LCOV - code coverage report
Current view: top level - src/backend/access/table - tableam.c (source / functions) Coverage Total Hit
Test: PostgreSQL 20devel Lines: 90.4 % 197 178
Test Date: 2026-07-03 19:57:34 Functions: 100.0 % 19 19
Legend: Lines:     hit not hit
Branches: + taken - not taken # not executed
Branches: 70.8 % 106 75

             Branch data     Line data    Source code
       1                 :             : /*----------------------------------------------------------------------
       2                 :             :  *
       3                 :             :  * tableam.c
       4                 :             :  *      Table access method routines too big to be inline functions.
       5                 :             :  *
       6                 :             :  * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
       7                 :             :  * Portions Copyright (c) 1994, Regents of the University of California
       8                 :             :  *
       9                 :             :  *
      10                 :             :  * IDENTIFICATION
      11                 :             :  *    src/backend/access/table/tableam.c
      12                 :             :  *
      13                 :             :  * NOTES
      14                 :             :  *    Note that most functions in here are documented in tableam.h, rather than
      15                 :             :  *    here. That's because there's a lot of inline functions in tableam.h and
      16                 :             :  *    it'd be harder to understand if one constantly had to switch between files.
      17                 :             :  *
      18                 :             :  *----------------------------------------------------------------------
      19                 :             :  */
      20                 :             : #include "postgres.h"
      21                 :             : 
      22                 :             : #include <math.h>
      23                 :             : 
      24                 :             : #include "access/syncscan.h"
      25                 :             : #include "access/tableam.h"
      26                 :             : #include "access/xact.h"
      27                 :             : #include "optimizer/optimizer.h"
      28                 :             : #include "optimizer/plancat.h"
      29                 :             : #include "port/pg_bitutils.h"
      30                 :             : #include "storage/bufmgr.h"
      31                 :             : #include "storage/shmem.h"
      32                 :             : #include "storage/smgr.h"
      33                 :             : 
      34                 :             : /*
      35                 :             :  * Constants to control the behavior of block allocation to parallel workers
      36                 :             :  * during a parallel seqscan.  Technically these values do not need to be
      37                 :             :  * powers of 2, but having them as powers of 2 makes the math more optimal
      38                 :             :  * and makes the ramp-down stepping more even.
      39                 :             :  */
      40                 :             : 
      41                 :             : /* The number of I/O chunks we try to break a parallel seqscan down into */
      42                 :             : #define PARALLEL_SEQSCAN_NCHUNKS            2048
      43                 :             : /* Ramp down size of allocations when we've only this number of chunks left */
      44                 :             : #define PARALLEL_SEQSCAN_RAMPDOWN_CHUNKS    64
      45                 :             : /* Cap the size of parallel I/O chunks to this number of blocks */
      46                 :             : #define PARALLEL_SEQSCAN_MAX_CHUNK_SIZE     8192
      47                 :             : 
      48                 :             : /* GUC variables */
      49                 :             : char       *default_table_access_method = DEFAULT_TABLE_ACCESS_METHOD;
      50                 :             : bool        synchronize_seqscans = true;
      51                 :             : 
      52                 :             : 
      53                 :             : /* ----------------------------------------------------------------------------
      54                 :             :  * Slot functions.
      55                 :             :  * ----------------------------------------------------------------------------
      56                 :             :  */
      57                 :             : 
      58                 :             : const TupleTableSlotOps *
      59                 :    18416675 : table_slot_callbacks(Relation relation)
      60                 :             : {
      61                 :             :     const TupleTableSlotOps *tts_cb;
      62                 :             : 
      63         [ +  + ]:    18416675 :     if (relation->rd_tableam)
      64                 :    18411610 :         tts_cb = relation->rd_tableam->slot_callbacks(relation);
      65         [ +  + ]:        5065 :     else if (relation->rd_rel->relkind == RELKIND_FOREIGN_TABLE)
      66                 :             :     {
      67                 :             :         /*
      68                 :             :          * Historically FDWs expect to store heap tuples in slots. Continue
      69                 :             :          * handing them one, to make it less painful to adapt FDWs to new
      70                 :             :          * versions. The cost of a heap slot over a virtual slot is pretty
      71                 :             :          * small.
      72                 :             :          */
      73                 :         224 :         tts_cb = &TTSOpsHeapTuple;
      74                 :             :     }
      75                 :             :     else
      76                 :             :     {
      77                 :             :         /*
      78                 :             :          * These need to be supported, as some parts of the code (like COPY)
      79                 :             :          * need to create slots for such relations too. It seems better to
      80                 :             :          * centralize the knowledge that a heap slot is the right thing in
      81                 :             :          * that case here.
      82                 :             :          */
      83                 :             :         Assert(relation->rd_rel->relkind == RELKIND_VIEW ||
      84                 :             :                relation->rd_rel->relkind == RELKIND_PARTITIONED_TABLE);
      85                 :        4841 :         tts_cb = &TTSOpsVirtual;
      86                 :             :     }
      87                 :             : 
      88                 :    18416675 :     return tts_cb;
      89                 :             : }
      90                 :             : 
      91                 :             : TupleTableSlot *
      92                 :    18108476 : table_slot_create(Relation relation, List **reglist)
      93                 :             : {
      94                 :             :     const TupleTableSlotOps *tts_cb;
      95                 :             :     TupleTableSlot *slot;
      96                 :             : 
      97                 :    18108476 :     tts_cb = table_slot_callbacks(relation);
      98                 :    18108476 :     slot = MakeSingleTupleTableSlot(RelationGetDescr(relation), tts_cb);
      99                 :             : 
     100         [ +  + ]:    18108476 :     if (reglist)
     101                 :      154531 :         *reglist = lappend(*reglist, slot);
     102                 :             : 
     103                 :    18108476 :     return slot;
     104                 :             : }
     105                 :             : 
     106                 :             : 
     107                 :             : /* ----------------------------------------------------------------------------
     108                 :             :  * Table scan functions.
