LCOV - code coverage report
Current view: top level - src/backend/utils/sort - tuplesort.c (source / functions) Coverage Total Hit
Test: PostgreSQL 20devel Lines: 91.6 % 912 835
Test Date: 2026-07-03 19:57:34 Functions: 100.0 % 57 57
Legend: Lines:     hit not hit
Branches: + taken - not taken # not executed
Branches: 69.9 % 522 365

             Branch data     Line data    Source code
       1                 :             : /*-------------------------------------------------------------------------
       2                 :             :  *
       3                 :             :  * tuplesort.c
       4                 :             :  *    Generalized tuple sorting routines.
       5                 :             :  *
       6                 :             :  * This module provides a generalized facility for tuple sorting, which can be
       7                 :             :  * applied to different kinds of sortable objects.  Implementation of
       8                 :             :  * the particular sorting variants is given in tuplesortvariants.c.
       9                 :             :  * This module works efficiently for both small and large amounts
      10                 :             :  * of data.  Small amounts are sorted in-memory.  Large amounts are
      11                 :             :  * sorted using temporary files and a standard external sort
      12                 :             :  * algorithm.
      13                 :             :  *
      14                 :             :  * See Knuth, volume 3, for more than you want to know about external
      15                 :             :  * sorting algorithms.  The algorithm we use is a balanced k-way merge.
      16                 :             :  * Before PostgreSQL 15, we used the polyphase merge algorithm (Knuth's
      17                 :             :  * Algorithm 5.4.2D), but with modern hardware, a straightforward balanced
      18                 :             :  * merge is better.  Knuth is assuming that tape drives are expensive
      19                 :             :  * beasts, and in particular that there will always be many more runs than
      20                 :             :  * tape drives.  The polyphase merge algorithm was good at keeping all the
      21                 :             :  * tape drives busy, but in our implementation a "tape drive" doesn't cost
      22                 :             :  * much more than a few Kb of memory buffers, so we can afford to have
      23                 :             :  * lots of them.  In particular, if we can have as many tape drives as
      24                 :             :  * sorted runs, we can eliminate any repeated I/O at all.
      25                 :             :  *
      26                 :             :  * Historically, we divided the input into sorted runs using replacement
      27                 :             :  * selection, in the form of a priority tree implemented as a heap
      28                 :             :  * (essentially Knuth's Algorithm 5.2.3H), but now we always use quicksort
      29                 :             :  * or radix sort for run generation.
      30                 :             :  *
      31                 :             :  * The approximate amount of memory allowed for any one sort operation
      32                 :             :  * is specified in kilobytes by the caller (most pass work_mem).  Initially,
      33                 :             :  * we absorb tuples and simply store them in an unsorted array as long as
      34                 :             :  * we haven't exceeded workMem.  If we reach the end of the input without
      35                 :             :  * exceeding workMem, we sort the array in memory and subsequently return
      36                 :             :  * tuples just by scanning the tuple array sequentially.  If we do exceed
      37                 :             :  * workMem, we begin to emit tuples into sorted runs in temporary tapes.
      38                 :             :  * When tuples are dumped in batch after in-memory sorting, we begin a new run
      39                 :             :  * with a new output tape.  If we reach the max number of tapes, we write
      40                 :             :  * subsequent runs on the existing tapes in a round-robin fashion.  We will
      41                 :             :  * need multiple merge passes to finish the merge in that case.  After the
      42                 :             :  * end of the input is reached, we dump out remaining tuples in memory into
      43                 :             :  * a final run, then merge the runs.
      44                 :             :  *
      45                 :             :  * When merging runs, we use a heap containing just the frontmost tuple from
      46                 :             :  * each source run; we repeatedly output the smallest tuple and replace it
      47                 :             :  * with the next tuple from its source tape (if any).  When the heap empties,
      48                 :             :  * the merge is complete.  The basic merge algorithm thus needs very little
      49                 :             :  * memory --- only M tuples for an M-way merge, and M is constrained to a
      50                 :             :  * small number.  However, we can still make good use of our full workMem
      51                 :             :  * allocation by pre-reading additional blocks from each source tape.  Without
      52                 :             :  * prereading, our access pattern to the temporary file would be very erratic;
      53                 :             :  * on average we'd read one block from each of M source tapes during the same
      54                 :             :  * time that we're writing M blocks to the output tape, so there is no
      55                 :             :  * sequentiality of access at all, defeating the read-ahead methods used by
      56                 :             :  * most Unix kernels.  Worse, the output tape gets written into a very random
      57                 :             :  * sequence of blocks of the temp file, ensuring that things will be even
      58                 :             :  * worse when it comes time to read that tape.  A straightforward merge pass
      59                 :             :  * thus ends up doing a lot of waiting for disk seeks.  We can improve matters
      60                 :             :  * by prereading from each source tape sequentially, loading about workMem/M
      61                 :             :  * bytes from each tape in turn, and making the sequential blocks immediately
      62                 :             :  * available for reuse.  This approach helps to localize both read and write
      63                 :             :  * accesses.  The pre-reading is handled by logtape.c, we just tell it how
      64                 :             :  * much memory to use for the buffers.
      65                 :             :  *
      66                 :             :  * In the current code we determine the number of input tapes M on the basis
      67                 :             :  * of workMem: we want workMem/M to be large enough that we read a fair
      68                 :             :  * amount of data each time we read from a tape, so as to maintain the
      69                 :             :  * locality of access described above.  Nonetheless, with large workMem we
      70                 :             :  * can have many tapes.  The logical "tapes" are implemented by logtape.c,
      71                 :             :  * which avoids space wastage by recycling disk space as soon as each block
      72                 :             :  * is read from its "tape".
      73                 :             :  *
      74                 :             :  * When the caller requests random access to the sort result, we form
      75                 :             :  * the final sorted run on a logical tape which is then "frozen", so
      76                 :             :  * that we can access it randomly.  When the caller does not need random
      77                 :             :  * access, we return from tuplesort_performsort() as soon as we are down
      78                 :             :  * to one run per logical tape.  The final merge is then performed
      79                 :             :  * on-the-fly as the caller repeatedly calls tuplesort_getXXX; this
      80                 :             :  * saves one cycle of writing all the data out to disk and reading it in.
      81                 :             :  *
      82                 :             :  * This module supports parallel sorting.  Parallel sorts involve coordination
      83                 :             :  * among one or more worker processes, and a leader process, each with its own
      84                 :             :  * tuplesort state.  The leader process (or, more accurately, the
      85                 :             :  * Tuplesortstate associated with a leader process) creates a full tapeset
      86                 :             :  * consisting of worker tapes with one run to merge; a run for every
      87                 :             :  * worker process.  This is then merged.  Worker processes are guaranteed to
      88                 :             :  * produce exactly one output run from their partial input.
      89                 :             :  *
      90                 :             :  *
      91                 :             :  * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
      92                 :             :  * Portions Copyright (c) 1994, Regents of the University of California
      93                 :             :  *
      94                 :             :  * IDENTIFICATION
      95                 :             :  *    src/backend/utils/sort/tuplesort.c
      96                 :             :  *
      97                 :             :  *-------------------------------------------------------------------------
      98                 :             :  */
      99                 :             : 
     100                 :             : #include "postgres.h"
     101                 :             : 
     102                 :             : #include <limits.h>
     103                 :             : 
     104                 :             : #include "commands/tablespace.h"
     105                 :             : #include "miscadmin.h"
     106                 :             : #include "pg_trace.h"
     107                 :             : #include "port/pg_bitutils.h"
     108                 :             : #include "storage/shmem.h"
     109                 :             : #include "utils/guc.h"
     110                 :             : #include "utils/memutils.h"
     111                 :             : #include "utils/pg_rusage.h"
     112                 :             : #include "utils/tuplesort.h"
     113                 :             : 
     114                 :             : /*
     115                 :             :  * Initial size of memtuples array.  This must be more than
     116                 :             :  * ALLOCSET_SEPARATE_THRESHOLD; see comments in grow_memtuples().  Clamp at
     117                 :             :  * 1024 elements to avoid excessive reallocs.
     118                 :             :  */
     119                 :             : #define INITIAL_MEMTUPSIZE Max(1024, \
     120                 :             :     ALLOCSET_SEPARATE_THRESHOLD / sizeof(SortTuple) + 1)
     121                 :             : 
     122                 :             : /* GUC variables */
     123                 :             : bool        trace_sort = false;
     124                 :             : 
     125                 :             : #ifdef DEBUG_BOUNDED_SORT
     126                 :             : bool        optimize_bounded_sort = true;
     127                 :             : #endif
     128                 :             : 
     129                 :             : 
     130                 :             : /*
     131                 :             :  * During merge, we use a pre-allocated set of fixed-size slots to hold
     132                 :             :  * tuples.  To avoid palloc/pfree overhead.
     133                 :             :  *
     134                 :             :  * Merge doesn't require a lot of memory, so we can afford to waste some,
     135                 :             :  * by using gratuitously-sized slots.  If a tuple is larger than 1 kB, the
     136                 :             :  * palloc() overhead is not significant anymore.
     137                 :             :  *
     138                 :             :  * 'nextfree' is valid when this chunk is in the free list.  When in use, the
     139                 :             :  * slot holds a tuple.
     140                 :             :  */
     141                 :             : #define SLAB_SLOT_SIZE 1024
     142                 :             : 
     143                 :             : typedef union SlabSlot
     144                 :             : {
     145                 :             :     union SlabSlot *nextfree;
     146                 :             :     char        buffer[SLAB_SLOT_SIZE];
     147                 :             : } SlabSlot;
     148                 :             : 
     149                 :             : /*
     150                 :             :  * Possible states of a Tuplesort object.  These denote the states that
     151                 :             :  * persist between calls of Tuplesort routines.
     152                 :             :  */
     153                 :             : typedef enum
     154                 :             : {
     155                 :             :     TSS_INITIAL,                /* Loading tuples; still within memory limit */
     156                 :             :     TSS_BOUNDED,                /* Loading tuples into bounded-size heap */
     157                 :             :     TSS_BUILDRUNS,              /* Loading tuples; writing to tape */
     158                 :             :     TSS_SORTEDINMEM,            /* Sort completed entirely in memory */
     159                 :             :     TSS_SORTEDONTAPE,           /* Sort completed, final run is on tape */
     160                 :             :     TSS_FINALMERGE,             /* Performing final merge on-the-fly */
     161                 :             : } TupSortStatus;
     162                 :             : 
     163                 :             : /*
     164                 :             :  * Parameters for calculation of number of tapes to use --- see inittapes()
     165                 :             :  * and tuplesort_merge_order().
     166                 :             :  *
     167                 :             :  * In this calculation we assume that each tape will cost us about 1 blocks
     168                 :             :  * worth of buffer space.  This ignores the overhead of all the other data
     169                 :             :  * structures needed for each tape, but it's probably close enough.
     170                 :             :  *
     171                 :             :  * MERGE_BUFFER_SIZE is how much buffer space we'd like to allocate for each
     172                 :             :  * input tape, for pre-reading (see discussion at top of file).  This is *in
     173                 :             :  * addition to* the 1 block already included in TAPE_BUFFER_OVERHEAD.
     174                 :             :  */
     175                 :             : #define MINORDER        6       /* minimum merge order */
     176                 :             : #define MAXORDER        500     /* maximum merge order */
     177                 :             : #define TAPE_BUFFER_OVERHEAD        BLCKSZ
     178                 :             : #define MERGE_BUFFER_SIZE           (BLCKSZ * 32)
     179                 :             : 
     180                 :             : 
     181                 :             : /*
     182                 :             :  * Private state of a Tuplesort operation.
     183                 :             :  */
     184                 :             : struct Tuplesortstate
     185                 :             : {
     186                 :             :     TuplesortPublic base;
     187                 :             :     TupSortStatus status;       /* enumerated value as shown above */
     188                 :             :     bool        bounded;        /* did caller specify a maximum number of
     189                 :             :                                  * tuples to return? */
     190                 :             :     bool        boundUsed;      /* true if we made use of a bounded heap */
     191                 :             :     int         bound;          /* if bounded, the maximum number of tuples */
     192                 :             :     int64       tupleMem;       /* memory consumed by individual tuples.
     193                 :             :                                  * storing this separately from what we track
     194                 :             :                                  * in availMem allows us to subtract the
     195                 :             :                                  * memory consumed by all tuples when dumping
     196                 :             :                                  * tuples to tape */
     197                 :             :     int64       availMem;       /* remaining memory available, in bytes */
     198                 :             :     int64       allowedMem;     /* total memory allowed, in bytes */
     199                 :             :     int         maxTapes;       /* max number of input tapes to merge in each
     200                 :             :                                  * pass */
     201                 :             :     int64       maxSpace;       /* maximum amount of space occupied among sort
     202                 :             :                                  * of groups, either in-memory or on-disk */
     203                 :             :     bool        isMaxSpaceDisk; /* true when maxSpace tracks on-disk space,
     204                 :             :                                  * false means in-memory */
     205                 :             :     TupSortStatus maxSpaceStatus;   /* sort status when maxSpace was reached */
     206                 :             :     LogicalTapeSet *tapeset;    /* logtape.c object for tapes in a temp file */
     207                 :             : 
     208                 :             :     /*
     209                 :             :      * This array holds the tuples now in sort memory.  If we are in state
     210                 :             :      * INITIAL, the tuples are in no particular order; if we are in state
     211                 :             :      * SORTEDINMEM, the tuples are in final sorted order; in states BUILDRUNS
     212                 :             :      * and FINALMERGE, the tuples are organized in "heap" order per Algorithm
     213                 :             :      * H.  In state SORTEDONTAPE, the array is not used.
     214                 :             :      */
     215                 :             :     SortTuple  *memtuples;      /* array of SortTuple structs */
     216                 :             :     int         memtupcount;    /* number of tuples currently present */
     217                 :             :     int         memtupsize;     /* allocated length of memtuples array */
     218                 :             :     bool        growmemtuples;  /* memtuples' growth still underway? */
     219                 :             : 
     220                 :             :     /*
     221                 :             :      * Memory for tuples is sometimes allocated using a simple slab allocator,
     222                 :             :      * rather than with palloc().  Currently, we switch to slab allocation
     223                 :             :      * when we start merging.  Merging only needs to keep a small, fixed
     224                 :             :      * number of tuples in memory at any time, so we can avoid the
     225                 :             :      * palloc/pfree overhead by recycling a fixed number of fixed-size slots
     226                 :             :      * to hold the tuples.
     227                 :             :      *
     228                 :             :      * For the slab, we use one large allocation, divided into SLAB_SLOT_SIZE
     229                 :             :      * slots.  The allocation is sized to have one slot per tape, plus one
     230                 :             :      * additional slot.  We need that many slots to hold all the tuples kept
     231                 :             :      * in the heap during merge, plus the one we have last returned from the
     232                 :             :      * sort, with tuplesort_gettuple.
     233                 :             :      *
     234                 :             :      * Initially, all the slots are kept in a linked list of free slots.  When
     235                 :             :      * a tuple is read from a tape, it is put to the next available slot, if
     236                 :             :      * it fits.  If the tuple is larger than SLAB_SLOT_SIZE, it is palloc'd
     237                 :             :      * instead.
     238                 :             :      *
     239                 :             :      * When we're done processing a tuple, we return the slot back to the free
     240                 :             :      * list, or pfree() if it was palloc'd.  We know that a tuple was
     241                 :             :      * allocated from the slab, if its pointer value is between
     242                 :             :      * slabMemoryBegin and -End.
     243                 :             :      *
     244                 :             :      * When the slab allocator is used, the USEMEM/LACKMEM mechanism of
     245                 :             :      * tracking memory usage is not used.
     246                 :             :      */
     247                 :             :     bool        slabAllocatorUsed;
     248                 :             : 
     249                 :             :     char       *slabMemoryBegin;    /* beginning of slab memory arena */
     250                 :             :     char       *slabMemoryEnd;  /* end of slab memory arena */
     251                 :             :     SlabSlot   *slabFreeHead;   /* head of free list */
     252                 :             : 
     253                 :             :     /* Memory used for input and output tape buffers. */
     254                 :             :     size_t      tape_buffer_mem;
     255                 :             : 
     256                 :             :     /*
     257                 :             :      * When we return a tuple to the caller in tuplesort_gettuple_XXX, that
     258                 :             :      * came from a tape (that is, in TSS_SORTEDONTAPE or TSS_FINALMERGE
     259                 :             :      * modes), we remember the tuple in 'lastReturnedTuple', so that we can
     260                 :             :      * recycle the memory on next gettuple call.
     261                 :             :      */
     262                 :             :     void       *lastReturnedTuple;
     263                 :             : 
     264                 :             :     /*
     265                 :             :      * While building initial runs, this is the current output run number.
     266                 :             :      * Afterwards, it is the number of initial runs we made.
     267                 :             :      */
     268                 :             :     int         currentRun;
     269                 :             : 
     270                 :             :     /*
     271                 :             :      * Logical tapes, for merging.
     272                 :             :      *
     273                 :             :      * The initial runs are written in the output tapes.  In each merge pass,
     274                 :             :      * the output tapes of the previous pass become the input tapes, and new
     275                 :             :      * output tapes are created as needed.  When nInputTapes equals
     276                 :             :      * nInputRuns, there is only one merge pass left.
