/*------------------------------------------------------------------------- * * pruneheap.c * heap page pruning and HOT-chain management code * * Portions Copyright (c) 1996-2025, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/access/heap/pruneheap.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/heapam.h" #include "access/heapam_xlog.h" #include "access/htup_details.h" #include "access/multixact.h" #include "access/transam.h" #include "access/xlog.h" #include "access/xloginsert.h" #include "commands/vacuum.h" #include "executor/instrument.h" #include "miscadmin.h" #include "pgstat.h" #include "storage/bufmgr.h" #include "utils/rel.h" #include "utils/snapmgr.h" /* Working data for heap_page_prune_and_freeze() and subroutines */ typedef struct { /*------------------------------------------------------- * Arguments passed to heap_page_prune_and_freeze() *------------------------------------------------------- */ /* tuple visibility test, initialized for the relation */ GlobalVisState *vistest; /* whether or not dead items can be set LP_UNUSED during pruning */ bool mark_unused_now; /* whether to attempt freezing tuples */ bool freeze; struct VacuumCutoffs *cutoffs; /*------------------------------------------------------- * Fields describing what to do to the page *------------------------------------------------------- */ TransactionId new_prune_xid; /* new prune hint value */ TransactionId latest_xid_removed; int nredirected; /* numbers of entries in arrays below */ int ndead; int nunused; int nfrozen; /* arrays that accumulate indexes of items to be changed */ OffsetNumber redirected[MaxHeapTuplesPerPage * 2]; OffsetNumber nowdead[MaxHeapTuplesPerPage]; OffsetNumber nowunused[MaxHeapTuplesPerPage]; HeapTupleFreeze frozen[MaxHeapTuplesPerPage]; /*------------------------------------------------------- * Working state for HOT chain processing *------------------------------------------------------- */ /* * 'root_items' contains offsets of all LP_REDIRECT line pointers and * normal non-HOT tuples. They can be stand-alone items or the first item * in a HOT chain. 'heaponly_items' contains heap-only tuples which can * only be removed as part of a HOT chain. */ int nroot_items; OffsetNumber root_items[MaxHeapTuplesPerPage]; int nheaponly_items; OffsetNumber heaponly_items[MaxHeapTuplesPerPage]; /* * processed[offnum] is true if item at offnum has been processed. * * This needs to be MaxHeapTuplesPerPage + 1 long as FirstOffsetNumber is * 1. Otherwise every access would need to subtract 1. */ bool processed[MaxHeapTuplesPerPage + 1]; /* * Tuple visibility is only computed once for each tuple, for correctness * and efficiency reasons; see comment in heap_page_prune_and_freeze() for * details. This is of type int8[], instead of HTSV_Result[], so we can * use -1 to indicate no visibility has been computed, e.g. for LP_DEAD * items. * * This needs to be MaxHeapTuplesPerPage + 1 long as FirstOffsetNumber is * 1. Otherwise every access would need to subtract 1. */ int8 htsv[MaxHeapTuplesPerPage + 1]; /* * Freezing-related state. */ HeapPageFreeze pagefrz; /*------------------------------------------------------- * Information about what was done * * These fields are not used by pruning itself for the most part, but are * used to collect information about what was pruned and what state the * page is in after pruning, for the benefit of the caller. They are * copied to the caller's PruneFreezeResult at the end. * ------------------------------------------------------- */ int ndeleted; /* Number of tuples deleted from the page */ /* Number of live and recently dead tuples, after pruning */ int live_tuples; int recently_dead_tuples; /* Whether or not the page makes rel truncation unsafe */ bool hastup; /* * LP_DEAD items on the page after pruning. Includes existing LP_DEAD * items */ int lpdead_items; /* number of items in the array */ OffsetNumber *deadoffsets; /* points directly to presult->deadoffsets */ /* * all_visible and all_frozen indicate if the all-visible and all-frozen * bits in the visibility map can be set for this page after pruning. * * visibility_cutoff_xid is the newest xmin of live tuples on the page. * The caller can use it as the conflict horizon, when setting the VM * bits. It is only valid if we froze some tuples, and all_frozen is * true. * * NOTE: all_visible and all_frozen don't include LP_DEAD items. That's * convenient for heap_page_prune_and_freeze(), to use them to decide * whether to freeze the page or not. The all_visible and all_frozen * values returned to the caller are adjusted to include LP_DEAD items at * the end. * * all_frozen should only be considered valid if all_visible is also set; * we don't bother to clear the all_frozen flag every time we clear the * all_visible flag. */ bool all_visible; bool all_frozen; TransactionId visibility_cutoff_xid; } PruneState; /* Local functions */ static HTSV_Result heap_prune_satisfies_vacuum(PruneState *prstate, HeapTuple tup, Buffer buffer); static inline HTSV_Result htsv_get_valid_status(int status); static void heap_prune_chain(Page page, BlockNumber blockno, OffsetNumber maxoff, OffsetNumber rootoffnum, PruneState *prstate); static void heap_prune_record_prunable(PruneState *prstate, TransactionId xid); static void heap_prune_record_redirect(PruneState *prstate, OffsetNumber offnum, OffsetNumber rdoffnum, bool was_normal); static void heap_prune_record_dead(PruneState *prstate, OffsetNumber offnum, bool was_normal); static void heap_prune_record_dead_or_unused(PruneState *prstate, OffsetNumber offnum, bool was_normal); static void heap_prune_record_unused(PruneState *prstate, OffsetNumber offnum, bool was_normal); static void heap_prune_record_unchanged_lp_unused(Page page, PruneState *prstate, OffsetNumber offnum); static void heap_prune_record_unchanged_lp_normal(Page page, PruneState *prstate, OffsetNumber offnum); static void heap_prune_record_unchanged_lp_dead(Page page, PruneState *prstate, OffsetNumber offnum); static void heap_prune_record_unchanged_lp_redirect(PruneState *prstate, OffsetNumber offnum); static void page_verify_redirects(Page page); /* * Optionally prune and repair fragmentation in the specified page. * * This is an opportunistic function. It will perform housekeeping * only if the page heuristically looks like a candidate for pruning and we * can acquire buffer cleanup lock without blocking. * * Note: this is called quite often. It's important that it fall out quickly * if there's not any use in pruning. * * Caller must have pin on the buffer, and must *not* have a lock on it. */ void heap_page_prune_opt(Relation relation, Buffer buffer) { Page page = BufferGetPage(buffer); TransactionId prune_xid; GlobalVisState *vistest; Size minfree; /* * We can't write WAL in recovery mode, so there's no point trying to * clean the page. The primary will likely issue a cleaning WAL record * soon anyway, so this is no particular loss. */ if (RecoveryInProgress()) return; /* * First check whether there's any chance there's something to prune, * determining the appropriate horizon is a waste if there's no prune_xid * (i.e. no updates/deletes left potentially dead tuples around). */ prune_xid = ((PageHeader) page)->pd_prune_xid; if (!TransactionIdIsValid(prune_xid)) return; /* * Check whether prune_xid indicates that there may be dead rows that can * be cleaned up. */ vistest = GlobalVisTestFor(relation); if (!GlobalVisTestIsRemovableXid(vistest, prune_xid)) return; /* * We prune when a previous UPDATE failed to find enough space on the page * for a new tuple version, or when free space falls below the relation's * fill-factor target (but not less than 10%). * * Checking free space here is questionable since we aren't holding any * lock on the buffer; in the worst case we could get a bogus answer. It's * unlikely to be *seriously* wrong, though, since reading either pd_lower * or pd_upper is probably atomic. Avoiding taking a lock seems more * important than sometimes getting a wrong answer in what is after all * just a heuristic estimate. */ minfree = RelationGetTargetPageFreeSpace(relation, HEAP_DEFAULT_FILLFACTOR); minfree = Max(minfree, BLCKSZ / 10); if (PageIsFull(page) || PageGetHeapFreeSpace(page) < minfree) { /* OK, try to get exclusive buffer lock */ if (!ConditionalLockBufferForCleanup(buffer)) return; /* * Now that we have buffer lock, get accurate information about the * page's free space, and recheck the heuristic about whether to * prune. */ if (PageIsFull(page) || PageGetHeapFreeSpace(page) < minfree) { OffsetNumber dummy_off_loc; PruneFreezeResult presult; /* * For now, pass mark_unused_now as false regardless of whether or * not the relation has indexes, since we cannot safely determine * that during on-access pruning with the current implementation. */ heap_page_prune_and_freeze(relation, buffer, vistest, 0, NULL, &presult, PRUNE_ON_ACCESS, &dummy_off_loc, NULL, NULL); /* * Report the number of tuples reclaimed to pgstats. This is * presult.ndeleted minus the number of newly-LP_DEAD-set items. * * We derive the number of dead tuples like this to avoid totally * forgetting about items that were set to LP_DEAD, since they * still need to be cleaned up by VACUUM. We only want to count * heap-only tuples that just became LP_UNUSED in our report, * which don't. * * VACUUM doesn't have to compensate in the same way when it * tracks ndeleted, since it will set the same LP_DEAD items to * LP_UNUSED separately. */ if (presult.ndeleted > presult.nnewlpdead) pgstat_update_heap_dead_tuples(relation, presult.ndeleted - presult.nnewlpdead); } /* And release buffer lock */ LockBuffer(buffer, BUFFER_LOCK_UNLOCK); /* * We avoid reuse of any free space created on the page by unrelated * UPDATEs/INSERTs by opting to not update the FSM at this point. The * free space should be reused by UPDATEs to *this* page. */ } } /* * Prune and repair fragmentation and potentially freeze tuples on the * specified page. * * Caller must have pin and buffer cleanup lock on the page. Note that we * don't update the FSM information for page on caller's behalf. Caller might * also need to account for a reduction in the length of the line pointer * array following array truncation by us. * * If the HEAP_PRUNE_FREEZE option is set, we will also freeze tuples if it's * required in order to advance relfrozenxid / relminmxid, or if it's * considered advantageous for overall system performance to do so now. The * 'cutoffs', 'presult', 'new_relfrozen_xid' and 'new_relmin_mxid' arguments * are required when freezing. When HEAP_PRUNE_FREEZE option is set, we also * set presult->all_visible and presult->all_frozen on exit, to indicate if * the VM bits can be set. They are always set to false when the * HEAP_PRUNE_FREEZE option is not set, because at the moment only callers * that also freeze need that information. * * vistest is used to distinguish whether tuples are DEAD or RECENTLY_DEAD * (see heap_prune_satisfies_vacuum). * * options: * MARK_UNUSED_NOW indicates that dead items can be set LP_UNUSED during * pruning. * * FREEZE indicates that we will also freeze tuples, and will return * 'all_visible', 'all_frozen' flags to the caller. * * cutoffs contains the freeze cutoffs, established by VACUUM at the beginning * of vacuuming the relation. Required if HEAP_PRUNE_FREEZE option is set. * cutoffs->OldestXmin is also used to determine if dead tuples are * HEAPTUPLE_RECENTLY_DEAD or HEAPTUPLE_DEAD. * * presult contains output parameters needed by callers, such as the number of * tuples removed and the offsets of dead items on the page after pruning. * heap_page_prune_and_freeze() is responsible for initializing it. Required * by all callers. * * reason indicates why the pruning is performed. It is included in the WAL * record for debugging and analysis purposes, but otherwise has no effect. * * off_loc is the offset location required by the caller to use in error * callback. * * new_relfrozen_xid and new_relmin_mxid must provided by the caller if the * HEAP_PRUNE_FREEZE option is set. On entry, they contain the oldest XID and * multi-XID seen on the relation so far. They will be updated with oldest * values present on the page after pruning. After processing the whole * relation, VACUUM can use these values as the new relfrozenxid/relminmxid * for the relation. */ void heap_page_prune_and_freeze(Relation relation, Buffer buffer, GlobalVisState *vistest, int options, struct VacuumCutoffs *cutoffs, PruneFreezeResult *presult, PruneReason reason, OffsetNumber *off_loc, TransactionId *new_relfrozen_xid, MultiXactId *new_relmin_mxid) { Page page = BufferGetPage(buffer); BlockNumber blockno = BufferGetBlockNumber(buffer); OffsetNumber offnum, maxoff; PruneState prstate; HeapTupleData tup; bool do_freeze; bool do_prune; bool do_hint; bool hint_bit_fpi; int64 fpi_before = pgWalUsage.wal_fpi; /* Copy parameters to prstate */ prstate.vistest = vistest; prstate.mark_unused_now = (options & HEAP_PAGE_PRUNE_MARK_UNUSED_NOW) != 0; prstate.freeze = (options & HEAP_PAGE_PRUNE_FREEZE) != 0; prstate.cutoffs = cutoffs; /* * Our strategy is to scan the page and make lists of items to change, * then apply the changes within a critical section. This keeps as much * logic as possible out of the critical section, and also ensures that * WAL replay will work the same as the normal case. * * First, initialize the new pd_prune_xid value to zero (indicating no * prunable tuples). If we find any tuples which may soon become * prunable, we will save the lowest relevant XID in new_prune_xid. Also * initialize the rest of our working state. */ prstate.new_prune_xid = InvalidTransactionId; prstate.latest_xid_removed = InvalidTransactionId; prstate.nredirected = prstate.ndead = prstate.nunused = prstate.nfrozen = 0; prstate.nroot_items = 0; prstate.nheaponly_items = 0; /* initialize page freezing working state */ prstate.pagefrz.freeze_required = false; if (prstate.freeze) { Assert(new_relfrozen_xid && new_relmin_mxid); prstate.pagefrz.FreezePageRelfrozenXid = *new_relfrozen_xid; prstate.pagefrz.NoFreezePageRelfrozenXid = *new_relfrozen_xid; prstate.pagefrz.FreezePageRelminMxid = *new_relmin_mxid; prstate.pagefrz.NoFreezePageRelminMxid = *new_relmin_mxid; } else { Assert(new_relfrozen_xid == NULL && new_relmin_mxid == NULL); prstate.pagefrz.FreezePageRelminMxid = InvalidMultiXactId; prstate.pagefrz.NoFreezePageRelminMxid = InvalidMultiXactId; prstate.pagefrz.FreezePageRelfrozenXid = InvalidTransactionId; prstate.pagefrz.NoFreezePageRelfrozenXid = InvalidTransactionId; } prstate.ndeleted = 0; prstate.live_tuples = 0; prstate.recently_dead_tuples = 0; prstate.hastup = false; prstate.lpdead_items = 0; prstate.deadoffsets = presult->deadoffsets; /* * Caller may update the VM after we're done. We can keep track of * whether the page will be all-visible and all-frozen after pruning and * freezing to help the caller to do that. * * Currently, only VACUUM sets the VM bits. To save the effort, only do * the bookkeeping if the caller needs it. Currently, that's tied to * HEAP_PAGE_PRUNE_FREEZE, but it could be a separate flag if you wanted * to update the VM bits without also freezing or freeze without also * setting the VM bits. * * In addition to telling the caller whether it can set the VM bit, we * also use 'all_visible' and 'all_frozen' for our own decision-making. If * the whole page would become frozen, we consider opportunistically * freezing tuples. We will not be able to freeze the whole page if there * are tuples present that are not visible to everyone or if there are * dead tuples which are not yet removable. However, dead tuples which * will be removed by the end of vacuuming should not preclude us from * opportunistically freezing. Because of that, we do not clear * all_visible when we see LP_DEAD items. We fix that at the end of the * function, when we return the value to the caller, so that the caller * doesn't set the VM bit incorrectly. */ if (prstate.freeze) { prstate.all_visible = true; prstate.all_frozen = true; } else { /* * Initializing to false allows skipping the work to update them in * heap_prune_record_unchanged_lp_normal(). */ prstate.all_visible = false; prstate.all_frozen = false; } /* * The visibility cutoff xid is the newest xmin of live tuples on the * page. In the common case, this will be set as the conflict horizon the * caller can use for updating the VM. If, at the end of freezing and * pruning, the page is all-frozen, there is no possibility that any * running transaction on the standby does not see tuples on the page as * all-visible, so the conflict horizon remains InvalidTransactionId. */ prstate.visibility_cutoff_xid = InvalidTransactionId; maxoff = PageGetMaxOffsetNumber(page); tup.t_tableOid = RelationGetRelid(relation); /* * Determine HTSV for all tuples, and queue them up for processing as HOT * chain roots or as heap-only items. * * Determining HTSV only once for each tuple is required for correctness, * to deal with cases where running HTSV twice could result in different * results. For example, RECENTLY_DEAD can turn to DEAD if another * checked item causes GlobalVisTestIsRemovableFullXid() to update the * horizon, or INSERT_IN_PROGRESS can change to DEAD if the inserting * transaction aborts. * * It's also good for performance. Most commonly tuples within a page are * stored at decreasing offsets (while the items are stored at increasing * offsets). When processing all tuples on a page this leads to reading * memory at decreasing offsets within a page, with a variable stride. * That's hard for CPU prefetchers to deal with. Processing the items in * reverse order (and thus the tuples in increasing order) increases * prefetching efficiency significantly / decreases the number of cache * misses. */ for (offnum = maxoff; offnum >= FirstOffsetNumber; offnum = OffsetNumberPrev(offnum)) { ItemId itemid = PageGetItemId(page, offnum); HeapTupleHeader htup; /* * Set the offset number so that we can display it along with any * error that occurred while processing this tuple. */ *off_loc = offnum; prstate.processed[offnum] = false; prstate.htsv[offnum] = -1; /* Nothing to do if slot doesn't contain a tuple */ if (!ItemIdIsUsed(itemid)) { heap_prune_record_unchanged_lp_unused(page, &prstate, offnum); continue; } if (ItemIdIsDead(itemid)) { /* * If the caller set mark_unused_now true, we can set dead line * pointers LP_UNUSED now. */ if (unlikely(prstate.mark_unused_now)) heap_prune_record_unused(&prstate, offnum, false); else heap_prune_record_unchanged_lp_dead(page, &prstate, offnum); continue; } if (ItemIdIsRedirected(itemid)) { /* This is the start of a HOT chain */ prstate.root_items[prstate.nroot_items++] = offnum; continue; } Assert(ItemIdIsNormal(itemid)); /* * Get the tuple's visibility status and queue it up for processing. */ htup = (HeapTupleHeader) PageGetItem(page, itemid); tup.t_data = htup; tup.t_len = ItemIdGetLength(itemid); ItemPointerSet(&tup.t_self, blockno, offnum); prstate.htsv[offnum] = heap_prune_satisfies_vacuum(&prstate, &tup, buffer); if (!HeapTupleHeaderIsHeapOnly(htup)) prstate.root_items[prstate.nroot_items++] = offnum; else prstate.heaponly_items[prstate.nheaponly_items++] = offnum; } /* * If checksums are enabled, heap_prune_satisfies_vacuum() may have caused * an FPI to be emitted. */ hint_bit_fpi = fpi_before != pgWalUsage.wal_fpi; /* * Process HOT chains. * * We added the items to the array starting from 'maxoff', so by * processing the array in reverse order, we process the items in * ascending offset number order. The order doesn't matter for * correctness, but some quick micro-benchmarking suggests that this is * faster. (Earlier PostgreSQL versions, which scanned all the items on * the page instead of using the root_items array, also did it in * ascending offset number order.) */ for (int i = prstate.nroot_items - 1; i >= 0; i--) { offnum = prstate.root_items[i]; /* Ignore items already processed as part of an earlier chain */ if (prstate.processed[offnum]) continue; /* see preceding loop */ *off_loc = offnum; /* Process this item or chain of items */ heap_prune_chain(page, blockno, maxoff, offnum, &prstate); } /* * Process any heap-only tuples that were not already processed as part of * a HOT chain. */ for (int i = prstate.nheaponly_items - 1; i >= 0; i--) { offnum = prstate.heaponly_items[i]; if (prstate.processed[offnum]) continue; /* see preceding loop */ *off_loc = offnum; /* * If the tuple is DEAD and doesn't chain to anything else, mark it * unused. (If it does chain, we can only remove it as part of * pruning its chain.) * * We need this primarily to handle aborted HOT updates, that is, * XMIN_INVALID heap-only tuples. Those might not be linked to by any * chain, since the parent tuple might be re-updated before any * pruning occurs. So we have to be able to reap them separately from * chain-pruning. (Note that HeapTupleHeaderIsHotUpdated will never * return true for an XMIN_INVALID tuple, so this code will work even * when there were sequential updates within the aborted transaction.) */ if (prstate.htsv[offnum] == HEAPTUPLE_DEAD) { ItemId itemid = PageGetItemId(page, offnum); HeapTupleHeader htup = (HeapTupleHeader) PageGetItem(page, itemid); if (likely(!HeapTupleHeaderIsHotUpdated(htup))) { HeapTupleHeaderAdvanceConflictHorizon(htup, &prstate.latest_xid_removed); heap_prune_record_unused(&prstate, offnum, true); } else { /* * This tuple should've been processed and removed as part of * a HOT chain, so something's wrong. To preserve evidence, * we don't dare to remove it. We cannot leave behind a DEAD * tuple either, because that will cause VACUUM to error out. * Throwing an error with a distinct error message seems like * the least bad option. */ elog(ERROR, "dead heap-only tuple (%u, %d) is not linked to from any HOT chain", blockno, offnum); } } else heap_prune_record_unchanged_lp_normal(page, &prstate, offnum); } /* We should now have processed every tuple exactly once */ #ifdef USE_ASSERT_CHECKING for (offnum = FirstOffsetNumber; offnum <= maxoff; offnum = OffsetNumberNext(offnum)) { *off_loc = offnum; Assert(prstate.processed[offnum]); } #endif /* Clear the offset information once we have processed the given page. */ *off_loc = InvalidOffsetNumber; do_prune = prstate.nredirected > 0 || prstate.ndead > 0 || prstate.nunused > 0; /* * Even if we don't prune anything, if we found a new value for the * pd_prune_xid field or the page was marked full, we will update the hint * bit. */ do_hint = ((PageHeader) page)->pd_prune_xid != prstate.new_prune_xid || PageIsFull(page); /* * Decide if we want to go ahead with freezing according to the freeze * plans we prepared, or not. */ do_freeze = false; if (prstate.freeze) { if (prstate.pagefrz.freeze_required) { /* * heap_prepare_freeze_tuple indicated that at least one XID/MXID * from before FreezeLimit/MultiXactCutoff is present. Must * freeze to advance relfrozenxid/relminmxid. */ do_freeze = true; } else { /* * Opportunistically freeze the page if we are generating an FPI * anyway and if doing so means that we can set the page * all-frozen afterwards (might not happen until VACUUM's final * heap pass). * * XXX: Previously, we knew if pruning emitted an FPI by checking * pgWalUsage.wal_fpi before and after pruning. Once the freeze * and prune records were combined, this heuristic couldn't be * used anymore. The opportunistic freeze heuristic must be * improved; however, for now, try to approximate the old logic. */ if (prstate.all_visible && prstate.all_frozen && prstate.nfrozen > 0) { /* * Freezing would make the page all-frozen. Have already * emitted an FPI or will do so anyway? */ if (RelationNeedsWAL(relation)) { if (hint_bit_fpi) do_freeze = true; else if (do_prune) { if (XLogCheckBufferNeedsBackup(buffer)) do_freeze = true; } else if (do_hint) { if (XLogHintBitIsNeeded() && XLogCheckBufferNeedsBackup(buffer)) do_freeze = true; } } } } } if (do_freeze) { /* * Validate the tuples we will be freezing before entering the * critical section. */ heap_pre_freeze_checks(buffer, prstate.frozen, prstate.nfrozen); } else if (prstate.nfrozen > 0) { /* * The page contained some tuples that were not already frozen, and we * chose not to freeze them now. The page won't be all-frozen then. */ Assert(!prstate.pagefrz.freeze_required); prstate.all_frozen = false; prstate.nfrozen = 0; /* avoid miscounts in instrumentation */ } else { /* * We have no freeze plans to execute. The page might already be * all-frozen (perhaps only following pruning), though. Such pages * can be marked all-frozen in the VM by our caller, even though none * of its tuples were newly frozen here. */ } /* Any error while applying the changes is critical */ START_CRIT_SECTION(); if (do_hint) { /* * Update the page's pd_prune_xid field to either zero, or the lowest * XID of any soon-prunable tuple. */ ((PageHeader) page)->pd_prune_xid = prstate.new_prune_xid; /* * Also clear the "page is full" flag, since there's no point in * repeating the prune/defrag process until something else happens to * the page. */ PageClearFull(page); /* * If that's all we had to do to the page, this is a non-WAL-logged * hint. If we are going to freeze or prune the page, we will mark * the buffer dirty below. */ if (!do_freeze && !do_prune) MarkBufferDirtyHint(buffer, true); } if (do_prune || do_freeze) { /* Apply the planned item changes and repair page fragmentation. */ if (do_prune) { heap_page_prune_execute(buffer, false, prstate.redirected, prstate.nredirected, prstate.nowdead, prstate.ndead, prstate.nowunused, prstate.nunused); } if (do_freeze) heap_freeze_prepared_tuples(buffer, prstate.frozen, prstate.nfrozen); MarkBufferDirty(buffer); /* * Emit a WAL XLOG_HEAP2_PRUNE_FREEZE record showing what we did */ if (RelationNeedsWAL(relation)) { /* * The snapshotConflictHorizon for the whole record should be the * most conservative of all the horizons calculated for any of the * possible modifications. If this record will prune tuples, any * transactions on the standby older than the youngest xmax of the * most recently removed tuple this record will prune will * conflict. If this record will freeze tuples, any transactions * on the standby with xids older than the youngest tuple this * record will freeze will conflict. */ TransactionId frz_conflict_horizon = InvalidTransactionId; TransactionId conflict_xid; /* * We can use the visibility_cutoff_xid as our cutoff for * conflicts when the whole page is eligible to become all-frozen * in the VM once we're done with it. Otherwise we generate a * conservative cutoff by stepping back from OldestXmin. */ if (do_freeze) { if (prstate.all_visible && prstate.all_frozen) frz_conflict_horizon = prstate.visibility_cutoff_xid; else { /* Avoids false conflicts when hot_standby_feedback in use */ frz_conflict_horizon = prstate.cutoffs->OldestXmin; TransactionIdRetreat(frz_conflict_horizon); } } if (TransactionIdFollows(frz_conflict_horizon, prstate.latest_xid_removed)) conflict_xid = frz_conflict_horizon; else conflict_xid = prstate.latest_xid_removed; log_heap_prune_and_freeze(relation, buffer, conflict_xid, true, reason, prstate.frozen, prstate.nfrozen, prstate.redirected, prstate.nredirected, prstate.nowdead, prstate.ndead, prstate.nowunused, prstate.nunused); } } END_CRIT_SECTION(); /* Copy information back for caller */ presult->ndeleted = prstate.ndeleted; presult->nnewlpdead = prstate.ndead; presult->nfrozen = prstate.nfrozen; presult->live_tuples = prstate.live_tuples; presult->recently_dead_tuples = prstate.recently_dead_tuples; /* * It was convenient to ignore LP_DEAD items in all_visible earlier on to * make the choice of whether or not to freeze the page unaffected by the * short-term presence of LP_DEAD items. These LP_DEAD items were * effectively assumed to be LP_UNUSED items in the making. It doesn't * matter which vacuum heap pass (initial pass or final pass) ends up * setting the page all-frozen, as long as the ongoing VACUUM does it. * * Now that freezing has been finalized, unset all_visible if there are * any LP_DEAD items on the page. It needs to reflect the present state * of the page, as expected by our caller. */ if (prstate.all_visible && prstate.lpdead_items == 0) { presult->all_visible = prstate.all_visible; presult->all_frozen = prstate.all_frozen; } else { presult->all_visible = false; presult->all_frozen = false; } presult->hastup = prstate.hastup; /* * For callers planning to update the visibility map, the conflict horizon * for that record must be the newest xmin on the page. However, if the * page is completely frozen, there can be no conflict and the * vm_conflict_horizon should remain InvalidTransactionId. This includes * the case that we just froze all the tuples; the prune-freeze record * included the conflict XID already so the caller doesn't need it. */ if (presult->all_frozen) presult->vm_conflict_horizon = InvalidTransactionId; else presult->vm_conflict_horizon = prstate.visibility_cutoff_xid; presult->lpdead_items = prstate.lpdead_items; /* the presult->deadoffsets array was already filled in */ if (prstate.freeze) { if (presult->nfrozen > 0) { *new_relfrozen_xid = prstate.pagefrz.FreezePageRelfrozenXid; *new_relmin_mxid = prstate.pagefrz.FreezePageRelminMxid; } else { *new_relfrozen_xid = prstate.pagefrz.NoFreezePageRelfrozenXid; *new_relmin_mxid = prstate.pagefrz.NoFreezePageRelminMxid; } } } /* * Perform visibility checks for heap pruning. */ static HTSV_Result heap_prune_satisfies_vacuum(PruneState *prstate, HeapTuple tup, Buffer buffer) { HTSV_Result res; TransactionId dead_after; res = HeapTupleSatisfiesVacuumHorizon(tup, buffer, &dead_after); if (res != HEAPTUPLE_RECENTLY_DEAD) return res; /* * For VACUUM, we must be sure to prune tuples with xmax older than * OldestXmin -- a visibility cutoff determined at the beginning of * vacuuming the relation. OldestXmin is used for freezing determination * and we cannot freeze dead tuples' xmaxes. */ if (prstate->cutoffs && TransactionIdIsValid(prstate->cutoffs->OldestXmin) && NormalTransactionIdPrecedes(dead_after, prstate->cutoffs->OldestXmin)) return HEAPTUPLE_DEAD; /* * Determine whether or not the tuple is considered dead when compared * with the provided GlobalVisState. On-access pruning does not provide * VacuumCutoffs. And for vacuum, even if the tuple's xmax is not older * than OldestXmin, GlobalVisTestIsRemovableXid() could find the row dead * if the GlobalVisState has been updated since the beginning of vacuuming * the relation. */ if (GlobalVisTestIsRemovableXid(prstate->vistest, dead_after)) return HEAPTUPLE_DEAD; return res; } /* * Pruning calculates tuple visibility once and saves the results in an array * of int8. See PruneState.htsv for details. This helper function is meant * to guard against examining visibility status array members which have not * yet been computed. */ static inline HTSV_Result htsv_get_valid_status(int status) { Assert(status >= HEAPTUPLE_DEAD && status <= HEAPTUPLE_DELETE_IN_PROGRESS); return (HTSV_Result) status; } /* * Prune specified line pointer or a HOT chain originating at line pointer. * * Tuple visibility information is provided in prstate->htsv. * * If the item is an index-referenced tuple (i.e. not a heap-only tuple), * the HOT chain is pruned by removing all DEAD tuples at the start of the HOT * chain. We also prune any RECENTLY_DEAD tuples preceding a DEAD tuple. * This is OK because a RECENTLY_DEAD tuple preceding a DEAD tuple is really * DEAD, our visibility test is just too coarse to detect it. * * Pruning must never leave behind a DEAD tuple that still has tuple storage. * VACUUM isn't prepared to deal with that case. * * The root line pointer is redirected to the tuple immediately after the * latest DEAD tuple. If all tuples in the chain are DEAD, the root line * pointer is marked LP_DEAD. (This includes the case of a DEAD simple * tuple, which we treat as a chain of length 1.) * * We don't actually change the page here. We just add entries to the arrays in * prstate showing the changes to be made. Items to be redirected are added * to the redirected[] array (two entries per redirection); items to be set to * LP_DEAD state are added to nowdead[]; and items to be set to LP_UNUSED * state are added to nowunused[]. We perform bookkeeping of live tuples, * visibility etc. based on what the page will look like after the changes * applied. All that