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Update high level vacuumlazy.c comments.
Update vacuumlazy.c file header comments (as well as comments above the lazy_scan_heap function) that were largely written before the introduction of the HOT optimization, when lazy_scan_heap did far less, and didn't actually prune during its initial heap pass. Since lazy_scan_heap now outsources far more work to lower level functions, it makes sense to introduce the function by talking about the high level invariant that dictates the order in which each phase takes place. Also deemphasize the case where we run out of memory for TIDs, since delaying that discussion makes it easier to talk about issues of central importance. Finally, remove discussion of parallel VACUUM from header comments. These don't add much, and are in the wrong place.
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@ -3,39 +3,23 @@
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* vacuumlazy.c
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* Concurrent ("lazy") vacuuming.
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*
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*
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* The major space usage for LAZY VACUUM is storage for the array of dead tuple
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* TIDs. We want to ensure we can vacuum even the very largest relations with
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* finite memory space usage. To do that, we set upper bounds on the number of
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* tuples we will keep track of at once.
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* The major space usage for vacuuming is storage for the array of dead TIDs
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* that are to be removed from indexes. We want to ensure we can vacuum even
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* the very largest relations with finite memory space usage. To do that, we
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* set upper bounds on the number of TIDs we can keep track of at once.
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*
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* We are willing to use at most maintenance_work_mem (or perhaps
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* autovacuum_work_mem) memory space to keep track of dead tuples. We
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* initially allocate an array of TIDs of that size, with an upper limit that
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* depends on table size (this limit ensures we don't allocate a huge area
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* uselessly for vacuuming small tables). If the array threatens to overflow,
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* we suspend the heap scan phase and perform a pass of index cleanup and page
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* compaction, then resume the heap scan with an empty TID array.
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* autovacuum_work_mem) memory space to keep track of dead TIDs. We initially
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* allocate an array of TIDs of that size, with an upper limit that depends on
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* table size (this limit ensures we don't allocate a huge area uselessly for
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* vacuuming small tables). If the array threatens to overflow, we must call
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* lazy_vacuum to vacuum indexes (and to vacuum the pages that we've pruned).
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* This frees up the memory space dedicated to storing dead TIDs.
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*
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* If we're processing a table with no indexes, we can just vacuum each page
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* as we go; there's no need to save up multiple tuples to minimize the number
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* of index scans performed. So we don't use maintenance_work_mem memory for
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* the TID array, just enough to hold as many heap tuples as fit on one page.
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*
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* Lazy vacuum supports parallel execution with parallel worker processes. In
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* a parallel vacuum, we perform both index vacuum and index cleanup with
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* parallel worker processes. Individual indexes are processed by one vacuum
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* process. At the beginning of a lazy vacuum (at lazy_scan_heap) we prepare
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* the parallel context and initialize the DSM segment that contains shared
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* information as well as the memory space for storing dead tuples. When
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* starting either index vacuum or index cleanup, we launch parallel worker
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* processes. Once all indexes are processed the parallel worker processes
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* exit. After that, the leader process re-initializes the parallel context
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* so that it can use the same DSM for multiple passes of index vacuum and
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* for performing index cleanup. For updating the index statistics, we need
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* to update the system table and since updates are not allowed during
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* parallel mode we update the index statistics after exiting from the
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* parallel mode.
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* In practice VACUUM will often complete its initial pass over the target
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* heap relation without ever running out of space to store TIDs. This means
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* that there only needs to be one call to lazy_vacuum, after the initial pass
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* completes.
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*
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* Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group
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* Portions Copyright (c) 1994, Regents of the University of California
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@ -124,13 +108,6 @@
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#define VACUUM_FSM_EVERY_PAGES \
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((BlockNumber) (((uint64) 8 * 1024 * 1024 * 1024) / BLCKSZ))
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/*
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* Guesstimation of number of dead tuples per page. This is used to
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* provide an upper limit to memory allocated when vacuuming small
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* tables.
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*/
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#define LAZY_ALLOC_TUPLES MaxHeapTuplesPerPage
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/*
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* Before we consider skipping a page that's marked as clean in
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* visibility map, we must've seen at least this many clean pages.