     277                 :             :      */
     278                 :             :     LogicalTape **inputTapes;
     279                 :             :     int         nInputTapes;
     280                 :             :     int         nInputRuns;
     281                 :             : 
     282                 :             :     LogicalTape **outputTapes;
     283                 :             :     int         nOutputTapes;
     284                 :             :     int         nOutputRuns;
     285                 :             : 
     286                 :             :     LogicalTape *destTape;      /* current output tape */
     287                 :             : 
     288                 :             :     /*
     289                 :             :      * These variables are used after completion of sorting to keep track of
     290                 :             :      * the next tuple to return.  (In the tape case, the tape's current read
     291                 :             :      * position is also critical state.)
     292                 :             :      */
     293                 :             :     LogicalTape *result_tape;   /* actual tape of finished output */
     294                 :             :     int         current;        /* array index (only used if SORTEDINMEM) */
     295                 :             :     bool        eof_reached;    /* reached EOF (needed for cursors) */
     296                 :             : 
     297                 :             :     /* markpos_xxx holds marked position for mark and restore */
     298                 :             :     int64       markpos_block;  /* tape block# (only used if SORTEDONTAPE) */
     299                 :             :     int         markpos_offset; /* saved "current", or offset in tape block */
     300                 :             :     bool        markpos_eof;    /* saved "eof_reached" */
     301                 :             : 
     302                 :             :     /*
     303                 :             :      * These variables are used during parallel sorting.
     304                 :             :      *
     305                 :             :      * worker is our worker identifier.  Follows the general convention that
     306                 :             :      * -1 value relates to a leader tuplesort, and values >= 0 worker
     307                 :             :      * tuplesorts. (-1 can also be a serial tuplesort.)
     308                 :             :      *
     309                 :             :      * shared is mutable shared memory state, which is used to coordinate
     310                 :             :      * parallel sorts.
     311                 :             :      *
     312                 :             :      * nParticipants is the number of worker Tuplesortstates known by the
     313                 :             :      * leader to have actually been launched, which implies that they must
     314                 :             :      * finish a run that the leader needs to merge.  Typically includes a
     315                 :             :      * worker state held by the leader process itself.  Set in the leader
     316                 :             :      * Tuplesortstate only.
     317                 :             :      */
     318                 :             :     int         worker;
     319                 :             :     Sharedsort *shared;
     320                 :             :     int         nParticipants;
     321                 :             : 
     322                 :             :     /*
     323                 :             :      * Additional state for managing "abbreviated key" sortsupport routines
     324                 :             :      * (which currently may be used by all cases except the hash index case).
     325                 :             :      * Tracks the intervals at which the optimization's effectiveness is
     326                 :             :      * tested.
     327                 :             :      */
     328                 :             :     int64       abbrevNext;     /* Tuple # at which to next check
     329                 :             :                                  * applicability */
     330                 :             : 
     331                 :             :     /*
     332                 :             :      * Resource snapshot for time of sort start.
     333                 :             :      */
     334                 :             :     PGRUsage    ru_start;
     335                 :             : };
     336                 :             : 
     337                 :             : /*
     338                 :             :  * Private mutable state of tuplesort-parallel-operation.  This is allocated
     339                 :             :  * in shared memory.
     340                 :             :  */
     341                 :             : struct Sharedsort
     342                 :             : {
     343                 :             :     /* mutex protects all fields prior to tapes */
     344                 :             :     slock_t     mutex;
     345                 :             : 
     346                 :             :     /*
     347                 :             :      * currentWorker generates ordinal identifier numbers for parallel sort
     348                 :             :      * workers.  These start from 0, and are always gapless.
     349                 :             :      *
     350                 :             :      * Workers increment workersFinished to indicate having finished.  If this
     351                 :             :      * is equal to state.nParticipants within the leader, leader is ready to
     352                 :             :      * merge worker runs.
     353                 :             :      */
     354                 :             :     int         currentWorker;
     355                 :             :     int         workersFinished;
     356                 :             : 
     357                 :             :     /* Temporary file space */
     358                 :             :     SharedFileSet fileset;
     359                 :             : 
     360                 :             :     /* Size of tapes flexible array */
     361                 :             :     int         nTapes;
     362                 :             : 
     363                 :             :     /*
     364                 :             :      * Tapes array used by workers to report back information needed by the
     365                 :             :      * leader to concatenate all worker tapes into one for merging
     366                 :             :      */
     367                 :             :     TapeShare   tapes[FLEXIBLE_ARRAY_MEMBER];
     368                 :             : };
     369                 :             : 
     370                 :             : /*
     371                 :             :  * Is the given tuple allocated from the slab memory arena?
     372                 :             :  */
     373                 :             : #define IS_SLAB_SLOT(state, tuple) \
     374                 :             :     ((char *) (tuple) >= (state)->slabMemoryBegin && \
     375                 :             :      (char *) (tuple) < (state)->slabMemoryEnd)
     376                 :             : 
     377                 :             : /*
     378                 :             :  * Return the given tuple to the slab memory free list, or free it
     379                 :             :  * if it was palloc'd.
     380                 :             :  */
     381                 :             : #define RELEASE_SLAB_SLOT(state, tuple) \
     382                 :             :     do { \
     383                 :             :         SlabSlot *buf = (SlabSlot *) tuple; \
     384                 :             :         \
     385                 :             :         if (IS_SLAB_SLOT((state), buf)) \
     386                 :             :         { \
     387                 :             :             buf->nextfree = (state)->slabFreeHead; \
     388                 :             :             (state)->slabFreeHead = buf; \
     389                 :             :         } else \
     390                 :             :             pfree(buf); \
     391                 :             :     } while(0)
     392                 :             : 
     393                 :             : #define REMOVEABBREV(state,stup,count)  ((*(state)->base.removeabbrev) (state, stup, count))
     394                 :             : #define COMPARETUP(state,a,b)   ((*(state)->base.comparetup) (a, b, state))
     395                 :             : #define WRITETUP(state,tape,stup)   ((*(state)->base.writetup) (state, tape, stup))
     396                 :             : #define READTUP(state,stup,tape,len) ((*(state)->base.readtup) (state, stup, tape, len))
     397                 :             : #define FREESTATE(state)    ((state)->base.freestate ? (*(state)->base.freestate) (state) : (void) 0)
     398                 :             : #define LACKMEM(state)      ((state)->availMem < 0 && !(state)->slabAllocatorUsed)
     399                 :             : #define USEMEM(state,amt)   ((state)->availMem -= (amt))
     400                 :             : #define FREEMEM(state,amt)  ((state)->availMem += (amt))
     401                 :             : #define SERIAL(state)       ((state)->shared == NULL)
     402                 :             : #define WORKER(state)       ((state)->shared && (state)->worker != -1)
     403                 :             : #define LEADER(state)       ((state)->shared && (state)->worker == -1)
     404                 :             : 
     405                 :             : /*
     406                 :             :  * NOTES about on-tape representation of tuples:
     407                 :             :  *
     408                 :             :  * We require the first "unsigned int" of a stored tuple to be the total size
     409                 :             :  * on-tape of the tuple, including itself (so it is never zero; an all-zero
     410                 :             :  * unsigned int is used to delimit runs).  The remainder of the stored tuple
     411                 :             :  * may or may not match the in-memory representation of the tuple ---
     412                 :             :  * any conversion needed is the job of the writetup and readtup routines.
     413                 :             :  *
     414                 :             :  * If state->sortopt contains TUPLESORT_RANDOMACCESS, then the stored
     415                 :             :  * representation of the tuple must be followed by another "unsigned int" that
     416                 :             :  * is a copy of the length --- so the total tape space used is actually
     417                 :             :  * sizeof(unsigned int) more than the stored length value.  This allows
     418                 :             :  * read-backwards.  When the random access flag was not specified, the
     419                 :             :  * write/read routines may omit the extra length word.
     420                 :             :  *
     421                 :             :  * writetup is expected to write both length words as well as the tuple
     422                 :             :  * data.  When readtup is called, the tape is positioned just after the
     423                 :             :  * front length word; readtup must read the tuple data and advance past
     424                 :             :  * the back length word (if present).
     425                 :             :  *
     426                 :             :  * The write/read routines can make use of the tuple description data
     427                 :             :  * stored in the Tuplesortstate record, if needed.  They are also expected
     428                 :             :  * to adjust state->availMem by the amount of memory space (not tape space!)
     429                 :             :  * released or consumed.  There is no error return from either writetup
     430                 :             :  * or readtup; they should ereport() on failure.
     431                 :             :  *
     432                 :             :  *
     433                 :             :  * NOTES about memory consumption calculations:
     434                 :             :  *
     435                 :             :  * We count space allocated for tuples against the workMem limit, plus
     436                 :             :  * the space used by the variable-size memtuples array.  Fixed-size space
     437                 :             :  * is not counted; it's small enough to not be interesting.
     438                 :             :  *
     439                 :             :  * Note that we count actual space used (as shown by GetMemoryChunkSpace)
     440                 :             :  * rather than the originally-requested size.  This is important since
     441                 :             :  * palloc can add substantial overhead.  It's not a complete answer since
     442                 :             :  * we won't count any wasted space in palloc allocation blocks, but it's
     443                 :             :  * a lot better than what we were doing before 7.3.  As of 9.6, a
     444                 :             :  * separate memory context is used for caller passed tuples.  Resetting
     445                 :             :  * it at certain key increments significantly ameliorates fragmentation.
     446                 :             :  * readtup routines use the slab allocator (they cannot use
     447                 :             :  * the reset context because it gets deleted at the point that merging
     448                 :             :  * begins).
     449                 :             :  */
     450                 :             : 
     451                 :             : 
     452                 :             : static void tuplesort_begin_batch(Tuplesortstate *state);
     453                 :             : static bool consider_abort_common(Tuplesortstate *state);
     454                 :             : static void inittapes(Tuplesortstate *state, bool mergeruns);
     455                 :             : static void inittapestate(Tuplesortstate *state, int maxTapes);
     456                 :             : static void selectnewtape(Tuplesortstate *state);
     457                 :             : static void init_slab_allocator(Tuplesortstate *state, int numSlots);
     458                 :             : static void mergeruns(Tuplesortstate *state);
     459                 :             : static void mergeonerun(Tuplesortstate *state);
     460                 :             : static void beginmerge(Tuplesortstate *state);
     461                 :             : static bool mergereadnext(Tuplesortstate *state, LogicalTape *srcTape, SortTuple *stup);
     462                 :             : static void dumptuples(Tuplesortstate *state, bool alltuples);
     463                 :             : static void make_bounded_heap(Tuplesortstate *state);
     464                 :             : static void sort_bounded_heap(Tuplesortstate *state);
     465                 :             : static void tuplesort_sort_memtuples(Tuplesortstate *state);
     466                 :             : static void tuplesort_heap_insert(Tuplesortstate *state, SortTuple *tuple);
     467                 :             : static void tuplesort_heap_replace_top(Tuplesortstate *state, SortTuple *tuple);
     468                 :             : static void tuplesort_heap_delete_top(Tuplesortstate *state);
     469                 :             : static void reversedirection(Tuplesortstate *state);
     470                 :             : static unsigned int getlen(LogicalTape *tape, bool eofOK);
     471                 :             : static void markrunend(LogicalTape *tape);
     472                 :             : static int  worker_get_identifier(Tuplesortstate *state);
     473                 :             : static void worker_freeze_result_tape(Tuplesortstate *state);
     474                 :             : static void worker_nomergeruns(Tuplesortstate *state);
     475                 :             : static void leader_takeover_tapes(Tuplesortstate *state);
     476                 :             : static void free_sort_tuple(Tuplesortstate *state, SortTuple *stup);
     477                 :             : static void tuplesort_free(Tuplesortstate *state);
     478                 :             : static void tuplesort_updatemax(Tuplesortstate *state);
     479                 :             : 
     480                 :             : 
     481                 :             : /*
     482                 :             :  * Special versions of qsort just for SortTuple objects.  qsort_tuple() sorts
     483                 :             :  * any variant of SortTuples, using the appropriate comparetup function.
     484                 :             :  * qsort_ssup() is specialized for the case where the comparetup function
     485                 :             :  * reduces to ApplySortComparator(), that is single-key MinimalTuple sorts
     486                 :             :  * and Datum sorts.
     487                 :             :  */
     488                 :             : 
     489                 :             : #define ST_SORT qsort_tuple
     490                 :             : #define ST_ELEMENT_TYPE SortTuple
     491                 :             : #define ST_COMPARE_RUNTIME_POINTER
     492                 :             : #define ST_COMPARE_ARG_TYPE Tuplesortstate
     493                 :             : #define ST_CHECK_FOR_INTERRUPTS
     494                 :             : #define ST_SCOPE static
     495                 :             : #define ST_DECLARE
     496                 :             : #define ST_DEFINE
     497                 :             : #include "lib/sort_template.h"
     498                 :             : 
     499                 :             : #define ST_SORT qsort_ssup
     500                 :             : #define ST_ELEMENT_TYPE SortTuple
     501                 :             : #define ST_COMPARE(a, b, ssup) \
     502                 :             :     ApplySortComparator((a)->datum1, (a)->isnull1, \
     503                 :             :                         (b)->datum1, (b)->isnull1, (ssup))
     504                 :             : #define ST_COMPARE_ARG_TYPE SortSupportData
     505                 :             : #define ST_CHECK_FOR_INTERRUPTS
     506                 :             : #define ST_SCOPE static
     507                 :             : #define ST_DEFINE
     508                 :             : #include "lib/sort_template.h"
     509                 :             : 
     510                 :             : /* state for radix sort */
     511                 :             : typedef struct RadixSortInfo
     512                 :             : {
     513                 :             :     union
     514                 :             :     {
     515                 :             :         size_t      count;
     516                 :             :         size_t      offset;
     517                 :             :     };
     518                 :             :     size_t      next_offset;
     519                 :             : } RadixSortInfo;
     520                 :             : 
     521                 :             : /*
     522                 :             :  * Threshold below which qsort_tuple() is generally faster than a radix sort.
     523                 :             :  */
     524                 :             : #define QSORT_THRESHOLD 40
     525                 :             : 
     526                 :             : 
     527                 :             : /*
     528                 :             :  *      tuplesort_begin_xxx
     529                 :             :  *
     530                 :             :  * Initialize for a tuple sort operation.
     531                 :             :  *
     532                 :             :  * After calling tuplesort_begin, the caller should call tuplesort_putXXX
     533                 :             :  * zero or more times, then call tuplesort_performsort when all the tuples
     534                 :             :  * have been supplied.  After performsort, retrieve the tuples in sorted
     535                 :             :  * order by calling tuplesort_getXXX until it returns false/NULL.  (If random
     536                 :             :  * access was requested, rescan, markpos, and restorepos can also be called.)
     537                 :             :  * Call tuplesort_end to terminate the operation and release memory/disk space.
     538                 :             :  *
     539                 :             :  * Each variant of tuplesort_begin has a workMem parameter specifying the
     540                 :             :  * maximum number of kilobytes of RAM to use before spilling data to disk.
     541                 :             :  * (The normal value of this parameter is work_mem, but some callers use
     542                 :             :  * other values.)  Each variant also has a sortopt which is a bitmask of
     543                 :             :  * sort options.  See TUPLESORT_* definitions in tuplesort.h
     544                 :             :  */
     545                 :             : 
     546                 :             : Tuplesortstate *
     547                 :      175491 : tuplesort_begin_common(int workMem, SortCoordinate coordinate, int sortopt)
     548                 :             : {
     549                 :             :     Tuplesortstate *state;
     550                 :             :     MemoryContext maincontext;
     551                 :             :     MemoryContext sortcontext;
     552                 :             :     MemoryContext oldcontext;
     553                 :             : 
     554                 :             :     /* See leader_takeover_tapes() remarks on random access support */
     555   [ +  +  -  + ]:      175491 :     if (coordinate && (sortopt & TUPLESORT_RANDOMACCESS))
     556         [ #  # ]:           0 :         elog(ERROR, "random access disallowed under parallel sort");
     557                 :             : 
     558                 :             :     /*
     559                 :             :      * Memory context surviving tuplesort_reset.  This memory context holds
     560                 :             :      * data which is useful to keep while sorting multiple similar batches.
     561                 :             :      */
     562                 :      175491 :     maincontext = AllocSetContextCreate(CurrentMemoryContext,
     563                 :             :                                         "TupleSort main",
     564                 :             :                                         ALLOCSET_DEFAULT_SIZES);
     565                 :             : 
     566                 :             :     /*
     567                 :             :      * Create a working memory context for one sort operation.  The content of
     568                 :             :      * this context is deleted by tuplesort_reset.
     569                 :             :      */
     570                 :      175491 :     sortcontext = AllocSetContextCreate(maincontext,
     571                 :             :                                         "TupleSort sort",
     572                 :             :                                         ALLOCSET_DEFAULT_SIZES);
     573                 :             : 
     574                 :             :     /*
     575                 :             :      * Additionally a working memory context for tuples is setup in
     576                 :             :      * tuplesort_begin_batch.
     577                 :             :      */
     578                 :             : 
     579                 :             :     /*
     580                 :             :      * Make the Tuplesortstate within the per-sortstate context.  This way, we
     581                 :             :      * don't need a separate pfree() operation for it at shutdown.
     582                 :             :      */
     583                 :      175491 :     oldcontext = MemoryContextSwitchTo(maincontext);
     584                 :             : 
     585                 :      175491 :     state = palloc0_object(Tuplesortstate);
     586                 :             : 
     587         [ -  + ]:      175491 :     if (trace_sort)
     588                 :           0 :         pg_rusage_init(&state->ru_start);
     589                 :             : 
     590                 :      175491 :     state->base.sortopt = sortopt;
     591                 :      175491 :     state->base.tuples = true;
     592                 :      175491 :     state->abbrevNext = 10;
     593                 :             : 
     594                 :             :     /*
     595                 :             :      * workMem is forced to be at least 64KB, the current minimum valid value
     596                 :             :      * for the work_mem GUC.  This is a defense against parallel sort callers
     597                 :             :      * that divide out memory among many workers in a way that leaves each
     598                 :             :      * with very little memory.