     109                 :             :  * ----------------------------------------------------------------------------
     110                 :             :  */
     111                 :             : 
     112                 :             : TableScanDesc
     113                 :       47718 : table_beginscan_catalog(Relation relation, int nkeys, ScanKeyData *key)
     114                 :             : {
     115                 :       47718 :     uint32      flags = SO_TYPE_SEQSCAN |
     116                 :             :         SO_ALLOW_STRAT | SO_ALLOW_SYNC | SO_ALLOW_PAGEMODE | SO_TEMP_SNAPSHOT;
     117                 :       47718 :     Oid         relid = RelationGetRelid(relation);
     118                 :       47718 :     Snapshot    snapshot = RegisterSnapshot(GetCatalogSnapshot(relid));
     119                 :             : 
     120                 :       47718 :     return table_beginscan_common(relation, snapshot, nkeys, key,
     121                 :             :                                   NULL, flags, SO_NONE);
     122                 :             : }
     123                 :             : 
     124                 :             : 
     125                 :             : /* ----------------------------------------------------------------------------
     126                 :             :  * Parallel table scan related functions.
     127                 :             :  * ----------------------------------------------------------------------------
     128                 :             :  */
     129                 :             : 
     130                 :             : Size
     131                 :        1337 : table_parallelscan_estimate(Relation rel, Snapshot snapshot)
     132                 :             : {
     133                 :        1337 :     Size        sz = 0;
     134                 :             : 
     135         [ +  + ]:        1337 :     if (IsMVCCSnapshot(snapshot))
     136                 :        1210 :         sz = add_size(sz, EstimateSnapshotSpace(snapshot));
     137                 :             :     else
     138                 :             :         Assert(snapshot == SnapshotAny);
     139                 :             : 
     140                 :        1337 :     sz = add_size(sz, rel->rd_tableam->parallelscan_estimate(rel));
     141                 :             : 
     142                 :        1337 :     return sz;
     143                 :             : }
     144                 :             : 
     145                 :             : void
     146                 :        1337 : table_parallelscan_initialize(Relation rel, ParallelTableScanDesc pscan,
     147                 :             :                               Snapshot snapshot)
     148                 :             : {
     149                 :        1337 :     Size        snapshot_off = rel->rd_tableam->parallelscan_initialize(rel, pscan);
     150                 :             : 
     151                 :        1337 :     pscan->phs_snapshot_off = snapshot_off;
     152                 :             : 
     153         [ +  + ]:        1337 :     if (IsMVCCSnapshot(snapshot))
     154                 :             :     {
     155                 :        1210 :         SerializeSnapshot(snapshot, (char *) pscan + pscan->phs_snapshot_off);
     156                 :        1210 :         pscan->phs_snapshot_any = false;
     157                 :             :     }
     158                 :             :     else
     159                 :             :     {
     160                 :             :         Assert(snapshot == SnapshotAny);
     161                 :         127 :         pscan->phs_snapshot_any = true;
     162                 :             :     }
     163                 :        1337 : }
     164                 :             : 
     165                 :             : TableScanDesc
     166                 :        4438 : table_beginscan_parallel(Relation relation, ParallelTableScanDesc pscan,
     167                 :             :                          uint32 flags)
     168                 :             : {
     169                 :             :     Snapshot    snapshot;
     170                 :        4438 :     uint32      internal_flags = SO_TYPE_SEQSCAN |
     171                 :             :         SO_ALLOW_STRAT | SO_ALLOW_SYNC | SO_ALLOW_PAGEMODE;
     172                 :             : 
     173                 :             :     Assert(RelFileLocatorEquals(relation->rd_locator, pscan->phs_locator));
     174                 :             : 
     175         [ +  + ]:        4438 :     if (!pscan->phs_snapshot_any)
     176                 :             :     {
     177                 :             :         /* Snapshot was serialized -- restore it */
     178                 :        4167 :         snapshot = RestoreSnapshot((char *) pscan + pscan->phs_snapshot_off);
     179                 :        4167 :         RegisterSnapshot(snapshot);
     180                 :        4167 :         internal_flags |= SO_TEMP_SNAPSHOT;
     181                 :             :     }
     182                 :             :     else
     183                 :             :     {
     184                 :             :         /* SnapshotAny passed by caller (not serialized) */
     185                 :         271 :         snapshot = SnapshotAny;
     186                 :             :     }
     187                 :             : 
     188                 :        4438 :     return table_beginscan_common(relation, snapshot, 0, NULL,
     189                 :             :                                   pscan, internal_flags, flags);
     190                 :             : }
     191                 :             : 
     192                 :             : TableScanDesc
     193                 :          80 : table_beginscan_parallel_tidrange(Relation relation,
     194                 :             :                                   ParallelTableScanDesc pscan,
     195                 :             :                                   uint32 flags)
     196                 :             : {
     197                 :             :     Snapshot    snapshot;
     198                 :             :     TableScanDesc sscan;
     199                 :          80 :     uint32      internal_flags = SO_TYPE_TIDRANGESCAN | SO_ALLOW_PAGEMODE;
     200                 :             : 
     201                 :             :     Assert(RelFileLocatorEquals(relation->rd_locator, pscan->phs_locator));
     202                 :             : 
     203                 :             :     /* disable syncscan in parallel tid range scan. */
     204                 :          80 :     pscan->phs_syncscan = false;
     205                 :             : 
     206         [ +  - ]:          80 :     if (!pscan->phs_snapshot_any)
     207                 :             :     {
     208                 :             :         /* Snapshot was serialized -- restore it */
     209                 :          80 :         snapshot = RestoreSnapshot((char *) pscan + pscan->phs_snapshot_off);
     210                 :          80 :         RegisterSnapshot(snapshot);
     211                 :          80 :         internal_flags |= SO_TEMP_SNAPSHOT;
     212                 :             :     }
     213                 :             :     else
     214                 :             :     {
     215                 :             :         /* SnapshotAny passed by caller (not serialized) */
     216                 :           0 :         snapshot = SnapshotAny;
     217                 :             :     }
     218                 :             : 
     219                 :          80 :     sscan = table_beginscan_common(relation, snapshot, 0, NULL,
     220                 :             :                                    pscan, internal_flags, flags);
     221                 :          80 :     return sscan;
     222                 :             : }
     223                 :             : 
     224                 :             : 
     225                 :             : /* ----------------------------------------------------------------------------
     226                 :             :  * Index scan related functions.