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@ -472,8 +449,9 @@ static void restore_vacuum_error_info(LVRelState *vacrel,
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/*
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* heap_vacuum_rel() -- perform VACUUM for one heap relation
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*
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* This routine vacuums a single heap, cleans out its indexes, and
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* updates its relpages and reltuples statistics.
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* This routine sets things up for and then calls lazy_scan_heap, where
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* almost all work actually takes place. Finalizes everything after call
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* returns by managing rel truncation and updating pg_class statistics.
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*
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* At entry, we have already established a transaction and opened
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* and locked the relation.
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@ -631,7 +609,10 @@ heap_vacuum_rel(Relation rel, VacuumParams *params,
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errcallback.previous = error_context_stack;
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error_context_stack = &errcallback;
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/* Do the vacuuming */
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/*
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* Call lazy_scan_heap to perform all required heap pruning, index
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* vacuuming, and heap vacuuming (plus related processing)
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*/
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lazy_scan_heap(vacrel, params, aggressive);
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/* Done with indexes */
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@ -714,8 +695,8 @@ heap_vacuum_rel(Relation rel, VacuumParams *params,
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*
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* Deliberately avoid telling the stats collector about LP_DEAD items that
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* remain in the table due to VACUUM bypassing index and heap vacuuming.
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* ANALYZE will consider the remaining LP_DEAD items to be dead tuples. It
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* seems like a good idea to err on the side of not vacuuming again too
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* ANALYZE will consider the remaining LP_DEAD items to be dead "tuples".
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* It seems like a good idea to err on the side of not vacuuming again too
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* soon in cases where the failsafe prevented significant amounts of heap
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* vacuuming.
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*/
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@ -875,20 +856,40 @@ heap_vacuum_rel(Relation rel, VacuumParams *params,
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}
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/*
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* lazy_scan_heap() -- scan an open heap relation
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* lazy_scan_heap() -- workhorse function for VACUUM
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*
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* This routine prunes each page in the heap, which will among other
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* things truncate dead tuples to dead line pointers, defragment the
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* page, and set commit status bits (see heap_page_prune). It also builds
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* lists of dead tuples and pages with free space, calculates statistics
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* on the number of live tuples in the heap, and marks pages as
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* all-visible if appropriate. When done, or when we run low on space
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* for dead-tuple TIDs, invoke lazy_vacuum to vacuum indexes and vacuum
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* heap relation during its own second pass over the heap.
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* This routine prunes each page in the heap, and considers the need to
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* freeze remaining tuples with storage (not including pages that can be
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* skipped using the visibility map). Also performs related maintenance
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* of the FSM and visibility map. These steps all take place during an
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* initial pass over the target heap relation.
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*
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* If there are no indexes then we can reclaim line pointers on the fly;
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* dead line pointers need only be retained until all index pointers that
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* reference them have been killed.
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* Also invokes lazy_vacuum_all_indexes to vacuum indexes, which largely
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* consists of deleting index tuples that point to LP_DEAD items left in
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* heap pages following pruning. Earlier initial pass over the heap will
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* have collected the TIDs whose index tuples need to be removed.
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*
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* Finally, invokes lazy_vacuum_heap_rel to vacuum heap pages, which
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* largely consists of marking LP_DEAD items (from collected TID array)
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* as LP_UNUSED. This has to happen in a second, final pass over the
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* heap, to preserve a basic invariant that all index AMs rely on: no
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* extant index tuple can ever be allowed to contain a TID that points to
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* an LP_UNUSED line pointer in the heap. We must disallow premature
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* recycling of line pointers to avoid index scans that get confused
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* about which TID points to which tuple immediately after recycling.
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* (Actually, this isn't a concern when target heap relation happens to
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* have no indexes, which allows us to safely apply the one-pass strategy
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* as an optimization).
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*
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* In practice we often have enough space to fit all TIDs, and so won't
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* need to call lazy_vacuum more than once, after our initial pass over
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* the heap has totally finished. Otherwise things are slightly more
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* complicated: our "initial pass" over the heap applies only to those
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* pages that were pruned before we needed to call lazy_vacuum, and our
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* "final pass" over the heap only vacuums these same heap pages.