     599                 :             :      */
     600                 :      175491 :     state->allowedMem = Max(workMem, 64) * (int64) 1024;
     601                 :      175491 :     state->base.sortcontext = sortcontext;
     602                 :      175491 :     state->base.maincontext = maincontext;
     603                 :             : 
     604                 :      175491 :     state->memtupsize = INITIAL_MEMTUPSIZE;
     605                 :      175491 :     state->memtuples = NULL;
     606                 :             : 
     607                 :             :     /*
     608                 :             :      * After all of the other non-parallel-related state, we setup all of the
     609                 :             :      * state needed for each batch.
     610                 :             :      */
     611                 :      175491 :     tuplesort_begin_batch(state);
     612                 :             : 
     613                 :             :     /*
     614                 :             :      * Initialize parallel-related state based on coordination information
     615                 :             :      * from caller
     616                 :             :      */
     617         [ +  + ]:      175491 :     if (!coordinate)
     618                 :             :     {
     619                 :             :         /* Serial sort */
     620                 :      174934 :         state->shared = NULL;
     621                 :      174934 :         state->worker = -1;
     622                 :      174934 :         state->nParticipants = -1;
     623                 :             :     }
     624         [ +  + ]:         557 :     else if (coordinate->isWorker)
     625                 :             :     {
     626                 :             :         /* Parallel worker produces exactly one final run from all input */
     627                 :         379 :         state->shared = coordinate->sharedsort;
     628                 :         379 :         state->worker = worker_get_identifier(state);
     629                 :         379 :         state->nParticipants = -1;
     630                 :             :     }
     631                 :             :     else
     632                 :             :     {
     633                 :             :         /* Parallel leader state only used for final merge */
     634                 :         178 :         state->shared = coordinate->sharedsort;
     635                 :         178 :         state->worker = -1;
     636                 :         178 :         state->nParticipants = coordinate->nParticipants;
     637                 :             :         Assert(state->nParticipants >= 1);
     638                 :             :     }
     639                 :             : 
     640                 :      175491 :     MemoryContextSwitchTo(oldcontext);
     641                 :             : 
     642                 :      175491 :     return state;
     643                 :             : }
     644                 :             : 
     645                 :             : /*
     646                 :             :  *      tuplesort_begin_batch
     647                 :             :  *
     648                 :             :  * Setup, or reset, all state need for processing a new set of tuples with this
     649                 :             :  * sort state. Called both from tuplesort_begin_common (the first time sorting
     650                 :             :  * with this sort state) and tuplesort_reset (for subsequent usages).
     651                 :             :  */
     652                 :             : static void
     653                 :      177556 : tuplesort_begin_batch(Tuplesortstate *state)
     654                 :             : {
     655                 :             :     MemoryContext oldcontext;
     656                 :             : 
     657                 :      177556 :     oldcontext = MemoryContextSwitchTo(state->base.maincontext);
     658                 :             : 
     659                 :             :     /*
     660                 :             :      * Caller tuple (e.g. IndexTuple) memory context.
     661                 :             :      *
     662                 :             :      * A dedicated child context used exclusively for caller passed tuples
     663                 :             :      * eases memory management.  Resetting at key points reduces
     664                 :             :      * fragmentation. Note that the memtuples array of SortTuples is allocated
     665                 :             :      * in the parent context, not this context, because there is no need to
     666                 :             :      * free memtuples early.  For bounded sorts, tuples may be pfreed in any
     667                 :             :      * order, so we use a regular aset.c context so that it can make use of
     668                 :             :      * free'd memory.  When the sort is not bounded, we make use of a bump.c
     669                 :             :      * context as this keeps allocations more compact with less wastage.
     670                 :             :      * Allocations are also slightly more CPU efficient.
     671                 :             :      */
     672         [ +  + ]:      177556 :     if (TupleSortUseBumpTupleCxt(state->base.sortopt))
     673                 :      176678 :         state->base.tuplecontext = BumpContextCreate(state->base.sortcontext,
     674                 :             :                                                      "Caller tuples",
     675                 :             :                                                      ALLOCSET_DEFAULT_SIZES);
     676                 :             :     else
     677                 :         878 :         state->base.tuplecontext = AllocSetContextCreate(state->base.sortcontext,
     678                 :             :                                                          "Caller tuples",
     679                 :             :                                                          ALLOCSET_DEFAULT_SIZES);
     680                 :             : 
     681                 :             : 
     682                 :      177556 :     state->status = TSS_INITIAL;
     683                 :      177556 :     state->bounded = false;
     684                 :      177556 :     state->boundUsed = false;
     685                 :             : 
     686                 :      177556 :     state->availMem = state->allowedMem;
     687                 :             : 
     688                 :      177556 :     state->tapeset = NULL;
     689                 :             : 
     690                 :      177556 :     state->memtupcount = 0;
     691                 :             : 
     692                 :      177556 :     state->growmemtuples = true;
     693                 :      177556 :     state->slabAllocatorUsed = false;
     694   [ +  +  +  + ]:      177556 :     if (state->memtuples != NULL && state->memtupsize != INITIAL_MEMTUPSIZE)
     695                 :             :     {
     696                 :          48 :         pfree(state->memtuples);
     697                 :          48 :         state->memtuples = NULL;
     698                 :          48 :         state->memtupsize = INITIAL_MEMTUPSIZE;
     699                 :             :     }
     700         [ +  + ]:      177556 :     if (state->memtuples == NULL)
     701                 :             :     {
     702                 :      175539 :         state->memtuples = (SortTuple *) palloc(state->memtupsize * sizeof(SortTuple));
     703                 :      175539 :         USEMEM(state, GetMemoryChunkSpace(state->memtuples));
     704                 :             :     }
     705                 :             : 
     706                 :             :     /* workMem must be large enough for the minimal memtuples array */
     707   [ -  +  -  - ]:      177556 :     if (LACKMEM(state))
     708         [ #  # ]:           0 :         elog(ERROR, "insufficient memory allowed for sort");
     709                 :             : 
     710                 :      177556 :     state->currentRun = 0;
     711                 :             : 
     712                 :             :     /*
     713                 :             :      * Tape variables (inputTapes, outputTapes, etc.) will be initialized by
     714                 :             :      * inittapes(), if needed.
     715                 :             :      */
     716                 :             : 
     717                 :      177556 :     state->result_tape = NULL;   /* flag that result tape has not been formed */
     718                 :             : 
     719                 :      177556 :     MemoryContextSwitchTo(oldcontext);
     720                 :      177556 : }
     721                 :             : 
     722                 :             : /*
     723                 :             :  * tuplesort_set_bound
     724                 :             :  *
     725                 :             :  *  Advise tuplesort that at most the first N result tuples are required.
     726                 :             :  *
     727                 :             :  * Must be called before inserting any tuples.  (Actually, we could allow it
     728                 :             :  * as long as the sort hasn't spilled to disk, but there seems no need for
     729                 :             :  * delayed calls at the moment.)
     730                 :             :  *
     731                 :             :  * This is a hint only. The tuplesort may still return more tuples than
     732                 :             :  * requested.  Parallel leader tuplesorts will always ignore the hint.
     733                 :             :  */
     734                 :             : void
     735                 :         789 : tuplesort_set_bound(Tuplesortstate *state, int64 bound)
     736                 :             : {
     737                 :             :     /* Assert we're called before loading any tuples */
     738                 :             :     Assert(state->status == TSS_INITIAL && state->memtupcount == 0);
     739                 :             :     /* Assert we allow bounded sorts */
     740                 :             :     Assert(state->base.sortopt & TUPLESORT_ALLOWBOUNDED);
     741                 :             :     /* Can't set the bound twice, either */
     742                 :             :     Assert(!state->bounded);
     743                 :             :     /* Also, this shouldn't be called in a parallel worker */
     744                 :             :     Assert(!WORKER(state));
     745                 :             : 
     746                 :             :     /* Parallel leader allows but ignores hint */
     747   [ -  +  -  - ]:         789 :     if (LEADER(state))
     748                 :           0 :         return;
     749                 :             : 
     750                 :             : #ifdef DEBUG_BOUNDED_SORT
     751                 :             :     /* Honor GUC setting that disables the feature (for easy testing) */
     752                 :             :     if (!optimize_bounded_sort)
     753                 :             :         return;
     754                 :             : #endif
     755                 :             : 
     756                 :             :     /* We want to be able to compute bound * 2, so limit the setting */
     757         [ -  + ]:         789 :     if (bound > (int64) (INT_MAX / 2))
     758                 :           0 :         return;
     759                 :             : 
     760                 :         789 :     state->bounded = true;
     761                 :         789 :     state->bound = (int) bound;
     762                 :             : 
     763                 :             :     /*
     764                 :             :      * Bounded sorts are not an effective target for abbreviated key
     765                 :             :      * optimization.  Disable by setting state to be consistent with no
     766                 :             :      * abbreviation support.
     767                 :             :      */
     768                 :         789 :     state->base.sortKeys->abbrev_converter = NULL;
     769         [ +  + ]:         789 :     if (state->base.sortKeys->abbrev_full_comparator)
     770                 :          10 :         state->base.sortKeys->comparator = state->base.sortKeys->abbrev_full_comparator;
     771                 :             : 
     772                 :             :     /* Not strictly necessary, but be tidy */
     773                 :         789 :     state->base.sortKeys->abbrev_abort = NULL;
     774                 :         789 :     state->base.sortKeys->abbrev_full_comparator = NULL;
     775                 :             : }
     776                 :             : 
     777                 :             : /*
     778                 :             :  * tuplesort_used_bound
     779                 :             :  *
     780                 :             :  * Allow callers to find out if the sort state was able to use a bound.
     781                 :             :  */
     782                 :             : bool
     783                 :         247 : tuplesort_used_bound(Tuplesortstate *state)
     784                 :             : {
     785                 :         247 :     return state->boundUsed;
     786                 :             : }
     787                 :             : 
     788                 :             : /*
     789                 :             :  * tuplesort_free
     790                 :             :  *
     791                 :             :  *  Internal routine for freeing resources of tuplesort.
     792                 :             :  */
     793                 :             : static void
     794                 :      177369 : tuplesort_free(Tuplesortstate *state)
     795                 :             : {
     796                 :             :     /* context swap probably not needed, but let's be safe */
     797                 :      177369 :     MemoryContext oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
     798                 :             :     int64       spaceUsed;
     799                 :             : 
     800         [ +  + ]:      177369 :     if (state->tapeset)
     801                 :         599 :         spaceUsed = LogicalTapeSetBlocks(state->tapeset);
     802                 :             :     else
     803                 :      176770 :         spaceUsed = (state->allowedMem - state->availMem + 1023) / 1024;
     804                 :             : 
     805                 :             :     /*
     806                 :             :      * Delete temporary "tape" files, if any.
     807                 :             :      *
     808                 :             :      * We don't bother to destroy the individual tapes here. They will go away
     809                 :             :      * with the sortcontext.  (In TSS_FINALMERGE state, we have closed
     810                 :             :      * finished tapes already.)
     811                 :             :      */
     812         [ +  + ]:      177369 :     if (state->tapeset)
     813                 :         599 :         LogicalTapeSetClose(state->tapeset);
     814                 :             : 
     815         [ -  + ]:      177369 :     if (trace_sort)
     816                 :             :     {
     817         [ #  # ]:           0 :         if (state->tapeset)
     818   [ #  #  #  # ]:           0 :             elog(LOG, "%s of worker %d ended, %" PRId64 " disk blocks used: %s",
     819                 :             :                  SERIAL(state) ? "external sort" : "parallel external sort",
     820                 :             :                  state->worker, spaceUsed, pg_rusage_show(&state->ru_start));
     821                 :             :         else
     822   [ #  #  #  # ]:           0 :             elog(LOG, "%s of worker %d ended, %" PRId64 " KB used: %s",
     823                 :             :                  SERIAL(state) ? "internal sort" : "unperformed parallel sort",
     824                 :             :                  state->worker, spaceUsed, pg_rusage_show(&state->ru_start));
     825                 :             :     }
     826                 :             : 
     827                 :             :     TRACE_POSTGRESQL_SORT_DONE(state->tapeset != NULL, spaceUsed);
     828                 :             : 
     829         [ +  + ]:      177369 :     FREESTATE(state);
     830                 :      177369 :     MemoryContextSwitchTo(oldcontext);
     831                 :             : 
     832                 :             :     /*
     833                 :             :      * Free the per-sort memory context, thereby releasing all working memory.
     834                 :             :      */
     835                 :      177369 :     MemoryContextReset(state->base.sortcontext);
     836                 :      177369 : }
     837                 :             : 
     838                 :             : /*
     839                 :             :  * tuplesort_end
     840                 :             :  *
     841                 :             :  *  Release resources and clean up.
     842                 :             :  *
     843                 :             :  * NOTE: after calling this, any pointers returned by tuplesort_getXXX are
     844                 :             :  * pointing to garbage.  Be careful not to attempt to use or free such
     845                 :             :  * pointers afterwards!
     846                 :             :  */
     847                 :             : void
     848                 :      175304 : tuplesort_end(Tuplesortstate *state)
     849                 :             : {
     850                 :      175304 :     tuplesort_free(state);
     851                 :             : 
     852                 :             :     /*
     853                 :             :      * Free the main memory context, including the Tuplesortstate struct
     854                 :             :      * itself.
     855                 :             :      */
     856                 :      175304 :     MemoryContextDelete(state->base.maincontext);
     857                 :      175304 : }
     858                 :             : 
     859                 :             : /*
     860                 :             :  * tuplesort_updatemax
     861                 :             :  *
     862                 :             :  *  Update maximum resource usage statistics.
     863                 :             :  */
     864                 :             : static void
     865                 :        2329 : tuplesort_updatemax(Tuplesortstate *state)
     866                 :             : {
     867                 :             :     int64       spaceUsed;
     868                 :             :     bool        isSpaceDisk;
     869                 :             : 
     870                 :             :     /*
     871                 :             :      * Note: it might seem we should provide both memory and disk usage for a
     872                 :             :      * disk-based sort.  However, the current code doesn't track memory space
     873                 :             :      * accurately once we have begun to return tuples to the caller (since we
     874                 :             :      * don't account for pfree's the caller is expected to do), so we cannot
     875                 :             :      * rely on availMem in a disk sort.  This does not seem worth the overhead
     876                 :             :      * to fix.  Is it worth creating an API for the memory context code to
     877                 :             :      * tell us how much is actually used in sortcontext?
     878                 :             :      */
     879         [ +  + ]:        2329 :     if (state->tapeset)
     880                 :             :     {
     881                 :           4 :         isSpaceDisk = true;
     882                 :           4 :         spaceUsed = LogicalTapeSetBlocks(state->tapeset) * BLCKSZ;
     883                 :             :     }
     884                 :             :     else
     885                 :             :     {
     886                 :        2325 :         isSpaceDisk = false;
     887                 :        2325 :         spaceUsed = state->allowedMem - state->availMem;
     888                 :             :     }
     889                 :             : 
     890                 :             :     /*
     891                 :             :      * Sort evicts data to the disk when it wasn't able to fit that data into
     892                 :             :      * main memory.  This is why we assume space used on the disk to be more
     893                 :             :      * important for tracking resource usage than space used in memory. Note
     894                 :             :      * that the amount of space occupied by some tupleset on the disk might be
     895                 :             :      * less than amount of space occupied by the same tupleset in memory due
     896                 :             :      * to more compact representation.
     897                 :             :      */
     898   [ +  +  -  + ]:        2329 :     if ((isSpaceDisk && !state->isMaxSpaceDisk) ||
     899   [ +  -  +  + ]:        2325 :         (isSpaceDisk == state->isMaxSpaceDisk && spaceUsed > state->maxSpace))
     900                 :             :     {
     901                 :         329 :         state->maxSpace = spaceUsed;
     902                 :         329 :         state->isMaxSpaceDisk = isSpaceDisk;
     903                 :         329 :         state->maxSpaceStatus = state->status;
     904                 :             :     }
     905                 :        2329 : }
     906                 :             : 
     907                 :             : /*
     908                 :             :  * tuplesort_reset
     909                 :             :  *
     910                 :             :  *  Reset the tuplesort.  Reset all the data in the tuplesort, but leave the
     911                 :             :  *  meta-information in.  After tuplesort_reset, tuplesort is ready to start
     912                 :             :  *  a new sort.  This allows avoiding recreation of tuple sort states (and
     913                 :             :  *  save resources) when sorting multiple small batches.
     914                 :             :  */
     915                 :             : void
     916                 :        2065 : tuplesort_reset(Tuplesortstate *state)
     917                 :             : {
     918                 :        2065 :     tuplesort_updatemax(state);
     919                 :        2065 :     tuplesort_free(state);
     920                 :             : 
     921                 :             :     /*
     922                 :             :      * After we've freed up per-batch memory, re-setup all of the state common
     923                 :             :      * to both the first batch and any subsequent batch.
     924                 :             :      */
     925                 :        2065 :     tuplesort_begin_batch(state);
     926                 :             : 
     927                 :        2065 :     state->lastReturnedTuple = NULL;
     928                 :        2065 :     state->slabMemoryBegin = NULL;
     929                 :        2065 :     state->slabMemoryEnd = NULL;
     930                 :        2065 :     state->slabFreeHead = NULL;
     931                 :        2065 : }
     932                 :             : 
     933                 :             : /*
     934                 :             :  * Grow the memtuples[] array, if possible within our memory constraint.  We
     935                 :             :  * must not exceed INT_MAX tuples in memory or the caller-provided memory
     936                 :             :  * limit.  Return true if we were able to enlarge the array, false if not.