     227                 :             :  * ----------------------------------------------------------------------------
     228                 :             :  */
     229                 :             : 
     230                 :             : /*
     231                 :             :  * To perform that check simply start an index scan, create the necessary
     232                 :             :  * slot, do the heap lookup, and shut everything down again. This could be
     233                 :             :  * optimized, but is unlikely to matter from a performance POV. If there
     234                 :             :  * frequently are live index pointers also matching a unique index key, the
     235                 :             :  * CPU overhead of this routine is unlikely to matter.
     236                 :             :  *
     237                 :             :  * Note that *tid may be modified when we return true if the AM supports
     238                 :             :  * storing multiple row versions reachable via a single index entry (like
     239                 :             :  * heap's HOT).
     240                 :             :  */
     241                 :             : bool
     242                 :     7601687 : table_index_fetch_tuple_check(Relation rel,
     243                 :             :                               ItemPointer tid,
     244                 :             :                               Snapshot snapshot,
     245                 :             :                               bool *all_dead)
     246                 :             : {
     247                 :             :     IndexFetchTableData *scan;
     248                 :             :     TupleTableSlot *slot;
     249                 :     7601687 :     bool        call_again = false;
     250                 :             :     bool        found;
     251                 :             : 
     252                 :     7601687 :     slot = table_slot_create(rel, NULL);
     253                 :     7601687 :     scan = table_index_fetch_begin(rel, SO_NONE);
     254                 :     7601687 :     found = table_index_fetch_tuple(scan, tid, snapshot, slot, &call_again,
     255                 :             :                                     all_dead);
     256                 :     7601687 :     table_index_fetch_end(scan);
     257                 :     7601687 :     ExecDropSingleTupleTableSlot(slot);
     258                 :             : 
     259                 :     7601687 :     return found;
     260                 :             : }
     261                 :             : 
     262                 :             : 
     263                 :             : /* ------------------------------------------------------------------------
     264                 :             :  * Functions for non-modifying operations on individual tuples
     265                 :             :  * ------------------------------------------------------------------------
     266                 :             :  */
     267                 :             : 
     268                 :             : void
     269                 :         215 : table_tuple_get_latest_tid(TableScanDesc scan, ItemPointer tid)
     270                 :             : {
     271                 :         215 :     Relation    rel = scan->rs_rd;
     272                 :         215 :     const TableAmRoutine *tableam = rel->rd_tableam;
     273                 :             : 
     274                 :             :     /*
     275                 :             :      * Since this can be called with user-supplied TID, don't trust the input
     276                 :             :      * too much.
     277                 :             :      */
     278         [ +  + ]:         215 :     if (!tableam->tuple_tid_valid(scan, tid))
     279         [ +  - ]:           8 :         ereport(ERROR,
     280                 :             :                 (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
     281                 :             :                  errmsg("tid (%u, %u) is not valid for relation \"%s\"",
     282                 :             :                         ItemPointerGetBlockNumberNoCheck(tid),
     283                 :             :                         ItemPointerGetOffsetNumberNoCheck(tid),
     284                 :             :                         RelationGetRelationName(rel))));
     285                 :             : 
     286                 :         207 :     tableam->tuple_get_latest_tid(scan, tid);
     287                 :         207 : }
     288                 :             : 
     289                 :             : 
     290                 :             : /* ----------------------------------------------------------------------------
     291                 :             :  * Functions to make modifications a bit simpler.
     292                 :             :  * ----------------------------------------------------------------------------
     293                 :             :  */
     294                 :             : 
     295                 :             : /*
     296                 :             :  * simple_table_tuple_insert - insert a tuple
     297                 :             :  *
     298                 :             :  * Currently, this routine differs from table_tuple_insert only in supplying a
     299                 :             :  * default command ID and not allowing access to the speedup options.
     300                 :             :  */
     301                 :             : void
     302                 :       96458 : simple_table_tuple_insert(Relation rel, TupleTableSlot *slot)
     303                 :             : {
     304                 :       96458 :     table_tuple_insert(rel, slot, GetCurrentCommandId(true), 0, NULL);
     305                 :       96458 : }
     306                 :             : 
     307                 :             : /*
     308                 :             :  * simple_table_tuple_delete - delete a tuple
     309                 :             :  *
     310                 :             :  * This routine may be used to delete a tuple when concurrent updates of
     311                 :             :  * the target tuple are not expected (for example, because we have a lock
     312                 :             :  * on the relation associated with the tuple).  Any failure is reported
     313                 :             :  * via ereport().