bookkeeping is performed in the heap_prune_record_*() * subroutines. The division of labor is that heap_prune_chain() decides the * fate of each tuple, ie. whether it's going to be removed, redirected or * left unchanged, and the heap_prune_record_*() subroutines update PruneState * based on that outcome. */ static void heap_prune_chain(Page page, BlockNumber blockno, OffsetNumber maxoff, OffsetNumber rootoffnum, PruneState *prstate) { TransactionId priorXmax = InvalidTransactionId; ItemId rootlp; OffsetNumber offnum; OffsetNumber chainitems[MaxHeapTuplesPerPage]; /* * After traversing the HOT chain, ndeadchain is the index in chainitems * of the first live successor after the last dead item. */ int ndeadchain = 0, nchain = 0; rootlp = PageGetItemId(page, rootoffnum); /* Start from the root tuple */ offnum = rootoffnum; /* while not end of the chain */ for (;;) { HeapTupleHeader htup; ItemId lp; /* Sanity check (pure paranoia) */ if (offnum < FirstOffsetNumber) break; /* * An offset past the end of page's line pointer array is possible * when the array was truncated (original item must have been unused) */ if (offnum > maxoff) break; /* If item is already processed, stop --- it must not be same chain */ if (prstate->processed[offnum]) break; lp = PageGetItemId(page, offnum); /* * Unused item obviously isn't part of the chain. Likewise, a dead * line pointer can't be part of the chain. Both of those cases were * already marked as processed. */ Assert(ItemIdIsUsed(lp)); Assert(!ItemIdIsDead(lp)); /* * If we are looking at the redirected root line pointer, jump to the * first normal tuple in the chain. If we find a redirect somewhere * else, stop --- it must not be same chain. */ if (ItemIdIsRedirected(lp)) { if (nchain > 0) break; /* not at start of chain */ chainitems[nchain++] = offnum; offnum = ItemIdGetRedirect(rootlp); continue; } Assert(ItemIdIsNormal(lp)); htup = (HeapTupleHeader) PageGetItem(page, lp); /* * Check the tuple XMIN against prior XMAX, if any */ if (TransactionIdIsValid(priorXmax) && !TransactionIdEquals(HeapTupleHeaderGetXmin(htup), priorXmax)) break; /* * OK, this tuple is indeed a member of the chain. */ chainitems[nchain++] = offnum; switch (htsv_get_valid_status(prstate->htsv[offnum])) { case HEAPTUPLE_DEAD: /* Remember the last DEAD tuple seen */ ndeadchain = nchain; HeapTupleHeaderAdvanceConflictHorizon(htup, &prstate->latest_xid_removed); /* Advance to next chain member */ break; case HEAPTUPLE_RECENTLY_DEAD: /* * We don't need to advance the conflict horizon for * RECENTLY_DEAD tuples, even if we are removing them. This * is because we only remove RECENTLY_DEAD tuples if they * precede a DEAD tuple, and the DEAD tuple must have been * inserted by a newer transaction than the RECENTLY_DEAD * tuple by virtue of being later in the chain. We will have * advanced the conflict horizon for the DEAD tuple. */ /* * Advance past RECENTLY_DEAD tuples just in case there's a * DEAD one after them. We have to make sure that we don't * miss any DEAD tuples, since DEAD tuples that still have * tuple storage after pruning will confuse VACUUM. */ break; case HEAPTUPLE_DELETE_IN_PROGRESS: case HEAPTUPLE_LIVE: case HEAPTUPLE_INSERT_IN_PROGRESS: goto process_chain; default: elog(ERROR, "unexpected HeapTupleSatisfiesVacuum result"); goto process_chain; } /* * If the tuple is not HOT-updated, then we are at the end of this * HOT-update chain. */ if (!HeapTupleHeaderIsHotUpdated(htup)) goto process_chain; /* HOT implies it can't have moved to different partition */ Assert(!HeapTupleHeaderIndicatesMovedPartitions(htup)); /* * Advance to next chain member. */ Assert(ItemPointerGetBlockNumber(&htup->t_ctid) == blockno); offnum = ItemPointerGetOffsetNumber(&htup->t_ctid); priorXmax = HeapTupleHeaderGetUpdateXid(htup); } if (ItemIdIsRedirected(rootlp) && nchain < 2) { /* * We found a redirect item that doesn't point to a valid follow-on * item. This can happen if the loop in heap_page_prune_and_freeze() * caused us to visit the dead successor of a redirect item before * visiting the redirect item. We can clean up by setting the * redirect item to LP_DEAD state or LP_UNUSED if the caller * indicated. */ heap_prune_record_dead_or_unused(prstate, rootoffnum, false); return; } process_chain: if (ndeadchain == 0) { /* * No DEAD tuple was found, so the chain is entirely composed of * normal, unchanged tuples. Leave it alone. */ int i = 0; if (ItemIdIsRedirected(rootlp)) { heap_prune_record_unchanged_lp_redirect(prstate, rootoffnum); i++; } for (; i < nchain; i++) heap_prune_record_unchanged_lp_normal(page, prstate, chainitems[i]); } else if (ndeadchain == nchain) { /* * The entire chain is dead. Mark the root line pointer LP_DEAD, and * fully remove the other tuples in the chain. */ heap_prune_record_dead_or_unused(prstate, rootoffnum, ItemIdIsNormal(rootlp)); for (int i = 1; i < nchain; i++) heap_prune_record_unused(prstate, chainitems[i], true); } else { /* * We found a DEAD tuple in the chain. Redirect the root line pointer * to the first non-DEAD tuple, and mark as unused each intermediate * item that we are able to remove from the chain. */ heap_prune_record_redirect(prstate, rootoffnum, chainitems[ndeadchain], ItemIdIsNormal(rootlp)); for (int i = 1; i < ndeadchain; i++) heap_prune_record_unused(prstate, chainitems[i], true); /* the rest of tuples in the chain are normal, unchanged tuples */ for (int i = ndeadchain; i < nchain; i++) heap_prune_record_unchanged_lp_normal(page, prstate, chainitems[i]); } } /* Record lowest soon-prunable XID */ static void heap_prune_record_prunable(PruneState *prstate, TransactionId xid) { /* * This should exactly match the PageSetPrunable macro. We can't store * directly into the page header yet, so we update working state. */ Assert(TransactionIdIsNormal(xid)); if (!TransactionIdIsValid(prstate->new_prune_xid) || TransactionIdPrecedes(xid, prstate->new_prune_xid)) prstate->new_prune_xid = xid; } /* Record line pointer to be redirected */ static void heap_prune_record_redirect(PruneState *prstate, OffsetNumber offnum, OffsetNumber rdoffnum, bool was_normal) { Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; /* * Do not mark the redirect target here. It needs to be counted * separately as an unchanged tuple. */ Assert(prstate->nredirected < MaxHeapTuplesPerPage); prstate->redirected[prstate->nredirected * 2] = offnum; prstate->redirected[prstate->nredirected * 2 + 1] = rdoffnum; prstate->nredirected++; /* * If the root entry had been a normal tuple, we are deleting it, so count * it in the result. But changing a redirect (even to DEAD state) doesn't * count. */ if (was_normal) prstate->ndeleted++; prstate->hastup = true; } /* Record line pointer to be marked dead */ static void heap_prune_record_dead(PruneState *prstate, OffsetNumber offnum, bool was_normal) { Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; Assert(prstate->ndead < MaxHeapTuplesPerPage); prstate->nowdead[prstate->ndead] = offnum; prstate->ndead++; /* * Deliberately delay unsetting all_visible until later during pruning. * Removable dead tuples shouldn't preclude freezing the page. */ /* Record the dead offset for vacuum */ prstate->deadoffsets[prstate->lpdead_items++] = offnum; /* * If the root entry had been a normal tuple, we are deleting it, so count * it in the result. But changing a redirect (even to DEAD state) doesn't * count. */ if (was_normal) prstate->ndeleted++; } /* * Depending on whether or not the caller set mark_unused_now to true, record that a * line pointer should be marked LP_DEAD or LP_UNUSED. There are other cases in * which we will mark line pointers LP_UNUSED, but we will not mark line * pointers LP_DEAD if mark_unused_now is true. */ static void heap_prune_record_dead_or_unused(PruneState *prstate, OffsetNumber offnum, bool was_normal) { /* * If the caller set mark_unused_now to true, we can remove dead tuples * during pruning instead of marking their line pointers dead. Set this * tuple's line pointer LP_UNUSED. We hint that this option is less * likely. */ if (unlikely(prstate->mark_unused_now)) heap_prune_record_unused(prstate, offnum, was_normal); else