     937                 :             :  *
     938                 :             :  * Normally, at each increment we double the size of the array.  When doing
     939                 :             :  * that would exceed a limit, we attempt one last, smaller increase (and then
     940                 :             :  * clear the growmemtuples flag so we don't try any more).  That allows us to
     941                 :             :  * use memory as fully as permitted; sticking to the pure doubling rule could
     942                 :             :  * result in almost half going unused.  Because availMem moves around with
     943                 :             :  * tuple addition/removal, we need some rule to prevent making repeated small
     944                 :             :  * increases in memtupsize, which would just be useless thrashing.  The
     945                 :             :  * growmemtuples flag accomplishes that and also prevents useless
     946                 :             :  * recalculations in this function.
     947                 :             :  */
     948                 :             : static bool
     949                 :        5103 : grow_memtuples(Tuplesortstate *state)
     950                 :             : {
     951                 :             :     int         newmemtupsize;
     952                 :        5103 :     int         memtupsize = state->memtupsize;
     953                 :        5103 :     int64       memNowUsed = state->allowedMem - state->availMem;
     954                 :             : 
     955                 :             :     /* Forget it if we've already maxed out memtuples, per comment above */
     956         [ +  + ]:        5103 :     if (!state->growmemtuples)
     957                 :          90 :         return false;
     958                 :             : 
     959                 :             :     /* Select new value of memtupsize */
     960         [ +  + ]:        5013 :     if (memNowUsed <= state->availMem)
     961                 :             :     {
     962                 :             :         /*
     963                 :             :          * We've used no more than half of allowedMem; double our usage,
     964                 :             :          * clamping at INT_MAX tuples.
     965                 :             :          */
     966         [ +  - ]:        4919 :         if (memtupsize < INT_MAX / 2)
     967                 :        4919 :             newmemtupsize = memtupsize * 2;
     968                 :             :         else
     969                 :             :         {
     970                 :           0 :             newmemtupsize = INT_MAX;
     971                 :           0 :             state->growmemtuples = false;
     972                 :             :         }
     973                 :             :     }
     974                 :             :     else
     975                 :             :     {
     976                 :             :         /*
     977                 :             :          * This will be the last increment of memtupsize.  Abandon doubling
     978                 :             :          * strategy and instead increase as much as we safely can.
     979                 :             :          *
     980                 :             :          * To stay within allowedMem, we can't increase memtupsize by more
     981                 :             :          * than availMem / sizeof(SortTuple) elements.  In practice, we want
     982                 :             :          * to increase it by considerably less, because we need to leave some
     983                 :             :          * space for the tuples to which the new array slots will refer.  We
     984                 :             :          * assume the new tuples will be about the same size as the tuples
     985                 :             :          * we've already seen, and thus we can extrapolate from the space
     986                 :             :          * consumption so far to estimate an appropriate new size for the
     987                 :             :          * memtuples array.  The optimal value might be higher or lower than
     988                 :             :          * this estimate, but it's hard to know that in advance.  We again
     989                 :             :          * clamp at INT_MAX tuples.
     990                 :             :          *
     991                 :             :          * This calculation is safe against enlarging the array so much that
     992                 :             :          * LACKMEM becomes true, because the memory currently used includes
     993                 :             :          * the present array; thus, there would be enough allowedMem for the
     994                 :             :          * new array elements even if no other memory were currently used.
     995                 :             :          *
     996                 :             :          * We do the arithmetic in float8, because otherwise the product of
     997                 :             :          * memtupsize and allowedMem could overflow.  Any inaccuracy in the
     998                 :             :          * result should be insignificant; but even if we computed a
     999                 :             :          * completely insane result, the checks below will prevent anything
    1000                 :             :          * really bad from happening.
    1001                 :             :          */
    1002                 :             :         double      grow_ratio;
    1003                 :             : 
    1004                 :          94 :         grow_ratio = (double) state->allowedMem / (double) memNowUsed;
    1005         [ +  - ]:          94 :         if (memtupsize * grow_ratio < INT_MAX)
    1006                 :          94 :             newmemtupsize = (int) (memtupsize * grow_ratio);
    1007                 :             :         else
    1008                 :           0 :             newmemtupsize = INT_MAX;
    1009                 :             : 
    1010                 :             :         /* We won't make any further enlargement attempts */
    1011                 :          94 :         state->growmemtuples = false;
    1012                 :             :     }
    1013                 :             : 
    1014                 :             :     /* Must enlarge array by at least one element, else report failure */
    1015         [ -  + ]:        5013 :     if (newmemtupsize <= memtupsize)
    1016                 :           0 :         goto noalloc;
    1017                 :             : 
    1018                 :             :     /*
    1019                 :             :      * On a 32-bit machine, allowedMem could exceed MaxAllocHugeSize.  Clamp
    1020                 :             :      * to ensure our request won't be rejected.  Note that we can easily
    1021                 :             :      * exhaust address space before facing this outcome.  (This is presently
    1022                 :             :      * impossible due to guc.c's MAX_KILOBYTES limitation on work_mem, but
    1023                 :             :      * don't rely on that at this distance.)
    1024                 :             :      */
    1025         [ -  + ]:        5013 :     if ((Size) newmemtupsize >= MaxAllocHugeSize / sizeof(SortTuple))
    1026                 :             :     {
    1027                 :           0 :         newmemtupsize = (int) (MaxAllocHugeSize / sizeof(SortTuple));
    1028                 :           0 :         state->growmemtuples = false;    /* can't grow any more */
    1029                 :             :     }
    1030                 :             : 
    1031                 :             :     /*
    1032                 :             :      * We need to be sure that we do not cause LACKMEM to become true, else
    1033                 :             :      * the space management algorithm will go nuts.  The code above should
    1034                 :             :      * never generate a dangerous request, but to be safe, check explicitly
    1035                 :             :      * that the array growth fits within availMem.  (We could still cause
    1036                 :             :      * LACKMEM if the memory chunk overhead associated with the memtuples
    1037                 :             :      * array were to increase.  That shouldn't happen because we chose the
    1038                 :             :      * initial array size large enough to ensure that palloc will be treating
    1039                 :             :      * both old and new arrays as separate chunks.  But we'll check LACKMEM
    1040                 :             :      * explicitly below just in case.)
    1041                 :             :      */
    1042         [ -  + ]:        5013 :     if (state->availMem < (int64) ((newmemtupsize - memtupsize) * sizeof(SortTuple)))
    1043                 :           0 :         goto noalloc;
    1044                 :             : 
    1045                 :             :     /* OK, do it */
    1046                 :        5013 :     FREEMEM(state, GetMemoryChunkSpace(state->memtuples));
    1047                 :        5013 :     state->memtupsize = newmemtupsize;
    1048                 :        5013 :     state->memtuples = (SortTuple *)
    1049                 :        5013 :         repalloc_huge(state->memtuples,
    1050                 :        5013 :                       state->memtupsize * sizeof(SortTuple));
    1051                 :        5013 :     USEMEM(state, GetMemoryChunkSpace(state->memtuples));
    1052   [ -  +  -  - ]:        5013 :     if (LACKMEM(state))
    1053         [ #  # ]:           0 :         elog(ERROR, "unexpected out-of-memory situation in tuplesort");
    1054                 :        5013 :     return true;
    1055                 :             : 
    1056                 :           0 : noalloc:
    1057                 :             :     /* If for any reason we didn't realloc, shut off future attempts */
    1058                 :           0 :     state->growmemtuples = false;
    1059                 :           0 :     return false;
    1060                 :             : }
    1061                 :             : 
    1062                 :             : /*
    1063                 :             :  * Shared code for tuple and datum cases.
    1064                 :             :  */
    1065                 :             : void
    1066                 :    18945784 : tuplesort_puttuple_common(Tuplesortstate *state, SortTuple *tuple,
    1067                 :             :                           bool useAbbrev, Size tuplen)
    1068                 :             : {
    1069                 :    18945784 :     MemoryContext oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
    1070                 :             : 
    1071                 :             :     Assert(!LEADER(state));
    1072                 :             : 
    1073                 :             :     /* account for the memory used for this tuple */
    1074                 :    18945784 :     USEMEM(state, tuplen);
    1075                 :    18945784 :     state->tupleMem += tuplen;
    1076                 :             : 
    1077         [ +  + ]:    18945784 :     if (!useAbbrev)
    1078                 :             :     {
    1079                 :             :         /*
    1080                 :             :          * Leave ordinary Datum representation, or NULL value.  If there is a
    1081                 :             :          * converter it won't expect NULL values, and cost model is not
    1082                 :             :          * required to account for NULL, so in that case we avoid calling
    1083                 :             :          * converter and just set datum1 to zeroed representation (to be
    1084                 :             :          * consistent, and to support cheap inequality tests for NULL
    1085                 :             :          * abbreviated keys).
    1086                 :             :          */
    1087                 :             :     }
    1088         [ +  + ]:     2900601 :     else if (!consider_abort_common(state))
    1089                 :             :     {
    1090                 :             :         /* Store abbreviated key representation */
    1091                 :     2900537 :         tuple->datum1 = state->base.sortKeys->abbrev_converter(tuple->datum1,
    1092                 :             :                                                                state->base.sortKeys);
    1093                 :             :     }
    1094                 :             :     else
    1095                 :             :     {
    1096                 :             :         /*
    1097                 :             :          * Set state to be consistent with never trying abbreviation.
    1098                 :             :          *
    1099                 :             :          * Alter datum1 representation in already-copied tuples, so as to
    1100                 :             :          * ensure a consistent representation (current tuple was just
    1101                 :             :          * handled).  It does not matter if some dumped tuples are already
    1102                 :             :          * sorted on tape, since serialized tuples lack abbreviated keys
    1103                 :             :          * (TSS_BUILDRUNS state prevents control reaching here in any case).
    1104                 :             :          */
    1105                 :          64 :         REMOVEABBREV(state, state->memtuples, state->memtupcount);
    1106                 :             :     }
    1107                 :             : 
    1108   [ +  +  +  - ]:    18945784 :     switch (state->status)
    1109                 :             :     {
    1110                 :    16068621 :         case TSS_INITIAL:
    1111                 :             : 
    1112                 :             :             /*
    1113                 :             :              * Save the tuple into the unsorted array.  First, grow the array
    1114                 :             :              * as needed.  Note that we try to grow the array when there is
    1115                 :             :              * still one free slot remaining --- if we fail, there'll still be
    1116                 :             :              * room to store the incoming tuple, and then we'll switch to
    1117                 :             :              * tape-based operation.
    1118                 :             :              */
    1119         [ +  + ]:    16068621 :             if (state->memtupcount >= state->memtupsize - 1)
    1120                 :             :             {
    1121                 :        5103 :                 (void) grow_memtuples(state);
    1122                 :             :                 Assert(state->memtupcount < state->memtupsize);
    1123                 :             :             }
    1124                 :    16068621 :             state->memtuples[state->memtupcount++] = *tuple;
    1125                 :             : 
    1126                 :             :             /*
    1127                 :             :              * Check if it's time to switch over to a bounded heapsort. We do
    1128                 :             :              * so if the input tuple count exceeds twice the desired tuple
    1129                 :             :              * count (this is a heuristic for where heapsort becomes cheaper
    1130                 :             :              * than a quicksort), or if we've just filled workMem and have
    1131                 :             :              * enough tuples to meet the bound.
    1132                 :             :              *
    1133                 :             :              * Note that once we enter TSS_BOUNDED state we will always try to
    1134                 :             :              * complete the sort that way.  In the worst case, if later input
    1135                 :             :              * tuples are larger than earlier ones, this might cause us to
    1136                 :             :              * exceed workMem significantly.
    1137                 :             :              */
    1138         [ +  + ]:    16068621 :             if (state->bounded &&
    1139         [ +  + ]:       33322 :                 (state->memtupcount > state->bound * 2 ||
    1140   [ +  +  -  +  :       33066 :                  (state->memtupcount > state->bound && LACKMEM(state))))
                   -  - ]
    1141                 :             :             {
    1142         [ -  + ]:         256 :                 if (trace_sort)
    1143         [ #  # ]:           0 :                     elog(LOG, "switching to bounded heapsort at %d tuples: %s",
    1144                 :             :                          state->memtupcount,
    1145                 :             :                          pg_rusage_show(&state->ru_start));
    1146                 :         256 :                 make_bounded_heap(state);
    1147                 :         256 :                 MemoryContextSwitchTo(oldcontext);
    1148                 :         256 :                 return;
    1149                 :             :             }
    1150                 :             : 
    1151                 :             :             /*
    1152                 :             :              * Done if we still fit in available memory and have array slots.
    1153                 :             :              */
    1154   [ +  +  -  +  :    16068365 :             if (state->memtupcount < state->memtupsize && !LACKMEM(state))
                   -  - ]
    1155                 :             :             {
    1156                 :    16068275 :                 MemoryContextSwitchTo(oldcontext);
    1157                 :    16068275 :                 return;
    1158                 :             :             }
    1159                 :             : 
    1160                 :             :             /*
    1161                 :             :              * Nope; time to switch to tape-based operation.
    1162                 :             :              */
    1163                 :          90 :             inittapes(state, true);
    1164                 :             : 
    1165                 :             :             /*
    1166                 :             :              * Dump all tuples.
    1167                 :             :              */
    1168                 :          90 :             dumptuples(state, false);
    1169                 :          90 :             break;
    1170                 :             : 
    1171                 :     2143090 :         case TSS_BOUNDED:
    1172                 :             : 
    1173                 :             :             /*
    1174                 :             :              * We don't want to grow the array here, so check whether the new
    1175                 :             :              * tuple can be discarded before putting it in.  This should be a
    1176                 :             :              * good speed optimization, too, since when there are many more
    1177                 :             :              * input tuples than the bound, most input tuples can be discarded
    1178                 :             :              * with just this one comparison.  Note that because we currently
    1179                 :             :              * have the sort direction reversed, we must check for <= not >=.
    1180                 :             :              */
    1181         [ +  + ]:     2143090 :             if (COMPARETUP(state, tuple, &state->memtuples[0]) <= 0)
    1182                 :             :             {
    1183                 :             :                 /* new tuple <= top of the heap, so we can discard it */
    1184                 :     1808289 :                 free_sort_tuple(state, tuple);
    1185         [ -  + ]:     1808289 :                 CHECK_FOR_INTERRUPTS();
    1186                 :             :             }
    1187                 :             :             else
    1188                 :             :             {
    1189                 :             :                 /* discard top of heap, replacing it with the new tuple */
    1190                 :      334801 :                 free_sort_tuple(state, &state->memtuples[0]);
    1191                 :      334801 :                 tuplesort_heap_replace_top(state, tuple);
    1192                 :             :             }
    1193                 :     2143090 :             break;
    1194                 :             : 
    1195                 :      734073 :         case TSS_BUILDRUNS:
    1196                 :             : 
    1197                 :             :             /*
    1198                 :             :              * Save the tuple into the unsorted array (there must be space)
    1199                 :             :              */
    1200                 :      734073 :             state->memtuples[state->memtupcount++] = *tuple;
    1201                 :             : 
    1202                 :             :             /*
    1203                 :             :              * If we are over the memory limit, dump all tuples.
    1204                 :             :              */
    1205                 :      734073 :             dumptuples(state, false);
    1206                 :      734073 :             break;
    1207                 :             : 
    1208                 :           0 :         default:
    1209         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    1210                 :             :             break;
    1211                 :             :     }
    1212                 :     2877253 :     MemoryContextSwitchTo(oldcontext);
    1213                 :             : }
    1214                 :             : 
    1215                 :             : static bool
    1216                 :     2900601 : consider_abort_common(Tuplesortstate *state)
    1217                 :             : {
    1218                 :             :     Assert(state->base.sortKeys[0].abbrev_converter != NULL);
    1219                 :             :     Assert(state->base.sortKeys[0].abbrev_abort != NULL);
    1220                 :             :     Assert(state->base.sortKeys[0].abbrev_full_comparator != NULL);
    1221                 :             : 
    1222                 :             :     /*
    1223                 :             :      * Check effectiveness of abbreviation optimization.  Consider aborting
    1224                 :             :      * when still within memory limit.
    1225                 :             :      */
    1226         [ +  + ]:     2900601 :     if (state->status == TSS_INITIAL &&
    1227         [ +  + ]:     2598568 :         state->memtupcount >= state->abbrevNext)
    1228                 :             :     {
    1229                 :        3282 :         state->abbrevNext *= 2;
    1230                 :             : 
    1231                 :             :         /*
    1232                 :             :          * Check opclass-supplied abbreviation abort routine.  It may indicate
    1233                 :             :          * that abbreviation should not proceed.
    1234                 :             :          */
    1235         [ +  + ]:        3282 :         if (!state->base.sortKeys->abbrev_abort(state->memtupcount,
    1236                 :             :                                                 state->base.sortKeys))
    1237                 :        3218 :             return false;
    1238                 :             : 
    1239                 :             :         /*
    1240                 :             :          * Finally, restore authoritative comparator, and indicate that
    1241                 :             :          * abbreviation is not in play by setting abbrev_converter to NULL
    1242                 :             :          */
    1243                 :          64 :         state->base.sortKeys[0].comparator = state->base.sortKeys[0].abbrev_full_comparator;
    1244                 :          64 :         state->base.sortKeys[0].abbrev_converter = NULL;
    1245                 :             :         /* Not strictly necessary, but be tidy */
    1246                 :          64 :         state->base.sortKeys[0].abbrev_abort = NULL;
    1247                 :          64 :         state->base.sortKeys[0].abbrev_full_comparator = NULL;
    1248                 :             : 
    1249                 :             :         /* Give up - expect original pass-by-value representation */
    1250                 :          64 :         return true;
    1251                 :             :     }
    1252                 :             : 
    1253                 :     2897319 :     return false;
    1254                 :             : }
    1255                 :             : 
    1256                 :             : /*
    1257                 :             :  * All tuples have been provided; finish the sort.