     314                 :             :  */
     315                 :             : void
     316                 :       40318 : simple_table_tuple_delete(Relation rel, ItemPointer tid, Snapshot snapshot)
     317                 :             : {
     318                 :             :     TM_Result   result;
     319                 :             :     TM_FailureData tmfd;
     320                 :             : 
     321                 :       40318 :     result = table_tuple_delete(rel, tid,
     322                 :             :                                 GetCurrentCommandId(true),
     323                 :             :                                 0, snapshot, InvalidSnapshot,
     324                 :             :                                 true /* wait for commit */ ,
     325                 :             :                                 &tmfd);
     326                 :             : 
     327   [ -  +  -  -  :       40318 :     switch (result)
                      - ]
     328                 :             :     {
     329                 :           0 :         case TM_SelfModified:
     330                 :             :             /* Tuple was already updated in current command? */
     331         [ #  # ]:           0 :             elog(ERROR, "tuple already updated by self");
     332                 :             :             break;
     333                 :             : 
     334                 :       40318 :         case TM_Ok:
     335                 :             :             /* done successfully */
     336                 :       40318 :             break;
     337                 :             : 
     338                 :           0 :         case TM_Updated:
     339         [ #  # ]:           0 :             elog(ERROR, "tuple concurrently updated");
     340                 :             :             break;
     341                 :             : 
     342                 :           0 :         case TM_Deleted:
     343         [ #  # ]:           0 :             elog(ERROR, "tuple concurrently deleted");
     344                 :             :             break;
     345                 :             : 
     346                 :           0 :         default:
     347         [ #  # ]:           0 :             elog(ERROR, "unrecognized table_tuple_delete status: %u", result);
     348                 :             :             break;
     349                 :             :     }
     350                 :       40318 : }
     351                 :             : 
     352                 :             : /*
     353                 :             :  * simple_table_tuple_update - replace a tuple
     354                 :             :  *
     355                 :             :  * This routine may be used to update a tuple when concurrent updates of
     356                 :             :  * the target tuple are not expected (for example, because we have a lock
     357                 :             :  * on the relation associated with the tuple).  Any failure is reported
     358                 :             :  * via ereport().
     359                 :             :  */
     360                 :             : void
     361                 :       31924 : simple_table_tuple_update(Relation rel, ItemPointer otid,
     362                 :             :                           TupleTableSlot *slot,
     363                 :             :                           Snapshot snapshot,
     364                 :             :                           TU_UpdateIndexes *update_indexes)
     365                 :             : {
     366                 :             :     TM_Result   result;
     367                 :             :     TM_FailureData tmfd;
     368                 :             :     LockTupleMode lockmode;
     369                 :             : 
     370                 :       31924 :     result = table_tuple_update(rel, otid, slot,
     371                 :             :                                 GetCurrentCommandId(true),
     372                 :             :                                 0, snapshot, InvalidSnapshot,
     373                 :             :                                 true /* wait for commit */ ,
     374                 :             :                                 &tmfd, &lockmode, update_indexes);
     375                 :             : 
     376   [ -  +  -  -  :       31924 :     switch (result)
                      - ]
     377                 :             :     {
     378                 :           0 :         case TM_SelfModified:
     379                 :             :             /* Tuple was already updated in current command? */
     380         [ #  # ]:           0 :             elog(ERROR, "tuple already updated by self");
     381                 :             :             break;
     382                 :             : 
     383                 :       31924 :         case TM_Ok:
     384                 :             :             /* done successfully */
     385                 :       31924 :             break;
     386                 :             : 
     387                 :           0 :         case TM_Updated:
     388         [ #  # ]:           0 :             elog(ERROR, "tuple concurrently updated");
     389                 :             :             break;
     390                 :             : 
     391                 :           0 :         case TM_Deleted:
     392         [ #  # ]:           0 :             elog(ERROR, "tuple concurrently deleted");
     393                 :             :             break;
     394                 :             : 
     395                 :           0 :         default:
     396         [ #  # ]:           0 :             elog(ERROR, "unrecognized table_tuple_update status: %u", result);
     397                 :             :             break;
     398                 :             :     }
     399                 :       31924 : }
     400                 :             : 
     401                 :             : 
     402                 :             : /* ----------------------------------------------------------------------------
     403                 :             :  * Helper functions to implement parallel scans for block oriented AMs.
     404                 :             :  * ----------------------------------------------------------------------------
     405                 :             :  */
     406                 :             : 
     407                 :             : Size
     408                 :        1337 : table_block_parallelscan_estimate(Relation rel)
     409                 :             : {
     410                 :        1337 :     return sizeof(ParallelBlockTableScanDescData);
     411                 :             : }
     412                 :             : 
     413                 :             : Size
     414                 :        1337 : table_block_parallelscan_initialize(Relation rel, ParallelTableScanDesc pscan)
     415                 :             : {
     416                 :        1337 :     ParallelBlockTableScanDesc bpscan = (ParallelBlockTableScanDesc) pscan;
     417                 :             : 
     418                 :        1337 :     bpscan->base.phs_locator = rel->rd_locator;
     419                 :        1337 :     bpscan->phs_nblocks = RelationGetNumberOfBlocks(rel);
     420                 :             :     /* compare phs_syncscan initialization to similar logic in initscan */
     421                 :        3681 :     bpscan->base.phs_syncscan = synchronize_seqscans &&
     422   [ +  +  +  - ]:        2344 :         !RelationUsesLocalBuffers(rel) &&
     423         [ +  + ]:        1007 :         bpscan->phs_nblocks > NBuffers / 4;
     424                 :        1337 :     SpinLockInit(&bpscan->phs_mutex);
     425                 :        1337 :     bpscan->phs_startblock = InvalidBlockNumber;
     426                 :        1337 :     bpscan->phs_numblock = InvalidBlockNumber;
     427                 :        1337 :     pg_atomic_init_u64(&bpscan->phs_nallocated, 0);
     428                 :             : 
     429                 :        1337 :     return sizeof(ParallelBlockTableScanDescData);
     430                 :             : }
     431                 :             : 
     432                 :             : void
     433                 :         152 : table_block_parallelscan_reinitialize(Relation rel, ParallelTableScanDesc pscan)
     434                 :             : {
     435                 :         152 :     ParallelBlockTableScanDesc bpscan = (ParallelBlockTableScanDesc) pscan;
     436                 :             : 
     437                 :         152 :     pg_atomic_write_u64(&bpscan->phs_nallocated, 0);
     438                 :         152 : }
     439                 :             : 
     440                 :             : /*
     441                 :             :  * find and set the scan's startblock
     442                 :             :  *
     443                 :             :  * Determine where the parallel seq scan should start.  This function may be
     444                 :             :  * called many times, once by each parallel worker.  We must be careful only
     445                 :             :  * to set the phs_startblock and phs_numblock fields once.