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* However, we process indexes in full every time lazy_vacuum is called,
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* which makes index processing very inefficient when memory is in short
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* supply.
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*/
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static void
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lazy_scan_heap(LVRelState *vacrel, VacuumParams *params, bool aggressive)
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@ -1173,7 +1174,7 @@ lazy_scan_heap(LVRelState *vacrel, VacuumParams *params, bool aggressive)
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vmbuffer = InvalidBuffer;
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}
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/* Remove the collected garbage tuples from table and indexes */
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/* Perform a round of index and heap vacuuming */
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vacrel->consider_bypass_optimization = false;
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lazy_vacuum(vacrel);
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@ -1490,12 +1491,12 @@ lazy_scan_heap(LVRelState *vacrel, VacuumParams *params, bool aggressive)
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* visible to everyone yet actually are, and the PD_ALL_VISIBLE flag
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* is correct.
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*
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* There should never be dead tuples on a page with PD_ALL_VISIBLE
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* There should never be LP_DEAD items on a page with PD_ALL_VISIBLE
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* set, however.
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*/
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else if (prunestate.has_lpdead_items && PageIsAllVisible(page))
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{
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elog(WARNING, "page containing dead tuples is marked as all-visible in relation \"%s\" page %u",
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elog(WARNING, "page containing LP_DEAD items is marked as all-visible in relation \"%s\" page %u",
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vacrel->relname, blkno);
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PageClearAllVisible(page);
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MarkBufferDirty(buf);
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@ -1585,7 +1586,7 @@ lazy_scan_heap(LVRelState *vacrel, VacuumParams *params, bool aggressive)
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vmbuffer = InvalidBuffer;
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}
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/* If any tuples need to be deleted, perform final vacuum cycle */
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/* Perform a final round of index and heap vacuuming */
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if (dead_tuples->num_tuples > 0)
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lazy_vacuum(vacrel);
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@ -1816,13 +1817,14 @@ retry:
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* VACUUM can't run inside a transaction block, which makes some cases
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* impossible (e.g. in-progress insert from the same transaction).
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*
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* We treat LP_DEAD items a little differently, too -- we don't count
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* them as dead_tuples at all (we only consider new_dead_tuples). The
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* outcome is no different because we assume that any LP_DEAD items we
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* encounter here will become LP_UNUSED inside lazy_vacuum_heap_page()
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* before we report anything to the stats collector. (Cases where we
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* bypass index vacuuming will violate our assumption, but the overall
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* impact of that should be negligible.)
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* We treat LP_DEAD items (which are the closest thing to DEAD tuples
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* that might be seen here) differently, too: we assume that they'll
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* become LP_UNUSED before VACUUM finishes. This difference is only
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* superficial. VACUUM effectively agrees with ANALYZE about DEAD
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* items, in the end. VACUUM won't remember LP_DEAD items, but only
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* because they're not supposed to be left behind when it is done.
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* (Cases where we bypass index vacuuming will violate this optimistic
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* assumption, but the overall impact of that should be negligible.)
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*/
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switch (res)
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{
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@ -2169,7 +2171,7 @@ lazy_vacuum(LVRelState *vacrel)
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/*
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* Failsafe case.
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*
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* we attempted index vacuuming, but didn't finish a full round/full
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* We attempted index vacuuming, but didn't finish a full round/full
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* index scan. This happens when relfrozenxid or relminmxid is too
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* far in the past.
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*
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@ -3448,8 +3450,8 @@ compute_max_dead_tuples(BlockNumber relblocks, bool hasindex)
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maxtuples = Min(maxtuples, MAXDEADTUPLES(MaxAllocSize));
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/* curious coding here to ensure the multiplication can't overflow */
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if ((BlockNumber) (maxtuples / LAZY_ALLOC_TUPLES) > relblocks)
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maxtuples = relblocks * LAZY_ALLOC_TUPLES;
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if ((BlockNumber) (maxtuples / MaxHeapTuplesPerPage) > relblocks)
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maxtuples = relblocks * MaxHeapTuplesPerPage;
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/* stay sane if small maintenance_work_mem */
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maxtuples = Max(maxtuples, MaxHeapTuplesPerPage);
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