    1258                 :             :  */
    1259                 :             : void
    1260                 :      150928 : tuplesort_performsort(Tuplesortstate *state)
    1261                 :             : {
    1262                 :      150928 :     MemoryContext oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
    1263                 :             : 
    1264         [ -  + ]:      150928 :     if (trace_sort)
    1265         [ #  # ]:           0 :         elog(LOG, "performsort of worker %d starting: %s",
    1266                 :             :              state->worker, pg_rusage_show(&state->ru_start));
    1267                 :             : 
    1268   [ +  +  +  - ]:      150928 :     switch (state->status)
    1269                 :             :     {
    1270                 :      150582 :         case TSS_INITIAL:
    1271                 :             : 
    1272                 :             :             /*
    1273                 :             :              * We were able to accumulate all the tuples within the allowed
    1274                 :             :              * amount of memory, or leader to take over worker tapes
    1275                 :             :              */
    1276         [ +  + ]:      150582 :             if (SERIAL(state))
    1277                 :             :             {
    1278                 :             :                 /* Sort in memory and we're done */
    1279                 :      150073 :                 tuplesort_sort_memtuples(state);
    1280                 :      150013 :                 state->status = TSS_SORTEDINMEM;
    1281                 :             :             }
    1282   [ +  -  +  + ]:         509 :             else if (WORKER(state))
    1283                 :             :             {
    1284                 :             :                 /*
    1285                 :             :                  * Parallel workers must still dump out tuples to tape.  No
    1286                 :             :                  * merge is required to produce single output run, though.
    1287                 :             :                  */
    1288                 :         379 :                 inittapes(state, false);
    1289                 :         379 :                 dumptuples(state, true);
    1290                 :         379 :                 worker_nomergeruns(state);
    1291                 :         379 :                 state->status = TSS_SORTEDONTAPE;
    1292                 :             :             }
    1293                 :             :             else
    1294                 :             :             {
    1295                 :             :                 /*
    1296                 :             :                  * Leader will take over worker tapes and merge worker runs.
    1297                 :             :                  * Note that mergeruns sets the correct state->status.
    1298                 :             :                  */
    1299                 :         130 :                 leader_takeover_tapes(state);
    1300                 :         130 :                 mergeruns(state);
    1301                 :             :             }
    1302                 :      150522 :             state->current = 0;
    1303                 :      150522 :             state->eof_reached = false;
    1304                 :      150522 :             state->markpos_block = 0L;
    1305                 :      150522 :             state->markpos_offset = 0;
    1306                 :      150522 :             state->markpos_eof = false;
    1307                 :      150522 :             break;
    1308                 :             : 
    1309                 :         256 :         case TSS_BOUNDED:
    1310                 :             : 
    1311                 :             :             /*
    1312                 :             :              * We were able to accumulate all the tuples required for output
    1313                 :             :              * in memory, using a heap to eliminate excess tuples.  Now we
    1314                 :             :              * have to transform the heap to a properly-sorted array. Note
    1315                 :             :              * that sort_bounded_heap sets the correct state->status.
    1316                 :             :              */
    1317                 :         256 :             sort_bounded_heap(state);
    1318                 :         256 :             state->current = 0;
    1319                 :         256 :             state->eof_reached = false;
    1320                 :         256 :             state->markpos_offset = 0;
    1321                 :         256 :             state->markpos_eof = false;
    1322                 :         256 :             break;
    1323                 :             : 
    1324                 :          90 :         case TSS_BUILDRUNS:
    1325                 :             : 
    1326                 :             :             /*
    1327                 :             :              * Finish tape-based sort.  First, flush all tuples remaining in
    1328                 :             :              * memory out to tape; then merge until we have a single remaining
    1329                 :             :              * run (or, if !randomAccess and !WORKER(), one run per tape).
    1330                 :             :              * Note that mergeruns sets the correct state->status.
    1331                 :             :              */
    1332                 :          90 :             dumptuples(state, true);
    1333                 :          90 :             mergeruns(state);
    1334                 :          90 :             state->eof_reached = false;
    1335                 :          90 :             state->markpos_block = 0L;
    1336                 :          90 :             state->markpos_offset = 0;
    1337                 :          90 :             state->markpos_eof = false;
    1338                 :          90 :             break;
    1339                 :             : 
    1340                 :           0 :         default:
    1341         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    1342                 :             :             break;
    1343                 :             :     }
    1344                 :             : 
    1345         [ -  + ]:      150868 :     if (trace_sort)
    1346                 :             :     {
    1347         [ #  # ]:           0 :         if (state->status == TSS_FINALMERGE)
    1348         [ #  # ]:           0 :             elog(LOG, "performsort of worker %d done (except %d-way final merge): %s",
    1349                 :             :                  state->worker, state->nInputTapes,
    1350                 :             :                  pg_rusage_show(&state->ru_start));
    1351                 :             :         else
    1352         [ #  # ]:           0 :             elog(LOG, "performsort of worker %d done: %s",
    1353                 :             :                  state->worker, pg_rusage_show(&state->ru_start));
    1354                 :             :     }
    1355                 :             : 
    1356                 :      150868 :     MemoryContextSwitchTo(oldcontext);
    1357                 :      150868 : }
    1358                 :             : 
    1359                 :             : /*
    1360                 :             :  * Internal routine to fetch the next tuple in either forward or back
    1361                 :             :  * direction into *stup.  Returns false if no more tuples.
    1362                 :             :  * Returned tuple belongs to tuplesort memory context, and must not be freed
    1363                 :             :  * by caller.  Note that fetched tuple is stored in memory that may be
    1364                 :             :  * recycled by any future fetch.
    1365                 :             :  */
    1366                 :             : bool
    1367                 :    17378542 : tuplesort_gettuple_common(Tuplesortstate *state, bool forward,
    1368                 :             :                           SortTuple *stup)
    1369                 :             : {
    1370                 :             :     unsigned int tuplen;
    1371                 :             :     size_t      nmoved;
    1372                 :             : 
    1373                 :             :     Assert(!WORKER(state));
    1374                 :             : 
    1375   [ +  +  +  - ]:    17378542 :     switch (state->status)
    1376                 :             :     {
    1377                 :    14436676 :         case TSS_SORTEDINMEM:
    1378                 :             :             Assert(forward || state->base.sortopt & TUPLESORT_RANDOMACCESS);
    1379                 :             :             Assert(!state->slabAllocatorUsed);
    1380         [ +  + ]:    14436676 :             if (forward)
    1381                 :             :             {
    1382         [ +  + ]:    14436632 :                 if (state->current < state->memtupcount)
    1383                 :             :                 {
    1384                 :    14287487 :                     *stup = state->memtuples[state->current++];
    1385                 :    14287487 :                     return true;
    1386                 :             :                 }
    1387                 :      149145 :                 state->eof_reached = true;
    1388                 :             : 
    1389                 :             :                 /*
    1390                 :             :                  * Complain if caller tries to retrieve more tuples than
    1391                 :             :                  * originally asked for in a bounded sort.  This is because
    1392                 :             :                  * returning EOF here might be the wrong thing.
    1393                 :             :                  */
    1394   [ +  +  -  + ]:      149145 :                 if (state->bounded && state->current >= state->bound)
    1395         [ #  # ]:           0 :                     elog(ERROR, "retrieved too many tuples in a bounded sort");
    1396                 :             : 
    1397                 :      149145 :                 return false;
    1398                 :             :             }
    1399                 :             :             else
    1400                 :             :             {
    1401         [ -  + ]:          44 :                 if (state->current <= 0)
    1402                 :           0 :                     return false;
    1403                 :             : 
    1404                 :             :                 /*
    1405                 :             :                  * if all tuples are fetched already then we return last
    1406                 :             :                  * tuple, else - tuple before last returned.
    1407                 :             :                  */
    1408         [ +  + ]:          44 :                 if (state->eof_reached)
    1409                 :           8 :                     state->eof_reached = false;
    1410                 :             :                 else
    1411                 :             :                 {
    1412                 :          36 :                     state->current--;    /* last returned tuple */
    1413         [ +  + ]:          36 :                     if (state->current <= 0)
    1414                 :           4 :                         return false;
    1415                 :             :                 }
    1416                 :          40 :                 *stup = state->memtuples[state->current - 1];
    1417                 :          40 :                 return true;
    1418                 :             :             }
    1419                 :             :             break;
    1420                 :             : 
    1421                 :      196999 :         case TSS_SORTEDONTAPE:
    1422                 :             :             Assert(forward || state->base.sortopt & TUPLESORT_RANDOMACCESS);
    1423                 :             :             Assert(state->slabAllocatorUsed);
    1424                 :             : 
    1425                 :             :             /*
    1426                 :             :              * The slot that held the tuple that we returned in previous
    1427                 :             :              * gettuple call can now be reused.
    1428                 :             :              */
    1429         [ +  + ]:      196999 :             if (state->lastReturnedTuple)
    1430                 :             :             {
    1431   [ +  -  +  - ]:      101900 :                 RELEASE_SLAB_SLOT(state, state->lastReturnedTuple);
    1432                 :      101900 :                 state->lastReturnedTuple = NULL;
    1433                 :             :             }
    1434                 :             : 
    1435         [ +  + ]:      196999 :             if (forward)
    1436                 :             :             {
    1437         [ -  + ]:      196979 :                 if (state->eof_reached)
    1438                 :           0 :                     return false;
    1439                 :             : 
    1440         [ +  + ]:      196979 :                 if ((tuplen = getlen(state->result_tape, true)) != 0)
    1441                 :             :                 {
    1442                 :      196960 :                     READTUP(state, stup, state->result_tape, tuplen);
    1443                 :             : 
    1444                 :             :                     /*
    1445                 :             :                      * Remember the tuple we return, so that we can recycle
    1446                 :             :                      * its memory on next call.  (This can be NULL, in the
    1447                 :             :                      * !state->tuples case).
    1448                 :             :                      */
    1449                 :      196960 :                     state->lastReturnedTuple = stup->tuple;
    1450                 :             : 
    1451                 :      196960 :                     return true;
    1452                 :             :                 }
    1453                 :             :                 else
    1454                 :             :                 {
    1455                 :          19 :                     state->eof_reached = true;
    1456                 :          19 :                     return false;
    1457                 :             :                 }
    1458                 :             :             }
    1459                 :             : 
    1460                 :             :             /*
    1461                 :             :              * Backward.
    1462                 :             :              *
    1463                 :             :              * if all tuples are fetched already then we return last tuple,
    1464                 :             :              * else - tuple before last returned.
    1465                 :             :              */
    1466         [ +  + ]:          20 :             if (state->eof_reached)
    1467                 :             :             {
    1468                 :             :                 /*
    1469                 :             :                  * Seek position is pointing just past the zero tuplen at the
    1470                 :             :                  * end of file; back up to fetch last tuple's ending length
    1471                 :             :                  * word.  If seek fails we must have a completely empty file.
    1472                 :             :                  */
    1473                 :           8 :                 nmoved = LogicalTapeBackspace(state->result_tape,
    1474                 :             :                                               2 * sizeof(unsigned int));
    1475         [ -  + ]:           8 :                 if (nmoved == 0)
    1476                 :           0 :                     return false;
    1477         [ -  + ]:           8 :                 else if (nmoved != 2 * sizeof(unsigned int))
    1478         [ #  # ]:           0 :                     elog(ERROR, "unexpected tape position");
    1479                 :           8 :                 state->eof_reached = false;
    1480                 :             :             }
    1481                 :             :             else
    1482                 :             :             {
    1483                 :             :                 /*
    1484                 :             :                  * Back up and fetch previously-returned tuple's ending length
    1485                 :             :                  * word.  If seek fails, assume we are at start of file.
    1486                 :             :                  */
    1487                 :          12 :                 nmoved = LogicalTapeBackspace(state->result_tape,
    1488                 :             :                                               sizeof(unsigned int));
    1489         [ -  + ]:          12 :                 if (nmoved == 0)
    1490                 :           0 :                     return false;
    1491         [ -  + ]:          12 :                 else if (nmoved != sizeof(unsigned int))
    1492         [ #  # ]:           0 :                     elog(ERROR, "unexpected tape position");
    1493                 :          12 :                 tuplen = getlen(state->result_tape, false);
    1494                 :             : 
    1495                 :             :                 /*
    1496                 :             :                  * Back up to get ending length word of tuple before it.
    1497                 :             :                  */
    1498                 :          12 :                 nmoved = LogicalTapeBackspace(state->result_tape,
    1499                 :             :                                               tuplen + 2 * sizeof(unsigned int));
    1500         [ +  + ]:          12 :                 if (nmoved == tuplen + sizeof(unsigned int))
    1501                 :             :                 {
    1502                 :             :                     /*
    1503                 :             :                      * We backed up over the previous tuple, but there was no
    1504                 :             :                      * ending length word before it.  That means that the prev
    1505                 :             :                      * tuple is the first tuple in the file.  It is now the
    1506                 :             :                      * next to read in forward direction (not obviously right,
    1507                 :             :                      * but that is what in-memory case does).
    1508                 :             :                      */
    1509                 :           4 :                     return false;
    1510                 :             :                 }
    1511         [ -  + ]:           8 :                 else if (nmoved != tuplen + 2 * sizeof(unsigned int))
    1512         [ #  # ]:           0 :                     elog(ERROR, "bogus tuple length in backward scan");
    1513                 :             :             }
    1514                 :             : 
    1515                 :          16 :             tuplen = getlen(state->result_tape, false);
    1516                 :             : 
    1517                 :             :             /*
    1518                 :             :              * Now we have the length of the prior tuple, back up and read it.
    1519                 :             :              * Note: READTUP expects we are positioned after the initial
    1520                 :             :              * length word of the tuple, so back up to that point.
    1521                 :             :              */
    1522                 :          16 :             nmoved = LogicalTapeBackspace(state->result_tape,
    1523                 :             :                                           tuplen);
    1524         [ -  + ]:          16 :             if (nmoved != tuplen)
    1525         [ #  # ]:           0 :                 elog(ERROR, "bogus tuple length in backward scan");
    1526                 :          16 :             READTUP(state, stup, state->result_tape, tuplen);
    1527                 :             : 
    1528                 :             :             /*
    1529                 :             :              * Remember the tuple we return, so that we can recycle its memory
    1530                 :             :              * on next call. (This can be NULL, in the Datum case).
    1531                 :             :              */
    1532                 :          16 :             state->lastReturnedTuple = stup->tuple;
    1533                 :             : 
    1534                 :          16 :             return true;
    1535                 :             : 
    1536                 :     2744867 :         case TSS_FINALMERGE:
    1537                 :             :             Assert(forward);
    1538                 :             :             /* We are managing memory ourselves, with the slab allocator. */
    1539                 :             :             Assert(state->slabAllocatorUsed);
    1540                 :             : 
    1541                 :             :             /*
    1542                 :             :              * The slab slot holding the tuple that we returned in previous
    1543                 :             :              * gettuple call can now be reused.
    1544                 :             :              */
    1545         [ +  + ]:     2744867 :             if (state->lastReturnedTuple)
    1546                 :             :             {
    1547   [ +  -  +  + ]:     2674641 :                 RELEASE_SLAB_SLOT(state, state->lastReturnedTuple);
    1548                 :     2674641 :                 state->lastReturnedTuple = NULL;
    1549                 :             :             }
    1550                 :             : 
    1551                 :             :             /*
    1552                 :             :              * This code should match the inner loop of mergeonerun().
    1553                 :             :              */
    1554         [ +  + ]:     2744867 :             if (state->memtupcount > 0)
    1555                 :             :             {
    1556                 :     2744673 :                 int         srcTapeIndex = state->memtuples[0].srctape;
    1557                 :     2744673 :                 LogicalTape *srcTape = state->inputTapes[srcTapeIndex];
    1558                 :             :                 SortTuple   newtup;
    1559                 :             : 
    1560                 :     2744673 :                 *stup = state->memtuples[0];
    1561                 :             : 
    1562                 :             :                 /*
    1563                 :             :                  * Remember the tuple we return, so that we can recycle its
    1564                 :             :                  * memory on next call. (This can be NULL, in the Datum case).
    1565                 :             :                  */
    1566                 :     2744673 :                 state->lastReturnedTuple = stup->tuple;
    1567                 :             : 
    1568                 :             :                 /*
    1569                 :             :                  * Pull next tuple from tape, and replace the returned tuple
    1570                 :             :                  * at top of the heap with it.
    1571                 :             :                  */
    1572         [ +  + ]:     2744673 :                 if (!mergereadnext(state, srcTape, &newtup))
    1573                 :             :                 {
    1574                 :             :                     /*
    1575                 :             :                      * If no more data, we've reached end of run on this tape.
    1576                 :             :                      * Remove the top node from the heap.
    1577                 :             :                      */
    1578                 :         286 :                     tuplesort_heap_delete_top(state);
    1579                 :         286 :                     state->nInputRuns--;
    1580                 :             : 
    1581                 :             :                     /*
    1582                 :             :                      * Close the tape.  It'd go away at the end of the sort
    1583                 :             :                      * anyway, but better to release the memory early.