     446                 :             :  *
     447                 :             :  * Callers may optionally specify a non-InvalidBlockNumber value for
     448                 :             :  * 'startblock' to force the scan to start at the given page.  Likewise,
     449                 :             :  * 'numblocks' can be specified as a non-InvalidBlockNumber to limit the
     450                 :             :  * number of blocks to scan to that many blocks.
     451                 :             :  */
     452                 :             : void
     453                 :        2808 : table_block_parallelscan_startblock_init(Relation rel,
     454                 :             :                                          ParallelBlockTableScanWorker pbscanwork,
     455                 :             :                                          ParallelBlockTableScanDesc pbscan,
     456                 :             :                                          BlockNumber startblock,
     457                 :             :                                          BlockNumber numblocks)
     458                 :             : {
     459                 :             :     StaticAssertDecl(MaxBlockNumber <= 0xFFFFFFFE,
     460                 :             :                      "pg_nextpower2_32 may be too small for non-standard BlockNumber width");
     461                 :             : 
     462                 :        2808 :     BlockNumber sync_startpage = InvalidBlockNumber;
     463                 :             :     BlockNumber scan_nblocks;
     464                 :             : 
     465                 :             :     /* Reset the state we use for controlling allocation size. */
     466                 :        2808 :     memset(pbscanwork, 0, sizeof(*pbscanwork));
     467                 :             : 
     468                 :        2810 : retry:
     469                 :             :     /* Grab the spinlock. */
     470                 :        2810 :     SpinLockAcquire(&pbscan->phs_mutex);
     471                 :             : 
     472                 :             :     /*
     473                 :             :      * When the caller specified a limit on the number of blocks to scan, set
     474                 :             :      * that in the ParallelBlockTableScanDesc, if it's not been done by
     475                 :             :      * another worker already.
     476                 :             :      */
     477         [ +  + ]:        2810 :     if (numblocks != InvalidBlockNumber &&
     478         [ +  + ]:          80 :         pbscan->phs_numblock == InvalidBlockNumber)
     479                 :             :     {
     480                 :          16 :         pbscan->phs_numblock = numblocks;
     481                 :             :     }
     482                 :             : 
     483                 :             :     /*
     484                 :             :      * If the scan's phs_startblock has not yet been initialized, we must do
     485                 :             :      * so now.  If a startblock was specified, start there, otherwise if this
     486                 :             :      * is not a synchronized scan, we just start at block 0, but if it is a
     487                 :             :      * synchronized scan, we must get the starting position from the
     488                 :             :      * synchronized scan machinery.  We can't hold the spinlock while doing
     489                 :             :      * that, though, so release the spinlock, get the information we need, and
     490                 :             :      * retry.  If nobody else has initialized the scan in the meantime, we'll
     491                 :             :      * fill in the value we fetched on the second time through.
     492                 :             :      */
     493         [ +  + ]:        2810 :     if (pbscan->phs_startblock == InvalidBlockNumber)
     494                 :             :     {
     495         [ +  + ]:        1326 :         if (startblock != InvalidBlockNumber)
     496                 :          16 :             pbscan->phs_startblock = startblock;
     497         [ +  + ]:        1310 :         else if (!pbscan->base.phs_syncscan)
     498                 :        1306 :             pbscan->phs_startblock = 0;
     499         [ +  + ]:           4 :         else if (sync_startpage != InvalidBlockNumber)
     500                 :           2 :             pbscan->phs_startblock = sync_startpage;
     501                 :             :         else
     502                 :             :         {
     503                 :           2 :             SpinLockRelease(&pbscan->phs_mutex);
     504                 :           2 :             sync_startpage = ss_get_location(rel, pbscan->phs_nblocks);
     505                 :           2 :             goto retry;
     506                 :             :         }
     507                 :             :     }
     508                 :        2808 :     SpinLockRelease(&pbscan->phs_mutex);
     509                 :             : 
     510                 :             :     /*
     511                 :             :      * Figure out how many blocks we're going to scan; either all of them, or
     512                 :             :      * just phs_numblock's worth, if a limit has been imposed.
     513                 :             :      */
     514         [ +  + ]:        2808 :     if (pbscan->phs_numblock == InvalidBlockNumber)
     515                 :        2728 :         scan_nblocks = pbscan->phs_nblocks;
     516                 :             :     else
     517                 :          80 :         scan_nblocks = pbscan->phs_numblock;
     518                 :             : 
     519                 :             :     /*
     520                 :             :      * We determine the chunk size based on scan_nblocks.  First we split
     521                 :             :      * scan_nblocks into PARALLEL_SEQSCAN_NCHUNKS chunks then we calculate the
     522                 :             :      * next highest power of 2 number of the result.  This means we split the
     523                 :             :      * blocks we're scanning into somewhere between PARALLEL_SEQSCAN_NCHUNKS
     524                 :             :      * and PARALLEL_SEQSCAN_NCHUNKS / 2 chunks.
     525                 :             :      */
     526         [ +  + ]:        2808 :     pbscanwork->phsw_chunk_size = pg_nextpower2_32(Max(scan_nblocks /
     527                 :             :                                                        PARALLEL_SEQSCAN_NCHUNKS, 1));
     528                 :             : 
     529                 :             :     /*
     530                 :             :      * Ensure we don't go over the maximum chunk size with larger tables. This
     531                 :             :      * means we may get much more than PARALLEL_SEQSCAN_NCHUNKS for larger
     532                 :             :      * tables.  Too large a chunk size has been shown to be detrimental to
     533                 :             :      * sequential scan performance.