heap_prune_record_dead(prstate, offnum, was_normal); } /* Record line pointer to be marked unused */ static void heap_prune_record_unused(PruneState *prstate, OffsetNumber offnum, bool was_normal) { Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; Assert(prstate->nunused < MaxHeapTuplesPerPage); prstate->nowunused[prstate->nunused] = offnum; prstate->nunused++; /* * If the root entry had been a normal tuple, we are deleting it, so count * it in the result. But changing a redirect (even to DEAD state) doesn't * count. */ if (was_normal) prstate->ndeleted++; } /* * Record an unused line pointer that is left unchanged. */ static void heap_prune_record_unchanged_lp_unused(Page page, PruneState *prstate, OffsetNumber offnum) { Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; } /* * Record line pointer that is left unchanged. We consider freezing it, and * update bookkeeping of tuple counts and page visibility. */ static void heap_prune_record_unchanged_lp_normal(Page page, PruneState *prstate, OffsetNumber offnum) { HeapTupleHeader htup; Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; prstate->hastup = true; /* the page is not empty */ /* * The criteria for counting a tuple as live in this block need to match * what analyze.c's acquire_sample_rows() does, otherwise VACUUM and * ANALYZE may produce wildly different reltuples values, e.g. when there * are many recently-dead tuples. * * The logic here is a bit simpler than acquire_sample_rows(), as VACUUM * can't run inside a transaction block, which makes some cases impossible * (e.g. in-progress insert from the same transaction). * * HEAPTUPLE_DEAD are handled by the other heap_prune_record_*() * subroutines. They don't count dead items like acquire_sample_rows() * does, because we assume that all dead items will become LP_UNUSED * before VACUUM finishes. This difference is only superficial. VACUUM * effectively agrees with ANALYZE about DEAD items, in the end. VACUUM * won't remember LP_DEAD items, but only because they're not supposed to * be left behind when it is done. (Cases where we bypass index vacuuming * will violate this optimistic assumption, but the overall impact of that * should be negligible.) */ htup = (HeapTupleHeader) PageGetItem(page, PageGetItemId(page, offnum)); switch (prstate->htsv[offnum]) { case HEAPTUPLE_LIVE: /* * Count it as live. Not only is this natural, but it's also what * acquire_sample_rows() does. */ prstate->live_tuples++; /* * Is the tuple definitely visible to all transactions? * * NB: Like with per-tuple hint bits, we can't set the * PD_ALL_VISIBLE flag if the inserter committed asynchronously. * See SetHintBits for more info. Check that the tuple is hinted * xmin-committed because of that. */ if (prstate->all_visible) { TransactionId xmin; if (!HeapTupleHeaderXminCommitted(htup)) { prstate->all_visible = false; break; } /* * The inserter definitely committed. But is it old enough * that everyone sees it as committed? A FrozenTransactionId * is seen as committed to everyone. Otherwise, we check if * there is a snapshot that considers this xid to still be * running, and if so, we don't consider the page all-visible. */ xmin = HeapTupleHeaderGetXmin(htup); /* * For now always use prstate->cutoffs for this test, because * we only update 'all_visible' when freezing is requested. We * could use GlobalVisTestIsRemovableXid instead, if a * non-freezing caller wanted to set the VM bit. */ Assert(prstate->cutoffs); if (!TransactionIdPrecedes(xmin, prstate->cutoffs->OldestXmin)) { prstate->all_visible = false; break; } /* Track newest xmin on page. */ if (TransactionIdFollows(xmin, prstate->visibility_cutoff_xid) && TransactionIdIsNormal(xmin)) prstate->visibility_cutoff_xid = xmin; } break; case HEAPTUPLE_RECENTLY_DEAD: prstate->recently_dead_tuples++; prstate->all_visible = false; /* * This tuple will soon become DEAD. Update the hint field so * that the page is reconsidered for pruning in future. */ heap_prune_record_prunable(prstate, HeapTupleHeaderGetUpdateXid(htup)); break; case HEAPTUPLE_INSERT_IN_PROGRESS: /* * We do not count these rows as live, because we expect the * inserting transaction to update the counters at commit, and we * assume that will happen only after we report our results. This * assumption is a bit shaky, but it is what acquire_sample_rows() * does, so be consistent. */ prstate->all_visible = false; /* * If we wanted to optimize for aborts, we might consider marking * the page prunable when we see INSERT_IN_PROGRESS. But we * don't. See related decisions about when to mark the page * prunable in heapam.c. */ break; case HEAPTUPLE_DELETE_IN_PROGRESS: /* * This an expected case during concurrent vacuum. Count such * rows as live. As above, we assume the deleting transaction * will commit and update the counters after we report. */ prstate->live_tuples++; prstate->all_visible = false; /* * This tuple may soon become DEAD. Update the hint field so that * the page is reconsidered for pruning in future. */ heap_prune_record_prunable(prstate, HeapTupleHeaderGetUpdateXid(htup)); break; default: /* * DEAD tuples should've been passed to heap_prune_record_dead() * or heap_prune_record_unused() instead. */ elog(ERROR, "unexpected HeapTupleSatisfiesVacuum result %d", prstate->htsv[offnum]); break; } /* Consider freezing any normal tuples which will not be removed */ if (prstate->freeze) { bool totally_frozen; if ((heap_prepare_freeze_tuple(htup, prstate->cutoffs, &prstate->pagefrz, &prstate->frozen[prstate->nfrozen], &totally_frozen))) { /* Save prepared freeze plan for later */ prstate->frozen[prstate->nfrozen++].offset = offnum; } /* * If any tuple isn't either totally frozen already or eligible to * become totally frozen (according to its freeze plan), then the page * definitely cannot be set all-frozen in the visibility map later on. */ if (!totally_frozen) prstate->all_frozen = false; } } /* * Record line pointer that was already LP_DEAD and is left unchanged. */ static void heap_prune_record_unchanged_lp_dead(Page page, PruneState *prstate, OffsetNumber offnum) { Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; /* * Deliberately don't set hastup for LP_DEAD items. We make the soft * assumption that any LP_DEAD items encountered here will become * LP_UNUSED later on, before count_nondeletable_pages is reached. If we * don't make this assumption then rel truncation will only happen every * other VACUUM, at most. Besides, VACUUM must treat * hastup/nonempty_pages as provisional no matter how LP_DEAD items are * handled (handled here, or handled later on). * * Similarly, don't unset all_visible until later, at the end of * heap_page_prune_and_freeze(). This will allow us to attempt to freeze * the page after pruning. As long as we unset it before updating the * visibility map, this will be correct. */ /* Record the dead offset for vacuum */ prstate->deadoffsets[prstate->lpdead_items++] = offnum; } /* * Record LP_REDIRECT that is left unchanged. */ static void heap_prune_record_unchanged_lp_redirect(PruneState *prstate, OffsetNumber offnum) { /* * A redirect line pointer doesn't count as a live tuple. * * If we leave a redirect line pointer in place, there will be another * tuple on the page that it points to. We will do the bookkeeping for * that separately. So we have nothing to do here, except remember that * we processed this item. */ Assert(!prstate->processed[offnum]); prstate->processed[offnum] = true; } /* * Perform the actual page changes needed by heap_page_prune_and_freeze(). * * If 'lp_truncate_only' is set, we are merely marking LP_DEAD line pointers * as unused, not redirecting or removing anything else. The * PageRepairFragmentation() call is skipped in that case. * * If 'lp_truncate_only' is not set, the caller must hold a cleanup lock on * the buffer. If it is set, an ordinary exclusive lock suffices. */ void heap_page_prune_execute(Buffer buffer, bool lp_truncate_only, OffsetNumber *redirected, int nredirected, OffsetNumber *nowdead, int ndead, OffsetNumber *nowunused, int nunused) { Page page = (Page) BufferGetPage(buffer); OffsetNumber *offnum; HeapTupleHeader htup PG_USED_FOR_ASSERTS_ONLY; /* Shouldn't be called unless there's something to do */ Assert(nredirected > 0 || ndead > 0 || nunused > 0); /* If 'lp_truncate_only', we can only remove already-dead line pointers */ Assert(!lp_truncate_only || (nredirected == 0 && ndead == 0)); /* Update all redirected line pointers */ offnum = redirected; for (int i = 0; i < nredirected; i++) { OffsetNumber fromoff = *offnum++; OffsetNumber tooff = *offnum++; ItemId fromlp = PageGetItemId(page, fromoff); ItemId tolp PG_USED_FOR_ASSERTS_ONLY; #ifdef USE_ASSERT_CHECKING /* * Any existing item that we set as an LP_REDIRECT (any 'from' item) * must be the first item from a HOT chain. If the item has tuple * storage then it can't be a heap-only tuple. Otherwise we are just * maintaining an existing LP_REDIRECT from an existing HOT chain that * has been pruned at least once before now. */ if (!ItemIdIsRedirected(fromlp)) { Assert(ItemIdHasStorage(fromlp) && ItemIdIsNormal(fromlp)); htup = (HeapTupleHeader) PageGetItem(page, fromlp); Assert(!HeapTupleHeaderIsHeapOnly(htup)); } else { /* We shouldn't need to redundantly set the redirect */ Assert(ItemIdGetRedirect(fromlp) != tooff); } /* * The item that we're about to set as an LP_REDIRECT (the 'from' * item) will point to an existing item (the 'to' item) that is * already a heap-only tuple. There can be at most one LP_REDIRECT * item per HOT chain. * * We need to keep around an LP_REDIRECT item (after original * non-heap-only root tuple gets pruned away) so that it's always * possible for VACUUM to easily figure out what TID to delete from * indexes when an entire HOT chain becomes dead. A heap-only tuple * can never become LP_DEAD; an LP_REDIRECT item or a regular heap * tuple can. * * This check may miss problems, e.g. the target of a redirect could * be marked as unused subsequently. The page_verify_redirects() check * below will catch such problems. */ tolp = PageGetItemId(page, tooff); Assert(ItemIdHasStorage(tolp) && ItemIdIsNormal(tolp)); htup = (HeapTupleHeader) PageGetItem(page, tolp); Assert(HeapTupleHeaderIsHeapOnly(htup)); #endif ItemIdSetRedirect(fromlp, tooff); } /* Update all now-dead line pointers */ offnum = nowdead; for (int i = 0; i < ndead; i++) { OffsetNumber off = *offnum++; ItemId lp = PageGetItemId(page, off); #ifdef USE_ASSERT_CHECKING /* * An LP_DEAD line pointer must be left behind when the original item * (which is dead to everybody) could still be referenced by a TID in * an index. This should never be necessary with any individual * heap-only tuple item, though. (It's not clear how much of a problem * that would be, but there is no reason to allow it.) */ if (ItemIdHasStorage(lp)) { Assert(ItemIdIsNormal(lp)); htup = (HeapTupleHeader) PageGetItem(page, lp); Assert(!HeapTupleHeaderIsHeapOnly(htup)); } else { /* Whole HOT chain becomes dead */ Assert(ItemIdIsRedirected(lp)); } #endif ItemIdSetDead(lp); } /* Update all now-unused line pointers */ offnum = nowunused; for (int i = 0; i < nunused; i++) { OffsetNumber off = *offnum++; ItemId lp = PageGetItemId(page, off); #ifdef USE_ASSERT_CHECKING if (lp_truncate_only) { /* Setting LP_DEAD to LP_UNUSED in vacuum's second pass */ Assert(ItemIdIsDead(lp) && !ItemIdHasStorage(lp)); } else { /* * When heap_page_prune_and_freeze() was called, mark_unused_now * may have been passed as true, which allows would-be LP_DEAD * items to be made LP_UNUSED instead. This is only possible if * the relation has no indexes. If there are any dead items, then * mark_unused_now was not true and every item being marked * LP_UNUSED must refer to a heap-only tuple. */ if (ndead > 0) { Assert(ItemIdHasStorage(lp) && ItemIdIsNormal(lp)); htup = (HeapTupleHeader) PageGetItem(page, lp); Assert(HeapTupleHeaderIsHeapOnly(htup)); } else Assert(ItemIdIsUsed(lp)); } #endif ItemIdSetUnused(lp); } if (lp_truncate_only) PageTruncateLinePointerArray(page); else { /* * Finally, repair any fragmentation, and update the page's hint bit * about whether it has free pointers. */ PageRepairFragmentation(page); /* * Now that the page has been modified, assert that redirect items * still point to valid targets. */ page_verify_redirects(page); } } /* * If built with assertions, verify that all LP_REDIRECT items point to a * valid item. * * One way that bugs related to HOT pruning show is redirect items pointing to * removed tuples. It's not trivial to reliably check that marking an item * unused will not orphan a redirect item during heap_prune_chain() / * heap_page_prune_execute(), so we additionally check the whole page after * pruning. Without this check such bugs would typically only cause asserts * later, potentially well after the corruption has been introduced. * * Also check comments in heap_page_prune_execute()'s redirection loop. */ static void page_verify_redirects(Page page) { #ifdef USE_ASSERT_CHECKING OffsetNumber offnum; OffsetNumber maxoff; maxoff = PageGetMaxOffsetNumber(page); for (offnum = FirstOffsetNumber; offnum <= maxoff; offnum = OffsetNumberNext(offnum)) { ItemId itemid = PageGetItemId(page, offnum); OffsetNumber targoff; ItemId targitem; HeapTupleHeader htup; if (!ItemIdIsRedirected(itemid)) continue; targoff = ItemIdGetRedirect(itemid); targitem = PageGetItemId(page, targoff); Assert(ItemIdIsUsed(targitem)); Assert(ItemIdIsNormal(targitem)); Assert(ItemIdHasStorage(targitem)); htup = (HeapTupleHeader) PageGetItem(page, targitem); Assert(HeapTupleHeaderIsHeapOnly(htup)); } #endif } /* * For all items in this page, find their respective root line pointers. * If item k is part of a HOT-chain with root at item j, then we set * root_offsets[k - 1] = j. * * The passed-in root_offsets array must have MaxHeapTuplesPerPage entries. * Unused entries are filled with InvalidOffsetNumber (zero). * * The function must be called with at least share lock on the buffer, to * prevent concurrent prune operations. * * Note: The information collected here is valid only as long as the caller * holds a pin on the buffer. Once pin is released, a tuple might be pruned * and reused by a completely unrelated tuple. */ void heap_get_root_tuples(Page page, OffsetNumber *root_offsets) { OffsetNumber offnum, maxoff; MemSet(root_offsets, InvalidOffsetNumber, MaxHeapTuplesPerPage * sizeof(OffsetNumber)); maxoff = PageGetMaxOffsetNumber(page); for (offnum = FirstOffsetNumber; offnum <= maxoff; offnum = OffsetNumberNext(offnum)) { ItemId lp = PageGetItemId(page, offnum); HeapTupleHeader htup; OffsetNumber nextoffnum; TransactionId priorXmax; /* skip unused and dead items */ if (!ItemIdIsUsed(lp) || ItemIdIsDead(lp)) continue; if (ItemIdIsNormal(lp)) { htup = (HeapTupleHeader) PageGetItem(page, lp); /* * Check if this tuple is part of a HOT-chain rooted at some other * tuple. If so, skip it for now; we'll process it when we find * its root. */ if (HeapTupleHeaderIsHeapOnly(htup)) continue; /* * This is either a plain tuple or the root of a HOT-chain. * Remember it in the mapping. */ root_offsets[offnum - 1] = offnum; /* If it's not the start of a HOT-chain, we're done with it */ if (!HeapTupleHeaderIsHotUpdated(htup)) continue; /* Set up to scan the HOT-chain */ nextoffnum = ItemPointerGetOffsetNumber(&htup->t_ctid); priorXmax = HeapTupleHeaderGetUpdateXid(htup); } else { /* Must be a redirect item. We do not set its root_offsets entry */ Assert(ItemIdIsRedirected(lp)); /* Set up to scan the HOT-chain */ nextoffnum = ItemIdGetRedirect(lp); priorXmax = InvalidTransactionId; } /* * Now follow the HOT-chain and collect other tuples in the chain. * * Note: Even though this is a nested loop, the complexity of the * function is O(N) because a tuple in the page should be visited not * more than twice, once in the outer loop and once in HOT-chain * chases. */ for (;;) { /* Sanity check (pure paranoia) */ if (offnum < FirstOffsetNumber) break; /* * An offset past the end of page's line pointer array is possible * when the array was truncated */ if (offnum > maxoff) break; lp = PageGetItemId(page, nextoffnum); /* Check for broken chains */ if (!ItemIdIsNormal(lp)) break; htup = (HeapTupleHeader) PageGetItem(page, lp); if (TransactionIdIsValid(priorXmax) && !TransactionIdEquals(priorXmax, HeapTupleHeaderGetXmin(htup))) break; /* Remember the root line pointer for this item */ root_offsets[nextoffnum - 1] = offnum; /* Advance to next chain member, if any */ if (!HeapTupleHeaderIsHotUpdated(htup)) break; /* HOT implies it can't have moved to different partition */ Assert(!HeapTupleHeaderIndicatesMovedPartitions(htup)); nextoffnum = ItemPointerGetOffsetNumber(&htup->t_ctid); priorXmax = HeapTupleHeaderGetUpdateXid(htup); } } } /* * Compare fields that describe actions required to freeze tuple with caller's * open plan. If everything matches then the frz tuple plan is equivalent to * caller's plan. */ static inline bool heap_log_freeze_eq(xlhp_freeze_plan *plan, HeapTupleFreeze *frz) { if (plan->xmax == frz->xmax && plan->t_infomask2 == frz->t_infomask2 && plan->t_infomask == frz->t_infomask && plan->frzflags == frz->frzflags) return true; /* Caller must call heap_log_freeze_new_plan again for frz */ return false; } /* * Comparator used to deduplicate the freeze plans used in WAL records. */ static int heap_log_freeze_cmp(const void *arg1, const void *arg2) { HeapTupleFreeze *frz1 = (HeapTupleFreeze *) arg1; HeapTupleFreeze *frz2 = (HeapTupleFreeze *) arg2; if (frz1->xmax < frz2->xmax) return -1; else if (frz1->xmax > frz2->xmax) return 1; if (frz1->t_infomask2 < frz2->t_infomask2) return -1; else if (frz1->t_infomask2 > frz2->t_infomask2) return 1; if (frz1->t_infomask < frz2->t_infomask) return -1; else if (frz1->t_infomask > frz2->t_infomask) return 1; if (frz1->frzflags < frz2->frzflags) return -1; else if (frz1->frzflags > frz2->frzflags) return 1; /* * heap_log_freeze_eq would consider these tuple-wise plans to be equal. * (So the tuples will share a single canonical freeze plan.) * * We tiebreak on page offset number to keep each freeze plan's page * offset number array individually sorted. (Unnecessary, but be tidy.) */ if (frz1->offset < frz2->offset) return -1; else if (frz1->offset > frz2->offset) return 1; Assert(false); return 0; } /* * Start new plan initialized using tuple-level actions. At least one tuple * will have steps required to freeze described by caller's plan during REDO. */ static inline void heap_log_freeze_new_plan(xlhp_freeze_plan *plan, HeapTupleFreeze *frz) { plan->xmax = frz->xmax; plan->t_infomask2 = frz->t_infomask2; plan->t_infomask = frz->t_infomask; plan->frzflags = frz->frzflags; plan->ntuples = 1; /* for now */ } /* * Deduplicate tuple-based freeze plans so that each distinct set of * processing steps is only stored once in the WAL record. * Called during original execution of freezing (for logged relations). * * Return value is number of plans set in *plans_out for caller. Also writes * an array of offset numbers into *offsets_out output argument for caller * (actually there is one array per freeze plan, but that's not of immediate * concern to our caller). */ static int heap_log_freeze_plan(HeapTupleFreeze *tuples, int ntuples, xlhp_freeze_plan *plans_out, OffsetNumber *offsets_out) { int nplans = 0; /* Sort tuple-based freeze plans in the order required to deduplicate */ qsort(tuples, ntuples, sizeof(HeapTupleFreeze), heap_log_freeze_cmp); for (int i = 0; i < ntuples; i++) { HeapTupleFreeze *frz = tuples + i; if (i == 0) { /* New canonical freeze plan starting with first tup */ heap_log_freeze_new_plan(plans_out, frz); nplans++; } else if (heap_log_freeze_eq(plans_out, frz)) { /* tup matches open canonical plan -- include tup in it */ Assert(offsets_out[i - 1] < frz->offset); plans_out->ntuples++; } else { /* Tup doesn't match current plan -- done with it now */ plans_out++; /* New canonical freeze plan starting with this tup */ heap_log_freeze_new_plan(plans_out, frz); nplans++; } /* * Save page offset number in dedicated buffer in passing. * * REDO routine relies on the record's offset numbers array grouping * offset numbers by freeze plan. The sort order within each grouping * is ascending offset number order, just to keep things tidy. */ offsets_out[i] = frz->offset; } Assert(nplans > 0 && nplans <= ntuples); return nplans; } /* * Write an XLOG_HEAP2_PRUNE_FREEZE WAL record * * This is used for several different page maintenance operations: * * - Page pruning, in VACUUM's 1st pass or on access: Some items are * redirected, some marked dead, and some removed altogether. * * - Freezing: Items are marked as 'frozen'. * * - Vacuum, 2nd pass: Items that are already LP_DEAD are marked as unused. * * They have enough commonalities that we use a single WAL record for them * all. * * If replaying the record requires a cleanup lock, pass cleanup_lock = true. * Replaying 'redirected' or 'dead' items always requires a cleanup lock, but * replaying 'unused' items depends on whether they were all previously marked * as dead. * * Note: This function scribbles on the 'frozen' array. * * Note: This is called in a critical section, so careful what you do here. */ void log_heap_prune_and_freeze(Relation relation, Buffer buffer, TransactionId conflict_xid, bool cleanup_lock, PruneReason reason, HeapTupleFreeze *frozen, int nfrozen, OffsetNumber *redirected, int nredirected, OffsetNumber *dead, int ndead, OffsetNumber *unused, int nunused) { xl_heap_prune xlrec; XLogRecPtr recptr; uint8 info; /* The following local variables hold data registered in the WAL record: */ xlhp_freeze_plan plans[MaxHeapTuplesPerPage]; xlhp_freeze_plans freeze_plans; xlhp_prune_items redirect_items; xlhp_prune_items dead_items; xlhp_prune_items unused_items; OffsetNumber frz_offsets[MaxHeapTuplesPerPage]; xlrec.flags = 0; /* * Prepare data for the buffer. The arrays are not actually in the * buffer, but we pretend that they are. When XLogInsert stores a full * page image, the arrays can be omitted. */ XLogBeginInsert(); XLogRegisterBuffer(0, buffer, REGBUF_STANDARD); if (nfrozen > 0) { int nplans; xlrec.flags |= XLHP_HAS_FREEZE_PLANS; /* * Prepare deduplicated representation for use in the WAL record. This * destructively sorts frozen tuples array in-place. */ nplans = heap_log_freeze_plan(frozen, nfrozen, plans, frz_offsets); freeze_plans.nplans = nplans; XLogRegisterBufData(0, &freeze_plans, offsetof(xlhp_freeze_plans, plans)); XLogRegisterBufData(0, plans, sizeof(xlhp_freeze_plan) * nplans); } if (nredirected > 0) { xlrec.flags |= XLHP_HAS_REDIRECTIONS; redirect_items.ntargets = nredirected; XLogRegisterBufData(0, &redirect_items, offsetof(xlhp_prune_items, data)); XLogRegisterBufData(0, redirected, sizeof(OffsetNumber[2]) * nredirected); } if (ndead > 0) { xlrec.flags |= XLHP_HAS_DEAD_ITEMS; dead_items.ntargets = ndead; XLogRegisterBufData(0, &dead_items, offsetof(xlhp_prune_items, data)); XLogRegisterBufData(0, dead, sizeof(OffsetNumber) * ndead); } if (nunused > 0) { xlrec.flags |= XLHP_HAS_NOW_UNUSED_ITEMS; unused_items.ntargets = nunused; XLogRegisterBufData(0, &unused_items, offsetof(xlhp_prune_items, data)); XLogRegisterBufData(0, unused, sizeof(OffsetNumber) * nunused); } if (nfrozen > 0) XLogRegisterBufData(0, frz_offsets, sizeof(OffsetNumber) * nfrozen); /* * Prepare the main xl_heap_prune record. We already set the XLHP_HAS_* * flag above. */ if (RelationIsAccessibleInLogicalDecoding(relation)) xlrec.flags |= XLHP_IS_CATALOG_REL; if (TransactionIdIsValid(conflict_xid)) xlrec.flags |= XLHP_HAS_CONFLICT_HORIZON; if (cleanup_lock) xlrec.flags |= XLHP_CLEANUP_LOCK; else { Assert(nredirected == 0 && ndead == 0); /* also, any items in 'unused' must've been LP_DEAD previously */ } XLogRegisterData(&xlrec, SizeOfHeapPrune); if (TransactionIdIsValid(conflict_xid)) XLogRegisterData(&conflict_xid, sizeof(TransactionId)); switch (reason) { case PRUNE_ON_ACCESS: info = XLOG_HEAP2_PRUNE_ON_ACCESS; break; case PRUNE_VACUUM_SCAN: info = XLOG_HEAP2_PRUNE_VACUUM_SCAN; break; case PRUNE_VACUUM_CLEANUP: info = XLOG_HEAP2_PRUNE_VACUUM_CLEANUP; break; default: elog(ERROR, "unrecognized prune reason: %d", (int) reason); break; } recptr = XLogInsert(RM_HEAP2_ID, info); PageSetLSN(BufferGetPage(buffer), recptr); }