    1584                 :             :                      */
    1585                 :         286 :                     LogicalTapeClose(srcTape);
    1586                 :         286 :                     return true;
    1587                 :             :                 }
    1588                 :     2744387 :                 newtup.srctape = srcTapeIndex;
    1589                 :     2744387 :                 tuplesort_heap_replace_top(state, &newtup);
    1590                 :     2744387 :                 return true;
    1591                 :             :             }
    1592                 :         194 :             return false;
    1593                 :             : 
    1594                 :           0 :         default:
    1595         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    1596                 :             :             return false;       /* keep compiler quiet */
    1597                 :             :     }
    1598                 :             : }
    1599                 :             : 
    1600                 :             : 
    1601                 :             : /*
    1602                 :             :  * Advance over N tuples in either forward or back direction,
    1603                 :             :  * without returning any data.  N==0 is a no-op.
    1604                 :             :  * Returns true if successful, false if ran out of tuples.
    1605                 :             :  */
    1606                 :             : bool
    1607                 :         258 : tuplesort_skiptuples(Tuplesortstate *state, int64 ntuples, bool forward)
    1608                 :             : {
    1609                 :             :     MemoryContext oldcontext;
    1610                 :             : 
    1611                 :             :     /*
    1612                 :             :      * We don't actually support backwards skip yet, because no callers need
    1613                 :             :      * it.  The API is designed to allow for that later, though.
    1614                 :             :      */
    1615                 :             :     Assert(forward);
    1616                 :             :     Assert(ntuples >= 0);
    1617                 :             :     Assert(!WORKER(state));
    1618                 :             : 
    1619      [ +  +  - ]:         258 :     switch (state->status)
    1620                 :             :     {
    1621                 :         242 :         case TSS_SORTEDINMEM:
    1622         [ +  - ]:         242 :             if (state->memtupcount - state->current >= ntuples)
    1623                 :             :             {
    1624                 :         242 :                 state->current += ntuples;
    1625                 :         242 :                 return true;
    1626                 :             :             }
    1627                 :           0 :             state->current = state->memtupcount;
    1628                 :           0 :             state->eof_reached = true;
    1629                 :             : 
    1630                 :             :             /*
    1631                 :             :              * Complain if caller tries to retrieve more tuples than
    1632                 :             :              * originally asked for in a bounded sort.  This is because
    1633                 :             :              * returning EOF here might be the wrong thing.
    1634                 :             :              */
    1635   [ #  #  #  # ]:           0 :             if (state->bounded && state->current >= state->bound)
    1636         [ #  # ]:           0 :                 elog(ERROR, "retrieved too many tuples in a bounded sort");
    1637                 :             : 
    1638                 :           0 :             return false;
    1639                 :             : 
    1640                 :          16 :         case TSS_SORTEDONTAPE:
    1641                 :             :         case TSS_FINALMERGE:
    1642                 :             : 
    1643                 :             :             /*
    1644                 :             :              * We could probably optimize these cases better, but for now it's
    1645                 :             :              * not worth the trouble.
    1646                 :             :              */
    1647                 :          16 :             oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
    1648         [ +  + ]:      160088 :             while (ntuples-- > 0)
    1649                 :             :             {
    1650                 :             :                 SortTuple   stup;
    1651                 :             : 
    1652         [ -  + ]:      160072 :                 if (!tuplesort_gettuple_common(state, forward, &stup))
    1653                 :             :                 {
    1654                 :           0 :                     MemoryContextSwitchTo(oldcontext);
    1655                 :           0 :                     return false;
    1656                 :             :                 }
    1657         [ -  + ]:      160072 :                 CHECK_FOR_INTERRUPTS();
    1658                 :             :             }
    1659                 :          16 :             MemoryContextSwitchTo(oldcontext);
    1660                 :          16 :             return true;
    1661                 :             : 
    1662                 :           0 :         default:
    1663         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    1664                 :             :             return false;       /* keep compiler quiet */
    1665                 :             :     }
    1666                 :             : }
    1667                 :             : 
    1668                 :             : /*
    1669                 :             :  * tuplesort_merge_order - report merge order we'll use for given memory
    1670                 :             :  * (note: "merge order" just means the number of input tapes in the merge).
    1671                 :             :  *
    1672                 :             :  * This is exported for use by the planner.  allowedMem is in bytes.
    1673                 :             :  */
    1674                 :             : int
    1675                 :       11127 : tuplesort_merge_order(int64 allowedMem)
    1676                 :             : {
    1677                 :             :     int         mOrder;
    1678                 :             : 
    1679                 :             :     /*----------
    1680                 :             :      * In the merge phase, we need buffer space for each input and output tape.
    1681                 :             :      * Each pass in the balanced merge algorithm reads from M input tapes, and
    1682                 :             :      * writes to N output tapes.  Each tape consumes TAPE_BUFFER_OVERHEAD bytes
    1683                 :             :      * of memory.  In addition to that, we want MERGE_BUFFER_SIZE workspace per
    1684                 :             :      * input tape.
    1685                 :             :      *
    1686                 :             :      * totalMem = M * (TAPE_BUFFER_OVERHEAD + MERGE_BUFFER_SIZE) +
    1687                 :             :      *            N * TAPE_BUFFER_OVERHEAD
    1688                 :             :      *
    1689                 :             :      * Except for the last and next-to-last merge passes, where there can be
    1690                 :             :      * fewer tapes left to process, M = N.  We choose M so that we have the
    1691                 :             :      * desired amount of memory available for the input buffers
    1692                 :             :      * (TAPE_BUFFER_OVERHEAD + MERGE_BUFFER_SIZE), given the total memory
    1693                 :             :      * available for the tape buffers (allowedMem).
    1694                 :             :      *
    1695                 :             :      * Note: you might be thinking we need to account for the memtuples[]
    1696                 :             :      * array in this calculation, but we effectively treat that as part of the
    1697                 :             :      * MERGE_BUFFER_SIZE workspace.
    1698                 :             :      *----------
    1699                 :             :      */
    1700                 :       11127 :     mOrder = allowedMem /
    1701                 :             :         (2 * TAPE_BUFFER_OVERHEAD + MERGE_BUFFER_SIZE);
    1702                 :             : 
    1703                 :             :     /*
    1704                 :             :      * Even in minimum memory, use at least a MINORDER merge.  On the other
    1705                 :             :      * hand, even when we have lots of memory, do not use more than a MAXORDER
    1706                 :             :      * merge.  Tapes are pretty cheap, but they're not entirely free.  Each
    1707                 :             :      * additional tape reduces the amount of memory available to build runs,
    1708                 :             :      * which in turn can cause the same sort to need more runs, which makes
    1709                 :             :      * merging slower even if it can still be done in a single pass.  Also,
    1710                 :             :      * high order merges are quite slow due to CPU cache effects; it can be
    1711                 :             :      * faster to pay the I/O cost of a multi-pass merge than to perform a
    1712                 :             :      * single merge pass across many hundreds of tapes.
    1713                 :             :      */
    1714                 :       11127 :     mOrder = Max(mOrder, MINORDER);
    1715                 :       11127 :     mOrder = Min(mOrder, MAXORDER);
    1716                 :             : 
    1717                 :       11127 :     return mOrder;
    1718                 :             : }
    1719                 :             : 
    1720                 :             : /*
    1721                 :             :  * Helper function to calculate how much memory to allocate for the read buffer
    1722                 :             :  * of each input tape in a merge pass.
    1723                 :             :  *
    1724                 :             :  * 'avail_mem' is the amount of memory available for the buffers of all the
    1725                 :             :  *      tapes, both input and output.
    1726                 :             :  * 'nInputTapes' and 'nInputRuns' are the number of input tapes and runs.
    1727                 :             :  * 'maxOutputTapes' is the max. number of output tapes we should produce.
    1728                 :             :  */
    1729                 :             : static int64
    1730                 :         240 : merge_read_buffer_size(int64 avail_mem, int nInputTapes, int nInputRuns,
    1731                 :             :                        int maxOutputTapes)
    1732                 :             : {
    1733                 :             :     int         nOutputRuns;
    1734                 :             :     int         nOutputTapes;
    1735                 :             : 
    1736                 :             :     /*
    1737                 :             :      * How many output tapes will we produce in this pass?
    1738                 :             :      *
    1739                 :             :      * This is nInputRuns / nInputTapes, rounded up.
    1740                 :             :      */
    1741                 :         240 :     nOutputRuns = (nInputRuns + nInputTapes - 1) / nInputTapes;
    1742                 :             : 
    1743                 :         240 :     nOutputTapes = Min(nOutputRuns, maxOutputTapes);
    1744                 :             : 
    1745                 :             :     /*
    1746                 :             :      * Each output tape consumes TAPE_BUFFER_OVERHEAD bytes of memory.  All
    1747                 :             :      * remaining memory is divided evenly between the input tapes.
    1748                 :             :      *
    1749                 :             :      * This also follows from the formula in tuplesort_merge_order, but here
    1750                 :             :      * we derive the input buffer size from the amount of memory available,
    1751                 :             :      * and M and N.
    1752                 :             :      */
    1753                 :         240 :     return Max((avail_mem - TAPE_BUFFER_OVERHEAD * nOutputTapes) / nInputTapes, 0);
    1754                 :             : }
    1755                 :             : 
    1756                 :             : /*
    1757                 :             :  * inittapes - initialize for tape sorting.
    1758                 :             :  *
    1759                 :             :  * This is called only if we have found we won't sort in memory.
    1760                 :             :  */
    1761                 :             : static void
    1762                 :         469 : inittapes(Tuplesortstate *state, bool mergeruns)
    1763                 :             : {
    1764                 :             :     Assert(!LEADER(state));
    1765                 :             : 
    1766         [ +  + ]:         469 :     if (mergeruns)
    1767                 :             :     {
    1768                 :             :         /* Compute number of input tapes to use when merging */
    1769                 :          90 :         state->maxTapes = tuplesort_merge_order(state->allowedMem);
    1770                 :             :     }
    1771                 :             :     else
    1772                 :             :     {
    1773                 :             :         /* Workers can sometimes produce single run, output without merge */
    1774                 :             :         Assert(WORKER(state));
    1775                 :         379 :         state->maxTapes = MINORDER;
    1776                 :             :     }
    1777                 :             : 
    1778         [ -  + ]:         469 :     if (trace_sort)
    1779         [ #  # ]:           0 :         elog(LOG, "worker %d switching to external sort with %d tapes: %s",
    1780                 :             :              state->worker, state->maxTapes, pg_rusage_show(&state->ru_start));
    1781                 :             : 
    1782                 :             :     /* Create the tape set */
    1783                 :         469 :     inittapestate(state, state->maxTapes);
    1784                 :         469 :     state->tapeset =
    1785                 :         469 :         LogicalTapeSetCreate(false,
    1786         [ +  + ]:         469 :                              state->shared ? &state->shared->fileset : NULL,
    1787                 :             :                              state->worker);
    1788                 :             : 
    1789                 :         469 :     state->currentRun = 0;
    1790                 :             : 
    1791                 :             :     /*
    1792                 :             :      * Initialize logical tape arrays.
    1793                 :             :      */
    1794                 :         469 :     state->inputTapes = NULL;
    1795                 :         469 :     state->nInputTapes = 0;
    1796                 :         469 :     state->nInputRuns = 0;
    1797                 :             : 
    1798                 :         469 :     state->outputTapes = palloc0(state->maxTapes * sizeof(LogicalTape *));
    1799                 :         469 :     state->nOutputTapes = 0;
    1800                 :         469 :     state->nOutputRuns = 0;
    1801                 :             : 
    1802                 :         469 :     state->status = TSS_BUILDRUNS;
    1803                 :             : 
    1804                 :         469 :     selectnewtape(state);
    1805                 :         469 : }
    1806                 :             : 
    1807                 :             : /*
    1808                 :             :  * inittapestate - initialize generic tape management state
    1809                 :             :  */
    1810                 :             : static void
    1811                 :         599 : inittapestate(Tuplesortstate *state, int maxTapes)
    1812                 :             : {
    1813                 :             :     int64       tapeSpace;
    1814                 :             : 
    1815                 :             :     /*
    1816                 :             :      * Decrease availMem to reflect the space needed for tape buffers; but
    1817                 :             :      * don't decrease it to the point that we have no room for tuples. (That
    1818                 :             :      * case is only likely to occur if sorting pass-by-value Datums; in all
    1819                 :             :      * other scenarios the memtuples[] array is unlikely to occupy more than
    1820                 :             :      * half of allowedMem.  In the pass-by-value case it's not important to
    1821                 :             :      * account for tuple space, so we don't care if LACKMEM becomes
    1822                 :             :      * inaccurate.)
    1823                 :             :      */
    1824                 :         599 :     tapeSpace = (int64) maxTapes * TAPE_BUFFER_OVERHEAD;
    1825                 :             : 
    1826         [ +  + ]:         599 :     if (tapeSpace + GetMemoryChunkSpace(state->memtuples) < state->allowedMem)
    1827                 :         521 :         USEMEM(state, tapeSpace);
    1828                 :             : 
    1829                 :             :     /*
    1830                 :             :      * Make sure that the temp file(s) underlying the tape set are created in
    1831                 :             :      * suitable temp tablespaces.  For parallel sorts, this should have been
    1832                 :             :      * called already, but it doesn't matter if it is called a second time.
    1833                 :             :      */
    1834                 :         599 :     PrepareTempTablespaces();
    1835                 :         599 : }
    1836                 :             : 
    1837                 :             : /*
    1838                 :             :  * selectnewtape -- select next tape to output to.
    1839                 :             :  *
    1840                 :             :  * This is called after finishing a run when we know another run
    1841                 :             :  * must be started.  This is used both when building the initial
    1842                 :             :  * runs, and during merge passes.
    1843                 :             :  */
    1844                 :             : static void
    1845                 :        1200 : selectnewtape(Tuplesortstate *state)
    1846                 :             : {
    1847                 :             :     /*
    1848                 :             :      * At the beginning of each merge pass, nOutputTapes and nOutputRuns are
    1849                 :             :      * both zero.  On each call, we create a new output tape to hold the next
    1850                 :             :      * run, until maxTapes is reached.  After that, we assign new runs to the
    1851                 :             :      * existing tapes in a round robin fashion.
    1852                 :             :      */
    1853         [ +  + ]:        1200 :     if (state->nOutputTapes < state->maxTapes)
    1854                 :             :     {
    1855                 :             :         /* Create a new tape to hold the next run */
    1856                 :             :         Assert(state->outputTapes[state->nOutputRuns] == NULL);
    1857                 :             :         Assert(state->nOutputRuns == state->nOutputTapes);
    1858                 :         812 :         state->destTape = LogicalTapeCreate(state->tapeset);
    1859                 :         812 :         state->outputTapes[state->nOutputTapes] = state->destTape;
    1860                 :         812 :         state->nOutputTapes++;
    1861                 :         812 :         state->nOutputRuns++;
    1862                 :             :     }
    1863                 :             :     else
    1864                 :             :     {
    1865                 :             :         /*
    1866                 :             :          * We have reached the max number of tapes.  Append to an existing
    1867                 :             :          * tape.
    1868                 :             :          */
    1869                 :         388 :         state->destTape = state->outputTapes[state->nOutputRuns % state->nOutputTapes];
    1870                 :         388 :         state->nOutputRuns++;
    1871                 :             :     }
    1872                 :        1200 : }
    1873                 :             : 
    1874                 :             : /*
    1875                 :             :  * Initialize the slab allocation arena, for the given number of slots.
    1876                 :             :  */
    1877                 :             : static void
    1878                 :         220 : init_slab_allocator(Tuplesortstate *state, int numSlots)
    1879                 :             : {
    1880         [ +  + ]:         220 :     if (numSlots > 0)
    1881                 :             :     {
    1882                 :             :         char       *p;
    1883                 :             :         int         i;
    1884                 :             : 
    1885                 :         204 :         state->slabMemoryBegin = palloc(numSlots * SLAB_SLOT_SIZE);
    1886                 :         204 :         state->slabMemoryEnd = state->slabMemoryBegin +
    1887                 :         204 :             numSlots * SLAB_SLOT_SIZE;
    1888                 :         204 :         state->slabFreeHead = (SlabSlot *) state->slabMemoryBegin;
    1889                 :         204 :         USEMEM(state, numSlots * SLAB_SLOT_SIZE);
    1890                 :             : 
    1891                 :         204 :         p = state->slabMemoryBegin;
    1892         [ +  + ]:         778 :         for (i = 0; i < numSlots - 1; i++)
    1893                 :             :         {
    1894                 :         574 :             ((SlabSlot *) p)->nextfree = (SlabSlot *) (p + SLAB_SLOT_SIZE);
    1895                 :         574 :             p += SLAB_SLOT_SIZE;
    1896                 :             :         }
    1897                 :         204 :         ((SlabSlot *) p)->nextfree = NULL;
    1898                 :             :     }
    1899                 :             :     else
    1900                 :             :     {
    1901                 :          16 :         state->slabMemoryBegin = state->slabMemoryEnd = NULL;
    1902                 :          16 :         state->slabFreeHead = NULL;
    1903                 :             :     }
    1904                 :         220 :     state->slabAllocatorUsed = true;
    1905                 :         220 : }
    1906                 :             : 
    1907                 :             : /*
    1908                 :             :  * mergeruns -- merge all the completed initial runs.
    1909                 :             :  *
    1910                 :             :  * This implements the Balanced k-Way Merge Algorithm.  All input data has
    1911                 :             :  * already been written to initial runs on tape (see dumptuples).