     534                 :             :      */
     535                 :        2808 :     pbscanwork->phsw_chunk_size = Min(pbscanwork->phsw_chunk_size,
     536                 :             :                                       PARALLEL_SEQSCAN_MAX_CHUNK_SIZE);
     537                 :        2808 : }
     538                 :             : 
     539                 :             : /*
     540                 :             :  * get the next page to scan
     541                 :             :  *
     542                 :             :  * Get the next page to scan.  Even if there are no pages left to scan,
     543                 :             :  * another backend could have grabbed a page to scan and not yet finished
     544                 :             :  * looking at it, so it doesn't follow that the scan is done when the first
     545                 :             :  * backend gets an InvalidBlockNumber return.
     546                 :             :  */
     547                 :             : BlockNumber
     548                 :      146285 : table_block_parallelscan_nextpage(Relation rel,
     549                 :             :                                   ParallelBlockTableScanWorker pbscanwork,
     550                 :             :                                   ParallelBlockTableScanDesc pbscan)
     551                 :             : {
     552                 :             :     BlockNumber scan_nblocks;
     553                 :             :     BlockNumber page;
     554                 :             :     uint64      nallocated;
     555                 :             : 
     556                 :             :     /*
     557                 :             :      * The logic below allocates block numbers out to parallel workers in a
     558                 :             :      * way that each worker will receive a set of consecutive block numbers to
     559                 :             :      * scan.  Earlier versions of this would allocate the next highest block
     560                 :             :      * number to the next worker to call this function.  This would generally
     561                 :             :      * result in workers never receiving consecutive block numbers.  Some
     562                 :             :      * operating systems would not detect the sequential I/O pattern due to
     563                 :             :      * each backend being a different process which could result in poor
     564                 :             :      * performance due to inefficient or no readahead.  To work around this
     565                 :             :      * issue, we now allocate a range of block numbers for each worker and
     566                 :             :      * when they come back for another block, we give them the next one in
     567                 :             :      * that range until the range is complete.  When the worker completes the
     568                 :             :      * range of blocks we then allocate another range for it and return the
     569                 :             :      * first block number from that range.
     570                 :             :      *
     571                 :             :      * Here we name these ranges of blocks "chunks".  The initial size of
     572                 :             :      * these chunks is determined in table_block_parallelscan_startblock_init
     573                 :             :      * based on the number of blocks to scan.  Towards the end of the scan, we
     574                 :             :      * start making reductions in the size of the chunks in order to attempt
     575                 :             :      * to divide the remaining work over all the workers as evenly as
     576                 :             :      * possible.
     577                 :             :      *
     578                 :             :      * Here pbscanwork is local worker memory.  phsw_chunk_remaining tracks
     579                 :             :      * the number of blocks remaining in the chunk.  When that reaches 0 then
     580                 :             :      * we must allocate a new chunk for the worker.
     581                 :             :      *
     582                 :             :      * phs_nallocated tracks how many blocks have been allocated to workers
     583                 :             :      * already.  When phs_nallocated >= rs_nblocks, all blocks have been
     584                 :             :      * allocated.
     585                 :             :      *
     586                 :             :      * Because we use an atomic fetch-and-add to fetch the current value, the
     587                 :             :      * phs_nallocated counter will exceed rs_nblocks, because workers will
     588                 :             :      * still increment the value, when they try to allocate the next block but
     589                 :             :      * all blocks have been allocated already. The counter must be 64 bits
     590                 :             :      * wide because of that, to avoid wrapping around when scan_nblocks is
     591                 :             :      * close to 2^32.
     592                 :             :      *
     593                 :             :      * The actual block to return is calculated by adding the counter to the
     594                 :             :      * starting block number, modulo phs_nblocks.
     595                 :             :      */
     596                 :             : 
     597                 :             :     /* First, figure out how many blocks we're planning on scanning */
     598         [ +  + ]:      146285 :     if (pbscan->phs_numblock == InvalidBlockNumber)
     599                 :      145873 :         scan_nblocks = pbscan->phs_nblocks;
     600                 :             :     else
     601                 :         412 :         scan_nblocks = pbscan->phs_numblock;
     602                 :             : 
     603                 :             :     /*
     604                 :             :      * Now check if we have any remaining blocks in a previous chunk for this
     605                 :             :      * worker.  We must consume all of the blocks from that before we allocate
     606                 :             :      * a new chunk to the worker.
     607                 :             :      */
     608         [ +  + ]:      146285 :     if (pbscanwork->phsw_chunk_remaining > 0)
     609                 :             :     {
     610                 :             :         /*
     611                 :             :          * Give them the next block in the range and update the remaining
     612                 :             :          * number of blocks.
     613                 :             :          */
     614                 :       17946 :         nallocated = ++pbscanwork->phsw_nallocated;
     615                 :       17946 :         pbscanwork->phsw_chunk_remaining--;
     616                 :             :     }
     617                 :             :     else
     618                 :             :     {
     619                 :             :         /*
     620                 :             :          * When we've only got PARALLEL_SEQSCAN_RAMPDOWN_CHUNKS chunks
     621                 :             :          * remaining in the scan, we half the chunk size.  Since we reduce the
     622                 :             :          * chunk size here, we'll hit this again after doing
     623                 :             :          * PARALLEL_SEQSCAN_RAMPDOWN_CHUNKS at the new size.  After a few
     624                 :             :          * iterations of this, we'll end up doing the last few blocks with the
     625                 :             :          * chunk size set to 1.
