/* * visibilitymap_set - set a bit 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 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. 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. * * 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. */ void visibilitymap_set(Relation rel, BlockNumber heapBlk, Buffer heapBuf, XLogRecPtr recptr, Buffer vmBuf, TransactionId cutoff_xid) { BlockNumber mapBlock = HEAPBLK_TO_MAPBLOCK(heapBlk); uint32 mapByte = HEAPBLK_TO_MAPBYTE(heapBlk); uint8 mapBit = HEAPBLK_TO_MAPBIT(heapBlk); Page page; char *map; #ifdef TRACE_VISIBILITYMAP elog(DEBUG1, "vm_set %s %d", RelationGetRelationName(rel), heapBlk); #endif Assert(InRecovery || XLogRecPtrIsInvalid(recptr)); Assert(InRecovery || BufferIsValid(heapBuf)); /* 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 = PageGetContents(page); LockBuffer(vmBuf, BUFFER_LOCK_EXCLUSIVE); if (!(map[mapByte] & (1 << mapBit))) { START_CRIT_SECTION(); map[mapByte] |= (1 << mapBit); MarkBufferDirty(vmBuf); if (RelationNeedsWAL(rel)) { if (XLogRecPtrIsInvalid(recptr)) { Assert(!InRecovery); recptr = log_heap_visible(rel->rd_node, heapBuf, vmBuf, cutoff_xid); /* * If data checksums are enabled (or wal_log_hints=on), we * need to protect the heap page from being torn. */ if (XLogHintBitIsNeeded()) { Page heapPage = BufferGetPage(heapBuf); /* caller is expected to set PD_ALL_VISIBLE first */ Assert(PageIsAllVisible(heapPage)); PageSetLSN(heapPage, recptr); } } PageSetLSN(page, recptr); } END_CRIT_SECTION(); } LockBuffer(vmBuf, BUFFER_LOCK_UNLOCK); }
/* * FreeSpaceMapTruncateRel - adjust for truncation of a relation. * * The caller must hold AccessExclusiveLock on the relation, to ensure that * other backends receive the smgr invalidation event that this function sends * before they access the FSM again. * * nblocks is the new size of the heap. */ void FreeSpaceMapTruncateRel(Relation rel, BlockNumber nblocks) { BlockNumber new_nfsmblocks; FSMAddress first_removed_address; uint16 first_removed_slot; Buffer buf; RelationOpenSmgr(rel); /* * If no FSM has been created yet for this relation, there's nothing to * truncate. */ if (!smgrexists(rel->rd_smgr, FSM_FORKNUM)) return; /* Get the location in the FSM of the first removed heap block */ first_removed_address = fsm_get_location(nblocks, &first_removed_slot); /* * Zero out the tail of the last remaining FSM page. If the slot * representing the first removed heap block is at a page boundary, as the * first slot on the FSM page that first_removed_address points to, we can * just truncate that page altogether. */ if (first_removed_slot > 0) { buf = fsm_readbuf(rel, first_removed_address, false); if (!BufferIsValid(buf)) return; /* nothing to do; the FSM was already smaller */ LockBuffer(buf, BUFFER_LOCK_EXCLUSIVE); /* NO EREPORT(ERROR) from here till changes are logged */ START_CRIT_SECTION(); fsm_truncate_avail(BufferGetPage(buf), first_removed_slot); /* * 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(buf); if (!InRecovery && RelationNeedsWAL(rel) && XLogHintBitIsNeeded()) log_newpage_buffer(buf, false); END_CRIT_SECTION(); UnlockReleaseBuffer(buf); new_nfsmblocks = fsm_logical_to_physical(first_removed_address) + 1; } else { new_nfsmblocks = fsm_logical_to_physical(first_removed_address); if (smgrnblocks(rel->rd_smgr, FSM_FORKNUM) <= new_nfsmblocks) return; /* nothing to do; the FSM was already smaller */ } /* Truncate the unused FSM pages, and send smgr inval message */ smgrtruncate(rel->rd_smgr, FSM_FORKNUM, new_nfsmblocks); /* * We might as well update the local smgr_fsm_nblocks setting. * smgrtruncate sent an smgr cache inval message, which will cause other * backends to invalidate their copy of smgr_fsm_nblocks, and this one too * at the next command boundary. But this ensures it isn't outright wrong * until then. */ if (rel->rd_smgr) rel->rd_smgr->smgr_fsm_nblocks = new_nfsmblocks; /* * Update upper-level FSM pages to account for the truncation. This is * important because the just-truncated pages were likely marked as * all-free, and would be preferentially selected. */ FreeSpaceMapVacuumRange(rel, nblocks, InvalidBlockNumber); }