    1912                 :             :  */
    1913                 :             : static void
    1914                 :         220 : mergeruns(Tuplesortstate *state)
    1915                 :             : {
    1916                 :             :     int         tapenum;
    1917                 :             : 
    1918                 :             :     Assert(state->status == TSS_BUILDRUNS);
    1919                 :             :     Assert(state->memtupcount == 0);
    1920                 :             : 
    1921   [ +  +  +  + ]:         220 :     if (state->base.sortKeys != NULL && state->base.sortKeys->abbrev_converter != NULL)
    1922                 :             :     {
    1923                 :             :         /*
    1924                 :             :          * If there are multiple runs to be merged, when we go to read back
    1925                 :             :          * tuples from disk, abbreviated keys will not have been stored, and
    1926                 :             :          * we don't care to regenerate them.  Disable abbreviation from this
    1927                 :             :          * point on.
    1928                 :             :          */
    1929                 :          19 :         state->base.sortKeys->abbrev_converter = NULL;
    1930                 :          19 :         state->base.sortKeys->comparator = state->base.sortKeys->abbrev_full_comparator;
    1931                 :             : 
    1932                 :             :         /* Not strictly necessary, but be tidy */
    1933                 :          19 :         state->base.sortKeys->abbrev_abort = NULL;
    1934                 :          19 :         state->base.sortKeys->abbrev_full_comparator = NULL;
    1935                 :             :     }
    1936                 :             : 
    1937                 :             :     /*
    1938                 :             :      * Reset tuple memory.  We've freed all the tuples that we previously
    1939                 :             :      * allocated.  We will use the slab allocator from now on.
    1940                 :             :      */
    1941                 :         220 :     MemoryContextResetOnly(state->base.tuplecontext);
    1942                 :             : 
    1943                 :             :     /*
    1944                 :             :      * We no longer need a large memtuples array.  (We will allocate a smaller
    1945                 :             :      * one for the heap later.)
    1946                 :             :      */
    1947                 :         220 :     FREEMEM(state, GetMemoryChunkSpace(state->memtuples));
    1948                 :         220 :     pfree(state->memtuples);
    1949                 :         220 :     state->memtuples = NULL;
    1950                 :             : 
    1951                 :             :     /*
    1952                 :             :      * Initialize the slab allocator.  We need one slab slot per input tape,
    1953                 :             :      * for the tuples in the heap, plus one to hold the tuple last returned
    1954                 :             :      * from tuplesort_gettuple.  (If we're sorting pass-by-val Datums,
    1955                 :             :      * however, we don't need to do allocate anything.)
    1956                 :             :      *
    1957                 :             :      * In a multi-pass merge, we could shrink this allocation for the last
    1958                 :             :      * merge pass, if it has fewer tapes than previous passes, but we don't
    1959                 :             :      * bother.
    1960                 :             :      *
    1961                 :             :      * From this point on, we no longer use the USEMEM()/LACKMEM() mechanism
    1962                 :             :      * to track memory usage of individual tuples.
    1963                 :             :      */
    1964         [ +  + ]:         220 :     if (state->base.tuples)
    1965                 :         204 :         init_slab_allocator(state, state->nOutputTapes + 1);
    1966                 :             :     else
    1967                 :          16 :         init_slab_allocator(state, 0);
    1968                 :             : 
    1969                 :             :     /*
    1970                 :             :      * Allocate a new 'memtuples' array, for the heap.  It will hold one tuple
    1971                 :             :      * from each input tape.
    1972                 :             :      *
    1973                 :             :      * We could shrink this, too, between passes in a multi-pass merge, but we
    1974                 :             :      * don't bother.  (The initial input tapes are still in outputTapes.  The
    1975                 :             :      * number of input tapes will not increase between passes.)
    1976                 :             :      */
    1977                 :         220 :     state->memtupsize = state->nOutputTapes;
    1978                 :         440 :     state->memtuples = (SortTuple *) MemoryContextAlloc(state->base.maincontext,
    1979                 :         220 :                                                         state->nOutputTapes * sizeof(SortTuple));
    1980                 :         220 :     USEMEM(state, GetMemoryChunkSpace(state->memtuples));
    1981                 :             : 
    1982                 :             :     /*
    1983                 :             :      * Use all the remaining memory we have available for tape buffers among
    1984                 :             :      * all the input tapes.  At the beginning of each merge pass, we will
    1985                 :             :      * divide this memory between the input and output tapes in the pass.
    1986                 :             :      */
    1987                 :         220 :     state->tape_buffer_mem = state->availMem;
    1988                 :         220 :     USEMEM(state, state->tape_buffer_mem);
    1989         [ -  + ]:         220 :     if (trace_sort)
    1990         [ #  # ]:           0 :         elog(LOG, "worker %d using %zu KB of memory for tape buffers",
    1991                 :             :              state->worker, state->tape_buffer_mem / 1024);
    1992                 :             : 
    1993                 :             :     for (;;)
    1994                 :             :     {
    1995                 :             :         /*
    1996                 :             :          * On the first iteration, or if we have read all the runs from the
    1997                 :             :          * input tapes in a multi-pass merge, it's time to start a new pass.
    1998                 :             :          * Rewind all the output tapes, and make them inputs for the next
    1999                 :             :          * pass.
    2000                 :             :          */
    2001         [ +  + ]:         312 :         if (state->nInputRuns == 0)
    2002                 :             :         {
    2003                 :             :             int64       input_buffer_size;
    2004                 :             : 
    2005                 :             :             /* Close the old, emptied, input tapes */
    2006         [ +  + ]:         240 :             if (state->nInputTapes > 0)
    2007                 :             :             {
    2008         [ +  + ]:         140 :                 for (tapenum = 0; tapenum < state->nInputTapes; tapenum++)
    2009                 :         120 :                     LogicalTapeClose(state->inputTapes[tapenum]);
    2010                 :          20 :                 pfree(state->inputTapes);
    2011                 :             :             }
    2012                 :             : 
    2013                 :             :             /* Previous pass's outputs become next pass's inputs. */
    2014                 :         240 :             state->inputTapes = state->outputTapes;
    2015                 :         240 :             state->nInputTapes = state->nOutputTapes;
    2016                 :         240 :             state->nInputRuns = state->nOutputRuns;
    2017                 :             : 
    2018                 :             :             /*
    2019                 :             :              * Reset output tape variables.  The actual LogicalTapes will be
    2020                 :             :              * created as needed, here we only allocate the array to hold
    2021                 :             :              * them.
    2022                 :             :              */
    2023                 :         240 :             state->outputTapes = palloc0(state->nInputTapes * sizeof(LogicalTape *));
    2024                 :         240 :             state->nOutputTapes = 0;
    2025                 :         240 :             state->nOutputRuns = 0;
    2026                 :             : 
    2027                 :             :             /*
    2028                 :             :              * Redistribute the memory allocated for tape buffers, among the
    2029                 :             :              * new input and output tapes.
    2030                 :             :              */
    2031                 :         240 :             input_buffer_size = merge_read_buffer_size(state->tape_buffer_mem,
    2032                 :             :                                                        state->nInputTapes,
    2033                 :             :                                                        state->nInputRuns,
    2034                 :             :                                                        state->maxTapes);
    2035                 :             : 
    2036         [ -  + ]:         240 :             if (trace_sort)
    2037         [ #  # ]:           0 :                 elog(LOG, "starting merge pass of %d input runs on %d tapes, " INT64_FORMAT " KB of memory for each input tape: %s",
    2038                 :             :                      state->nInputRuns, state->nInputTapes, input_buffer_size / 1024,
    2039                 :             :                      pg_rusage_show(&state->ru_start));
    2040                 :             : 
    2041                 :             :             /* Prepare the new input tapes for merge pass. */
    2042         [ +  + ]:         942 :             for (tapenum = 0; tapenum < state->nInputTapes; tapenum++)
    2043                 :         702 :                 LogicalTapeRewindForRead(state->inputTapes[tapenum], input_buffer_size);
    2044                 :             : 
    2045                 :             :             /*
    2046                 :             :              * If there's just one run left on each input tape, then only one
    2047                 :             :              * merge pass remains.  If we don't have to produce a materialized
    2048                 :             :              * sorted tape, we can stop at this point and do the final merge
    2049                 :             :              * on-the-fly.
    2050                 :             :              */
    2051         [ +  + ]:         240 :             if ((state->base.sortopt & TUPLESORT_RANDOMACCESS) == 0
    2052         [ +  + ]:         226 :                 && state->nInputRuns <= state->nInputTapes
    2053   [ +  +  +  - ]:         206 :                 && !WORKER(state))
    2054                 :             :             {
    2055                 :             :                 /* Tell logtape.c we won't be writing anymore */
    2056                 :         206 :                 LogicalTapeSetForgetFreeSpace(state->tapeset);
    2057                 :             :                 /* Initialize for the final merge pass */
    2058                 :         206 :                 beginmerge(state);
    2059                 :         206 :                 state->status = TSS_FINALMERGE;
    2060                 :         206 :                 return;
    2061                 :             :             }
    2062                 :             :         }
    2063                 :             : 
    2064                 :             :         /* Select an output tape */
    2065                 :         106 :         selectnewtape(state);
    2066                 :             : 
    2067                 :             :         /* Merge one run from each input tape. */
    2068                 :         106 :         mergeonerun(state);
    2069                 :             : 
    2070                 :             :         /*
    2071                 :             :          * If the input tapes are empty, and we output only one output run,
    2072                 :             :          * we're done.  The current output tape contains the final result.
    2073                 :             :          */
    2074   [ +  +  +  + ]:         106 :         if (state->nInputRuns == 0 && state->nOutputRuns <= 1)
    2075                 :          14 :             break;
    2076                 :             :     }
    2077                 :             : 
    2078                 :             :     /*
    2079                 :             :      * Done.  The result is on a single run on a single tape.
    2080                 :             :      */
    2081                 :          14 :     state->result_tape = state->outputTapes[0];
    2082   [ -  +  -  - ]:          14 :     if (!WORKER(state))
    2083                 :          14 :         LogicalTapeFreeze(state->result_tape, NULL);
    2084                 :             :     else
    2085                 :           0 :         worker_freeze_result_tape(state);
    2086                 :          14 :     state->status = TSS_SORTEDONTAPE;
    2087                 :             : 
    2088                 :             :     /* Close all the now-empty input tapes, to release their read buffers. */
    2089         [ +  + ]:          74 :     for (tapenum = 0; tapenum < state->nInputTapes; tapenum++)
    2090                 :          60 :         LogicalTapeClose(state->inputTapes[tapenum]);
    2091                 :             : }
    2092                 :             : 
    2093                 :             : /*
    2094                 :             :  * Merge one run from each input tape.
    2095                 :             :  */
    2096                 :             : static void
    2097                 :         106 : mergeonerun(Tuplesortstate *state)
    2098                 :             : {
    2099                 :             :     int         srcTapeIndex;
    2100                 :             :     LogicalTape *srcTape;
    2101                 :             : 
    2102                 :             :     /*
    2103                 :             :      * Start the merge by loading one tuple from each active source tape into
    2104                 :             :      * the heap.
    2105                 :             :      */
    2106                 :         106 :     beginmerge(state);
    2107                 :             : 
    2108                 :             :     Assert(state->slabAllocatorUsed);
    2109                 :             : 
    2110                 :             :     /*
    2111                 :             :      * Execute merge by repeatedly extracting lowest tuple in heap, writing it
    2112                 :             :      * out, and replacing it with next tuple from same tape (if there is
    2113                 :             :      * another one).
    2114                 :             :      */
    2115         [ +  + ]:      580394 :     while (state->memtupcount > 0)
    2116                 :             :     {
    2117                 :             :         SortTuple   stup;
    2118                 :             : 
    2119                 :             :         /* write the tuple to destTape */
    2120                 :      580288 :         srcTapeIndex = state->memtuples[0].srctape;
    2121                 :      580288 :         srcTape = state->inputTapes[srcTapeIndex];
    2122                 :      580288 :         WRITETUP(state, state->destTape, &state->memtuples[0]);
    2123                 :             : 
    2124                 :             :         /* recycle the slot of the tuple we just wrote out, for the next read */
    2125         [ +  + ]:      580288 :         if (state->memtuples[0].tuple)
    2126   [ +  -  +  - ]:      490232 :             RELEASE_SLAB_SLOT(state, state->memtuples[0].tuple);
    2127                 :             : 
    2128                 :             :         /*
    2129                 :             :          * pull next tuple from the tape, and replace the written-out tuple in
    2130                 :             :          * the heap with it.
    2131                 :             :          */
    2132         [ +  + ]:      580288 :         if (mergereadnext(state, srcTape, &stup))
    2133                 :             :         {
    2134                 :      579720 :             stup.srctape = srcTapeIndex;
    2135                 :      579720 :             tuplesort_heap_replace_top(state, &stup);
    2136                 :             :         }
    2137                 :             :         else
    2138                 :             :         {
    2139                 :         568 :             tuplesort_heap_delete_top(state);
    2140                 :         568 :             state->nInputRuns--;
    2141                 :             :         }
    2142                 :             :     }
    2143                 :             : 
    2144                 :             :     /*
    2145                 :             :      * When the heap empties, we're done.  Write an end-of-run marker on the
    2146                 :             :      * output tape.
    2147                 :             :      */
    2148                 :         106 :     markrunend(state->destTape);
    2149                 :         106 : }
    2150                 :             : 
    2151                 :             : /*
    2152                 :             :  * beginmerge - initialize for a merge pass
    2153                 :             :  *
    2154                 :             :  * Fill the merge heap with the first tuple from each input tape.
    2155                 :             :  */
    2156                 :             : static void
    2157                 :         312 : beginmerge(Tuplesortstate *state)
    2158                 :             : {
    2159                 :             :     int         activeTapes;
    2160                 :             :     int         srcTapeIndex;
    2161                 :             : 
    2162                 :             :     /* Heap should be empty here */
    2163                 :             :     Assert(state->memtupcount == 0);
    2164                 :             : 
    2165                 :         312 :     activeTapes = Min(state->nInputTapes, state->nInputRuns);
    2166                 :             : 
    2167         [ +  + ]:        1402 :     for (srcTapeIndex = 0; srcTapeIndex < activeTapes; srcTapeIndex++)
    2168                 :             :     {
    2169                 :             :         SortTuple   tup;
    2170                 :             : 
    2171         [ +  + ]:        1090 :         if (mergereadnext(state, state->inputTapes[srcTapeIndex], &tup))
    2172                 :             :         {
    2173                 :         886 :             tup.srctape = srcTapeIndex;
    2174                 :         886 :             tuplesort_heap_insert(state, &tup);
    2175                 :             :         }
    2176                 :             :     }
    2177                 :         312 : }
    2178                 :             : 
    2179                 :             : /*
    2180                 :             :  * mergereadnext - read next tuple from one merge input tape
    2181                 :             :  *
    2182                 :             :  * Returns false on EOF.
    2183                 :             :  */
    2184                 :             : static bool
    2185                 :     3326051 : mergereadnext(Tuplesortstate *state, LogicalTape *srcTape, SortTuple *stup)
    2186                 :             : {
    2187                 :             :     unsigned int tuplen;
    2188                 :             : 
    2189                 :             :     /* read next tuple, if any */
    2190         [ +  + ]:     3326051 :     if ((tuplen = getlen(srcTape, true)) == 0)
    2191                 :        1058 :         return false;
    2192                 :     3324993 :     READTUP(state, stup, srcTape, tuplen);
    2193                 :             : 
    2194                 :     3324993 :     return true;
    2195                 :             : }
    2196                 :             : 
    2197                 :             : /*
    2198                 :             :  * dumptuples - remove tuples from memtuples and write initial run to tape
    2199                 :             :  *
    2200                 :             :  * When alltuples = true, dump everything currently in memory.  (This case is
    2201                 :             :  * only used at end of input data.)
    2202                 :             :  */
    2203                 :             : static void
    2204                 :      734632 : dumptuples(Tuplesortstate *state, bool alltuples)
    2205                 :             : {
    2206                 :             :     int         memtupwrite;
    2207                 :             :     int         i;
    2208                 :             : 
    2209                 :             :     /*
    2210                 :             :      * Nothing to do if we still fit in available memory and have array slots,
    2211                 :             :      * unless this is the final call during initial run generation.
    2212                 :             :      */
    2213   [ +  +  +  +  :      734632 :     if (state->memtupcount < state->memtupsize && !LACKMEM(state) &&
                   -  + ]
    2214         [ +  + ]:      734007 :         !alltuples)
    2215                 :      733538 :         return;
    2216                 :             : 
    2217                 :             :     /*
    2218                 :             :      * Final call might require no sorting, in rare cases where we just so
    2219                 :             :      * happen to have previously LACKMEM()'d at the point where exactly all
    2220                 :             :      * remaining tuples are loaded into memory, just before input was
    2221                 :             :      * exhausted.  In general, short final runs are quite possible, but avoid
    2222                 :             :      * creating a completely empty run.  In a worker, though, we must produce
    2223                 :             :      * at least one tape, even if it's empty.