     626                 :             :          */
     627         [ +  + ]:      128339 :         if (pbscanwork->phsw_chunk_size > 1 &&
     628                 :        3939 :             pbscanwork->phsw_nallocated > scan_nblocks -
     629         [ +  + ]:        3939 :             (pbscanwork->phsw_chunk_size * PARALLEL_SEQSCAN_RAMPDOWN_CHUNKS))
     630                 :          13 :             pbscanwork->phsw_chunk_size >>= 1;
     631                 :             : 
     632                 :      128339 :         nallocated = pbscanwork->phsw_nallocated =
     633                 :      128339 :             pg_atomic_fetch_add_u64(&pbscan->phs_nallocated,
     634                 :      128339 :                                     pbscanwork->phsw_chunk_size);
     635                 :             : 
     636                 :             :         /*
     637                 :             :          * Set the remaining number of blocks in this chunk so that subsequent
     638                 :             :          * calls from this worker continue on with this chunk until it's done.
     639                 :             :          */
     640                 :      128339 :         pbscanwork->phsw_chunk_remaining = pbscanwork->phsw_chunk_size - 1;
     641                 :             :     }
     642                 :             : 
     643                 :             :     /* Check if we've run out of blocks to scan */
     644         [ +  + ]:      146285 :     if (nallocated >= scan_nblocks)
     645                 :        2808 :         page = InvalidBlockNumber;  /* all blocks have been allocated */
     646                 :             :     else
     647                 :      143477 :         page = (nallocated + pbscan->phs_startblock) % pbscan->phs_nblocks;
     648                 :             : 
     649                 :             :     /*
     650                 :             :      * Report scan location.  Normally, we report the current page number.
     651                 :             :      * When we reach the end of the scan, though, we report the starting page,
     652                 :             :      * not the ending page, just so the starting positions for later scans
     653                 :             :      * doesn't slew backwards.  We only report the position at the end of the
     654                 :             :      * scan once, though: subsequent callers will report nothing.
     655                 :             :      */
     656         [ +  + ]:      146285 :     if (pbscan->base.phs_syncscan)
     657                 :             :     {
     658         [ +  + ]:       22130 :         if (page != InvalidBlockNumber)
     659                 :       22125 :             ss_report_location(rel, page);
     660         [ +  + ]:           5 :         else if (nallocated == pbscan->phs_nblocks)
     661                 :           2 :             ss_report_location(rel, pbscan->phs_startblock);
     662                 :             :     }
     663                 :             : 
     664                 :      146285 :     return page;
     665                 :             : }
     666                 :             : 
     667                 :             : /* ----------------------------------------------------------------------------
     668                 :             :  * Helper functions to implement relation sizing for block oriented AMs.
     669                 :             :  * ----------------------------------------------------------------------------
     670                 :             :  */
     671                 :             : 
     672                 :             : /*
     673                 :             :  * table_block_relation_size
     674                 :             :  *
     675                 :             :  * If a table AM uses the various relation forks as the sole place where data
     676                 :             :  * is stored, and if it uses them in the expected manner (e.g. the actual data
     677                 :             :  * is in the main fork rather than some other), it can use this implementation
     678                 :             :  * of the relation_size callback rather than implementing its own.
     679                 :             :  */
     680                 :             : uint64
     681                 :     1698001 : table_block_relation_size(Relation rel, ForkNumber forkNumber)
     682                 :             : {
     683                 :     1698001 :     uint64      nblocks = 0;
     684                 :             : 
     685                 :             :     /* InvalidForkNumber indicates returning the size for all forks */
     686         [ -  + ]:     1698001 :     if (forkNumber == InvalidForkNumber)
     687                 :             :     {
     688         [ #  # ]:           0 :         for (int i = 0; i < MAX_FORKNUM; i++)
     689                 :           0 :             nblocks += smgrnblocks(RelationGetSmgr(rel), i);
     690                 :             :     }
     691                 :             :     else
     692                 :     1698001 :         nblocks = smgrnblocks(RelationGetSmgr(rel), forkNumber);
     693                 :             : 
     694                 :     1697982 :     return nblocks * BLCKSZ;
     695                 :             : }
     696                 :             : 
     697                 :             : /*
     698                 :             :  * table_block_relation_estimate_size
     699                 :             :  *
     700                 :             :  * This function can't be directly used as the implementation of the
     701                 :             :  * relation_estimate_size callback, because it has a few additional parameters.
     702                 :             :  * Instead, it is intended to be used as a helper function; the caller can
     703                 :             :  * pass through the arguments to its relation_estimate_size function plus the
     704                 :             :  * additional values required here.
     705                 :             :  *
     706                 :             :  * overhead_bytes_per_tuple should contain the approximate number of bytes
     707                 :             :  * of storage required to store a tuple above and beyond what is required for
     708                 :             :  * the tuple data proper. Typically, this would include things like the
     709                 :             :  * size of the tuple header and item pointer. This is only used for query
     710                 :             :  * planning, so a table AM where the value is not constant could choose to
     711                 :             :  * pass a "best guess".
     712                 :             :  *
     713                 :             :  * usable_bytes_per_page should contain the approximate number of bytes per
     714                 :             :  * page usable for tuple data, excluding the page header and any anticipated
     715                 :             :  * special space.
