the new size of the heap. * * Return the number of blocks of new visibility map. * If it's InvalidBlockNumber, there is nothing to truncate; * otherwise the caller is responsible for calling smgrtruncate() * to truncate the visibility map pages. */ BlockNumber visibilitymap_prepare_truncate(Relation rel, BlockNumber nheapblocks) { BlockNumber newnblocks; /* last remaining block, byte, and bit */ BlockNumber truncBlock = HEAPBLK_TO_MAPBLOCK(nheapblocks); uint32 truncByte = HEAPBLK_TO_MAPBYTE(nheapblocks); uint8 truncOffset = HEAPBLK_TO_OFFSET(nheapblocks); #ifdef TRACE_VISIBILITYMAP elog(DEBUG1, "vm_truncate %s %d", RelationGetRelationName(rel), nheapblocks); #endif /* * If no visibility map has been created yet for this relation, there's * nothing to truncate. */ if (!smgrexists(RelationGetSmgr(rel), VISIBILITYMAP_FORKNUM)) return InvalidBlockNumber; /* * Unless the new size is exactly at a visibility map page boundary, the * tail bits in the last remaining map page, representing truncated heap * blocks, need to be cleared. This is not only tidy, but also necessary * because we don't get a chance to clear the bits if the heap is extended * again. */ if (truncByte != 0 || truncOffset != 0) { Buffer mapBuffer; Page page; char *map; newnblocks = truncBlock + 1; mapBuffer = vm_readbuf(rel, truncBlock, false); if (!BufferIsValid(mapBuffer)) { /* nothing to do, the file was already smaller */ return InvalidBlockNumber; } page = BufferGetPage(mapBuffer); map = PageGetContents(page); LockBuffer(mapBuffer, BUFFER_LOCK_EXCLUSIVE); /* NO EREPORT(ERROR) from here till changes are logged */ START_CRIT_SECTION(); /* Clear out the unwanted bytes. */ MemSet(&map[truncByte + 1], 0, MAPSIZE - (truncByte + 1)); /*---- * Mask out the unwanted bits of the last remaining byte. * * ((1 << 0) - 1) = 00000000 * ((1 << 1) - 1) = 00000001 * ... * ((1 << 6) - 1) = 00111111 * ((1 << 7) - 1) = 01111111 *---- */ map[truncByte] &= (1 << truncOffset) - 1; /* * Truncation of a relation is WAL-logged at a higher-level, and we * will be called at WAL replay. But if checksums are enabled, we need * to still write a WAL record to protect against a torn page, if the * page is flushed to disk before the truncation WAL record. We cannot * use MarkBufferDirtyHint here, because that will not dirty the page * during recovery. */ MarkBufferDirty(mapBuffer); if (!InRecovery && RelationNeedsWAL(rel) && XLogHintBitIsNeeded()) log_newpage_buffer(mapBuffer, false); END_CRIT_SECTION(); UnlockReleaseBuffer(mapBuffer); } else newnblocks = truncBlock; if (smgrnblocks(RelationGetSmgr(rel), VISIBILITYMAP_FORKNUM) <= newnblocks) { /* nothing to do, the file was already smaller than requested size */ return InvalidBlockNumber; } return newnblocks; } /* * Read a visibility map page. * * If the page doesn't exist, InvalidBuffer is returned, or if 'extend' is * true, the visibility map file is extended. */ static Buffer vm_readbuf(Relation rel, BlockNumber blkno, bool extend) { Buffer buf; SMgrRelation reln; /* * Caution: re-using this smgr pointer could fail if the relcache entry * gets closed. It's safe as long as we only do smgr-level operations * between here and the last use of the pointer. */ reln = RelationGetSmgr(rel); /* * If we haven't cached the size of the visibility map fork yet, check it * first. */ if (reln->smgr_cached_nblocks[VISIBILITYMAP_FORKNUM] == InvalidBlockNumber) { if (smgrexists(reln, VISIBILITYMAP_FORKNUM)) smgrnblocks(reln, VISIBILITYMAP_FORKNUM); else reln->smgr_cached_nblocks[VISIBILITYMAP_FORKNUM] = 0; } /* * For reading we use ZERO_ON_ERROR mode, and initialize the page if * necessary. It's always safe to clear bits, so it's better to clear * corrupt pages than error out. * * We use the same path below to initialize pages when extending the * relation, as a concurrent extension can end up with vm_extend() * returning an already-initialized page. */ if (blkno >= reln->smgr_cached_nblocks[VISIBILITYMAP_FORKNUM]) { if (extend) buf = vm_extend(rel, blkno + 1); else return InvalidBuffer; } else buf = ReadBufferExtended(rel, VISIBILITYMAP_FORKNUM, blkno, RBM_ZERO_ON_ERROR, NULL); /* * Initializing the page when needed is trickier than it looks, because of * the possibility of multiple backends doing this concurrently, and our * desire to not uselessly take the buffer lock in the normal path where * the page is OK. We must take the lock to initialize the page, so * recheck page newness after we have the lock, in case someone else * already did it. Also, because we initially check PageIsNew with no * lock, it's possible to fall through and return the buffer while someone * else is still initializing the page (i.e., we might see pd_upper as set * but other page header fields are still zeroes). This is harmless for * callers that will take a buffer lock themselves, but some callers * inspect the page without any lock at all. The latter is OK only so * long as it doesn't depend on the page header having correct contents. * Current usage is safe because PageGetContents() does not require that. */ if (PageIsNew(BufferGetPage(buf))) { LockBuffer(buf, BUFFER_LOCK_EXCLUSIVE); if (PageIsNew(BufferGetPage(buf))) PageInit(BufferGetPage(buf), BLCKSZ, 0); LockBuffer(buf, BUFFER_LOCK_UNLOCK); } return buf; } /* * Ensure that the visibility map fork is at least vm_nblocks long, extending * it if necessary with zeroed pages. */ static Buffer vm_extend(Relation rel, BlockNumber vm_nblocks) { Buffer buf; buf = ExtendBufferedRelTo(BMR_REL(rel), VISIBILITYMAP_FORKNUM, NULL, EB_CREATE_FORK_IF_NEEDED | EB_CLEAR_SIZE_CACHE, vm_nblocks, RBM_ZERO_ON_ERROR); /* * Send a shared-inval message to force other backends to close any smgr * references they may have for this rel, which we are about to change. * This is a useful optimization because it means that backends don't have * to keep checking for creation or extension of the file, which happens * infrequently. */ CacheInvalidateSmgr(RelationGetSmgr(rel)->smgr_rlocator); return buf; }