     716                 :             :  */
     717                 :             : void
     718                 :      344974 : table_block_relation_estimate_size(Relation rel, int32 *attr_widths,
     719                 :             :                                    BlockNumber *pages, double *tuples,
     720                 :             :                                    double *allvisfrac,
     721                 :             :                                    Size overhead_bytes_per_tuple,
     722                 :             :                                    Size usable_bytes_per_page)
     723                 :             : {
     724                 :             :     BlockNumber curpages;
     725                 :             :     BlockNumber relpages;
     726                 :             :     double      reltuples;
     727                 :             :     BlockNumber relallvisible;
     728                 :             :     double      density;
     729                 :             : 
     730                 :             :     /* it should have storage, so we can call the smgr */
     731                 :      344974 :     curpages = RelationGetNumberOfBlocks(rel);
     732                 :             : 
     733                 :             :     /* coerce values in pg_class to more desirable types */
     734                 :      344974 :     relpages = (BlockNumber) rel->rd_rel->relpages;
     735                 :      344974 :     reltuples = (double) rel->rd_rel->reltuples;
     736                 :      344974 :     relallvisible = (BlockNumber) rel->rd_rel->relallvisible;
     737                 :             : 
     738                 :             :     /*
     739                 :             :      * HACK: if the relation has never yet been vacuumed, use a minimum size
     740                 :             :      * estimate of 10 pages.  The idea here is to avoid assuming a
     741                 :             :      * newly-created table is really small, even if it currently is, because
     742                 :             :      * that may not be true once some data gets loaded into it.  Once a vacuum
     743                 :             :      * or analyze cycle has been done on it, it's more reasonable to believe
     744                 :             :      * the size is somewhat stable.
     745                 :             :      *
     746                 :             :      * (Note that this is only an issue if the plan gets cached and used again
     747                 :             :      * after the table has been filled.  What we're trying to avoid is using a
     748                 :             :      * nestloop-type plan on a table that has grown substantially since the
     749                 :             :      * plan was made.  Normally, autovacuum/autoanalyze will occur once enough
     750                 :             :      * inserts have happened and cause cached-plan invalidation; but that
     751                 :             :      * doesn't happen instantaneously, and it won't happen at all for cases
     752                 :             :      * such as temporary tables.)
     753                 :             :      *
     754                 :             :      * We test "never vacuumed" by seeing whether reltuples < 0.
     755                 :             :      *
     756                 :             :      * If the table has inheritance children, we don't apply this heuristic.
     757                 :             :      * Totally empty parent tables are quite common, so we should be willing
     758                 :             :      * to believe that they are empty.
     759                 :             :      */
     760   [ +  +  +  + ]:      344974 :     if (curpages < 10 &&
     761                 :       90609 :         reltuples < 0 &&
     762         [ +  + ]:       90609 :         !rel->rd_rel->relhassubclass)
     763                 :       88370 :         curpages = 10;
     764                 :             : 
     765                 :             :     /* report estimated # pages */
     766                 :      344974 :     *pages = curpages;
     767                 :             :     /* quick exit if rel is clearly empty */
     768         [ +  + ]:      344974 :     if (curpages == 0)
     769                 :             :     {
     770                 :       16413 :         *tuples = 0;
     771                 :       16413 :         *allvisfrac = 0;
     772                 :       16413 :         return;
     773                 :             :     }
     774                 :             : 
     775                 :             :     /* estimate number of tuples from previous tuple density */
     776   [ +  +  +  + ]:      328561 :     if (reltuples >= 0 && relpages > 0)
     777                 :      200873 :         density = reltuples / (double) relpages;
     778                 :             :     else
     779                 :             :     {
     780                 :             :         /*
     781                 :             :          * When we have no data because the relation was never yet vacuumed,
     782                 :             :          * estimate tuple width from attribute datatypes.  We assume here that
     783                 :             :          * the pages are completely full, which is OK for tables but is
     784                 :             :          * probably an overestimate for indexes.  Fortunately
     785                 :             :          * get_relation_info() can clamp the overestimate to the parent
     786                 :             :          * table's size.
     787                 :             :          *
     788                 :             :          * Note: this code intentionally disregards alignment considerations,
     789                 :             :          * because (a) that would be gilding the lily considering how crude
     790                 :             :          * the estimate is, (b) it creates platform dependencies in the
     791                 :             :          * default plans which are kind of a headache for regression testing,
     792                 :             :          * and (c) different table AMs might use different padding schemes.
     793                 :             :          */
     794                 :             :         int32       tuple_width;
     795                 :             :         int         fillfactor;
     796                 :             : 
     797                 :             :         /*
     798                 :             :          * Without reltuples/relpages, we also need to consider fillfactor.
     799                 :             :          * The other branch considers it implicitly by calculating density
     800                 :             :          * from actual relpages/reltuples statistics.
     801                 :             :          */
     802         [ +  + ]:      127688 :         fillfactor = RelationGetFillFactor(rel, HEAP_DEFAULT_FILLFACTOR);
     803                 :             : 
     804                 :      127688 :         tuple_width = get_rel_data_width(rel, attr_widths);
     805                 :      127688 :         tuple_width += overhead_bytes_per_tuple;
     806                 :             :         /* note: integer division is intentional here */
     807                 :      127688 :         density = (usable_bytes_per_page * fillfactor / 100) / tuple_width;
     808                 :             :         /* There's at least one row on the page, even with low fillfactor. */
     809                 :      127688 :         density = clamp_row_est(density);
     810                 :             :     }
     811                 :      328561 :     *tuples = rint(density * (double) curpages);
     812                 :             : 
     813                 :             :     /*
     814                 :             :      * We use relallvisible as-is, rather than scaling it up like we do for
     815                 :             :      * the pages and tuples counts, on the theory that any pages added since
     816                 :             :      * the last VACUUM are most likely not marked all-visible.  But costsize.c
     817                 :             :      * wants it converted to a fraction.
     818                 :             :      */
     819   [ +  +  -  + ]:      328561 :     if (relallvisible == 0 || curpages <= 0)
     820                 :      169237 :         *allvisfrac = 0;
     821         [ +  + ]:      159324 :     else if ((double) relallvisible >= curpages)
     822                 :       83032 :         *allvisfrac = 1;
     823                 :             :     else
     824                 :       76292 :         *allvisfrac = (double) relallvisible / curpages;
     825                 :             : }
        

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