    2224                 :             :      */
    2225   [ +  +  -  + ]:        1094 :     if (state->memtupcount == 0 && state->currentRun > 0)
    2226                 :           0 :         return;
    2227                 :             : 
    2228                 :             :     Assert(state->status == TSS_BUILDRUNS);
    2229                 :             : 
    2230                 :             :     /*
    2231                 :             :      * It seems unlikely that this limit will ever be exceeded, but take no
    2232                 :             :      * chances
    2233                 :             :      */
    2234         [ -  + ]:        1094 :     if (state->currentRun == INT_MAX)
    2235         [ #  # ]:           0 :         ereport(ERROR,
    2236                 :             :                 (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
    2237                 :             :                  errmsg("cannot have more than %d runs for an external sort",
    2238                 :             :                         INT_MAX)));
    2239                 :             : 
    2240         [ +  + ]:        1094 :     if (state->currentRun > 0)
    2241                 :         625 :         selectnewtape(state);
    2242                 :             : 
    2243                 :        1094 :     state->currentRun++;
    2244                 :             : 
    2245         [ -  + ]:        1094 :     if (trace_sort)
    2246         [ #  # ]:           0 :         elog(LOG, "worker %d starting quicksort of run %d: %s",
    2247                 :             :              state->worker, state->currentRun,
    2248                 :             :              pg_rusage_show(&state->ru_start));
    2249                 :             : 
    2250                 :             :     /*
    2251                 :             :      * Sort all tuples accumulated within the allowed amount of memory for
    2252                 :             :      * this run.
    2253                 :             :      */
    2254                 :        1094 :     tuplesort_sort_memtuples(state);
    2255                 :             : 
    2256         [ -  + ]:        1094 :     if (trace_sort)
    2257         [ #  # ]:           0 :         elog(LOG, "worker %d finished quicksort of run %d: %s",
    2258                 :             :              state->worker, state->currentRun,
    2259                 :             :              pg_rusage_show(&state->ru_start));
    2260                 :             : 
    2261                 :        1094 :     memtupwrite = state->memtupcount;
    2262         [ +  + ]:     3085935 :     for (i = 0; i < memtupwrite; i++)
    2263                 :             :     {
    2264                 :     3084841 :         SortTuple  *stup = &state->memtuples[i];
    2265                 :             : 
    2266                 :     3084841 :         WRITETUP(state, state->destTape, stup);
    2267                 :             :     }
    2268                 :             : 
    2269                 :        1094 :     state->memtupcount = 0;
    2270                 :             : 
    2271                 :             :     /*
    2272                 :             :      * Reset tuple memory.  We've freed all of the tuples that we previously
    2273                 :             :      * allocated.  It's important to avoid fragmentation when there is a stark
    2274                 :             :      * change in the sizes of incoming tuples.  In bounded sorts,
    2275                 :             :      * fragmentation due to AllocSetFree's bucketing by size class might be
    2276                 :             :      * particularly bad if this step wasn't taken.
    2277                 :             :      */
    2278                 :        1094 :     MemoryContextReset(state->base.tuplecontext);
    2279                 :             : 
    2280                 :             :     /*
    2281                 :             :      * Now update the memory accounting to subtract the memory used by the
    2282                 :             :      * tuple.
    2283                 :             :      */
    2284                 :        1094 :     FREEMEM(state, state->tupleMem);
    2285                 :        1094 :     state->tupleMem = 0;
    2286                 :             : 
    2287                 :        1094 :     markrunend(state->destTape);
    2288                 :             : 
    2289         [ -  + ]:        1094 :     if (trace_sort)
    2290         [ #  # ]:           0 :         elog(LOG, "worker %d finished writing run %d to tape %d: %s",
    2291                 :             :              state->worker, state->currentRun, (state->currentRun - 1) % state->nOutputTapes + 1,
    2292                 :             :              pg_rusage_show(&state->ru_start));
    2293                 :             : }
    2294                 :             : 
    2295                 :             : /*
    2296                 :             :  * tuplesort_rescan     - rewind and replay the scan
    2297                 :             :  */
    2298                 :             : void
    2299                 :          35 : tuplesort_rescan(Tuplesortstate *state)
    2300                 :             : {
    2301                 :          35 :     MemoryContext oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
    2302                 :             : 
    2303                 :             :     Assert(state->base.sortopt & TUPLESORT_RANDOMACCESS);
    2304                 :             : 
    2305      [ +  +  - ]:          35 :     switch (state->status)
    2306                 :             :     {
    2307                 :          30 :         case TSS_SORTEDINMEM:
    2308                 :          30 :             state->current = 0;
    2309                 :          30 :             state->eof_reached = false;
    2310                 :          30 :             state->markpos_offset = 0;
    2311                 :          30 :             state->markpos_eof = false;
    2312                 :          30 :             break;
    2313                 :           5 :         case TSS_SORTEDONTAPE:
    2314                 :           5 :             LogicalTapeRewindForRead(state->result_tape, 0);
    2315                 :           5 :             state->eof_reached = false;
    2316                 :           5 :             state->markpos_block = 0L;
    2317                 :           5 :             state->markpos_offset = 0;
    2318                 :           5 :             state->markpos_eof = false;
    2319                 :           5 :             break;
    2320                 :           0 :         default:
    2321         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    2322                 :             :             break;
    2323                 :             :     }
    2324                 :             : 
    2325                 :          35 :     MemoryContextSwitchTo(oldcontext);
    2326                 :          35 : }
    2327                 :             : 
    2328                 :             : /*
    2329                 :             :  * tuplesort_markpos    - saves current position in the merged sort file
    2330                 :             :  */
    2331                 :             : void
    2332                 :      389424 : tuplesort_markpos(Tuplesortstate *state)
    2333                 :             : {
    2334                 :      389424 :     MemoryContext oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
    2335                 :             : 
    2336                 :             :     Assert(state->base.sortopt & TUPLESORT_RANDOMACCESS);
    2337                 :             : 
    2338      [ +  +  - ]:      389424 :     switch (state->status)
    2339                 :             :     {
    2340                 :      383552 :         case TSS_SORTEDINMEM:
    2341                 :      383552 :             state->markpos_offset = state->current;
    2342                 :      383552 :             state->markpos_eof = state->eof_reached;
    2343                 :      383552 :             break;
    2344                 :        5872 :         case TSS_SORTEDONTAPE:
    2345                 :        5872 :             LogicalTapeTell(state->result_tape,
    2346                 :             :                             &state->markpos_block,
    2347                 :             :                             &state->markpos_offset);
    2348                 :        5872 :             state->markpos_eof = state->eof_reached;
    2349                 :        5872 :             break;
    2350                 :           0 :         default:
    2351         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    2352                 :             :             break;
    2353                 :             :     }
    2354                 :             : 
    2355                 :      389424 :     MemoryContextSwitchTo(oldcontext);
    2356                 :      389424 : }
    2357                 :             : 
    2358                 :             : /*
    2359                 :             :  * tuplesort_restorepos - restores current position in merged sort file to
    2360                 :             :  *                        last saved position
    2361                 :             :  */
    2362                 :             : void
    2363                 :       24692 : tuplesort_restorepos(Tuplesortstate *state)
    2364                 :             : {
    2365                 :       24692 :     MemoryContext oldcontext = MemoryContextSwitchTo(state->base.sortcontext);
    2366                 :             : 
    2367                 :             :     Assert(state->base.sortopt & TUPLESORT_RANDOMACCESS);
    2368                 :             : 
    2369      [ +  +  - ]:       24692 :     switch (state->status)
    2370                 :             :     {
    2371                 :       20564 :         case TSS_SORTEDINMEM:
    2372                 :       20564 :             state->current = state->markpos_offset;
    2373                 :       20564 :             state->eof_reached = state->markpos_eof;
    2374                 :       20564 :             break;
    2375                 :        4128 :         case TSS_SORTEDONTAPE:
    2376                 :        4128 :             LogicalTapeSeek(state->result_tape,
    2377                 :             :                             state->markpos_block,
    2378                 :             :                             state->markpos_offset);
    2379                 :        4128 :             state->eof_reached = state->markpos_eof;
    2380                 :        4128 :             break;
    2381                 :           0 :         default:
    2382         [ #  # ]:           0 :             elog(ERROR, "invalid tuplesort state");
    2383                 :             :             break;
    2384                 :             :     }
    2385                 :             : 
    2386                 :       24692 :     MemoryContextSwitchTo(oldcontext);
    2387                 :       24692 : }
    2388                 :             : 
    2389                 :             : /*
    2390                 :             :  * tuplesort_get_stats - extract summary statistics
    2391                 :             :  *
    2392                 :             :  * This can be called after tuplesort_performsort() finishes to obtain
    2393                 :             :  * printable summary information about how the sort was performed.
    2394                 :             :  */
    2395                 :             : void
    2396                 :         264 : tuplesort_get_stats(Tuplesortstate *state,
    2397                 :             :                     TuplesortInstrumentation *stats)
    2398                 :             : {
    2399                 :             :     /*
    2400                 :             :      * Note: it might seem we should provide both memory and disk usage for a
    2401                 :             :      * disk-based sort.  However, the current code doesn't track memory space
    2402                 :             :      * accurately once we have begun to return tuples to the caller (since we
    2403                 :             :      * don't account for pfree's the caller is expected to do), so we cannot
    2404                 :             :      * rely on availMem in a disk sort.  This does not seem worth the overhead
    2405                 :             :      * to fix.  Is it worth creating an API for the memory context code to
    2406                 :             :      * tell us how much is actually used in sortcontext?
    2407                 :             :      */
    2408                 :         264 :     tuplesort_updatemax(state);
    2409                 :             : 
    2410         [ +  + ]:         264 :     if (state->isMaxSpaceDisk)
    2411                 :           4 :         stats->spaceType = SORT_SPACE_TYPE_DISK;
    2412                 :             :     else
    2413                 :         260 :         stats->spaceType = SORT_SPACE_TYPE_MEMORY;
    2414                 :         264 :     stats->spaceUsed = (state->maxSpace + 1023) / 1024;
    2415                 :             : 
    2416   [ +  -  +  - ]:         264 :     switch (state->maxSpaceStatus)
    2417                 :             :     {
    2418                 :         260 :         case TSS_SORTEDINMEM:
    2419         [ +  + ]:         260 :             if (state->boundUsed)
    2420                 :          28 :                 stats->sortMethod = SORT_TYPE_TOP_N_HEAPSORT;
    2421                 :             :             else
    2422                 :         232 :                 stats->sortMethod = SORT_TYPE_QUICKSORT;
    2423                 :         260 :             break;
    2424                 :           0 :         case TSS_SORTEDONTAPE:
    2425                 :           0 :             stats->sortMethod = SORT_TYPE_EXTERNAL_SORT;
    2426                 :           0 :             break;
    2427                 :           4 :         case TSS_FINALMERGE:
    2428                 :           4 :             stats->sortMethod = SORT_TYPE_EXTERNAL_MERGE;
    2429                 :           4 :             break;
    2430                 :           0 :         default:
    2431                 :           0 :             stats->sortMethod = SORT_TYPE_STILL_IN_PROGRESS;
    2432                 :           0 :             break;
    2433                 :             :     }
    2434                 :         264 : }
    2435                 :             : 
    2436                 :             : /*
    2437                 :             :  * Convert TuplesortMethod to a string.
    2438                 :             :  */
    2439                 :             : const char *
    2440                 :         196 : tuplesort_method_name(TuplesortMethod m)
    2441                 :             : {
    2442   [ -  +  +  -  :         196 :     switch (m)
                   +  - ]
    2443                 :             :     {
    2444                 :           0 :         case SORT_TYPE_STILL_IN_PROGRESS:
    2445                 :           0 :             return "still in progress";
    2446                 :          28 :         case SORT_TYPE_TOP_N_HEAPSORT:
    2447                 :          28 :             return "top-N heapsort";
    2448                 :         164 :         case SORT_TYPE_QUICKSORT:
    2449                 :         164 :             return "quicksort";
    2450                 :           0 :         case SORT_TYPE_EXTERNAL_SORT:
    2451                 :           0 :             return "external sort";
    2452                 :           4 :         case SORT_TYPE_EXTERNAL_MERGE:
    2453                 :           4 :             return "external merge";
    2454                 :             :     }
    2455                 :             : 
    2456                 :           0 :     return "unknown";
    2457                 :             : }
    2458                 :             : 
    2459                 :             : /*
    2460                 :             :  * Convert TuplesortSpaceType to a string.
    2461                 :             :  */
    2462                 :             : const char *
    2463                 :         172 : tuplesort_space_type_name(TuplesortSpaceType t)
    2464                 :             : {
    2465                 :             :     Assert(t == SORT_SPACE_TYPE_DISK || t == SORT_SPACE_TYPE_MEMORY);
    2466         [ +  + ]:         172 :     return t == SORT_SPACE_TYPE_DISK ? "Disk" : "Memory";
    2467                 :             : }
    2468                 :             : 
    2469                 :             : 
    2470                 :             : /*
    2471                 :             :  * Heap manipulation routines, per Knuth's Algorithm 5.2.3H.
    2472                 :             :  */
    2473                 :             : 
    2474                 :             : /*
    2475                 :             :  * Convert the existing unordered array of SortTuples to a bounded heap,
    2476                 :             :  * discarding all but the smallest "state->bound" tuples.
    2477                 :             :  *
    2478                 :             :  * When working with a bounded heap, we want to keep the largest entry
    2479                 :             :  * at the root (array entry zero), instead of the smallest as in the normal
    2480                 :             :  * sort case.  This allows us to discard the largest entry cheaply.
    2481                 :             :  * Therefore, we temporarily reverse the sort direction.
    2482                 :             :  */
    2483                 :             : static void
    2484                 :         256 : make_bounded_heap(Tuplesortstate *state)
    2485                 :             : {
    2486                 :         256 :     int         tupcount = state->memtupcount;
    2487                 :             :     int         i;
    2488                 :             : 
    2489                 :             :     Assert(state->status == TSS_INITIAL);
    2490                 :             :     Assert(state->bounded);
    2491                 :             :     Assert(tupcount >= state->bound);
    2492                 :             :     Assert(SERIAL(state));
    2493                 :             : 
    2494                 :             :     /* Reverse sort direction so largest entry will be at root */
    2495                 :         256 :     reversedirection(state);
    2496                 :             : 
    2497                 :         256 :     state->memtupcount = 0;      /* make the heap empty */
    2498         [ +  + ]:       24274 :     for (i = 0; i < tupcount; i++)
    2499                 :             :     {
    2500         [ +  + ]:       24018 :         if (state->memtupcount < state->bound)
    2501                 :             :         {
    2502                 :             :             /* Insert next tuple into heap */
    2503                 :             :             /* Must copy source tuple to avoid possible overwrite */
    2504                 :       11881 :             SortTuple   stup = state->memtuples[i];
    2505                 :             : 
    2506                 :       11881 :             tuplesort_heap_insert(state, &stup);
    2507                 :             :         }
    2508                 :             :         else
    2509                 :             :         {
    2510                 :             :             /*
    2511                 :             :              * The heap is full.  Replace the largest entry with the new
    2512                 :             :              * tuple, or just discard it, if it's larger than anything already
    2513                 :             :              * in the heap.
    2514                 :             :              */
    2515         [ +  + ]:       12137 :             if (COMPARETUP(state, &state->memtuples[i], &state->memtuples[0]) <= 0)
    2516                 :             :             {
    2517                 :        6069 :                 free_sort_tuple(state, &state->memtuples[i]);
    2518         [ -  + ]:        6069 :                 CHECK_FOR_INTERRUPTS();
    2519                 :             :             }
    2520                 :             :             else
    2521                 :        6068 :                 tuplesort_heap_replace_top(state, &state->memtuples[i]);
    2522                 :             :         }
    2523                 :             :     }
    2524                 :             : 
    2525                 :             :     Assert(state->memtupcount == state->bound);
    2526                 :         256 :     state->status = TSS_BOUNDED;
    2527                 :         256 : }
    2528                 :             : 
    2529                 :             : /*
    2530                 :             :  * Convert the bounded heap to a properly-sorted array
    2531                 :             :  */
    2532                 :             : static void
    2533                 :         256 : sort_bounded_heap(Tuplesortstate *state)
    2534                 :             : {
    2535                 :         256 :     int         tupcount = state->memtupcount;
    2536                 :             : 
    2537                 :             :     Assert(state->status == TSS_BOUNDED);
    2538                 :             :     Assert(state->bounded);
    2539                 :             :     Assert(tupcount == state->bound);
    2540                 :             :     Assert(SERIAL(state));
    2541                 :             : 
    2542                 :             :     /*
    2543                 :             :      * We can unheapify in place because each delete-top call will remove the
    2544                 :             :      * largest entry, which we can promptly store in the newly freed slot at
    2545                 :             :      * the end.  Once we're down to a single-entry heap, we're done.
    2546                 :             :      */
    2547         [ +  + ]:       11881 :     while (state->memtupcount > 1)
    2548                 :             :     {
    2549                 :       11625 :         SortTuple   stup = state->memtuples[0];
    2550                 :             : 
    2551                 :             :         /* this sifts-up the next-largest entry and decreases memtupcount */
    2552                 :       11625 :         tuplesort_heap_delete_top(state);
    2553                 :       11625 :         state->memtuples[state->memtupcount] = stup;
    2554                 :             :     }
    2555                 :         256 :     state->memtupcount = tupcount;
    2556                 :             : 
    2557                 :             :     /*
    2558                 :             :      * Reverse sort direction back to the original state.  This is not
    2559                 :             :      * actually necessary but seems like a good idea for tidiness.
    2560                 :             :      */
    2561                 :         256 :     reversedirection(state);
    2562                 :             : 
    2563                 :         256 :     state->status = TSS_SORTEDINMEM;
    2564                 :         256 :     state->boundUsed = true;
    2565                 :         256 : }
    2566                 :             : 
    2567                 :             : 
    2568                 :             : /* radix sort routines */
    2569                 :             : 
    2570                 :             : /*
    2571                 :             :  * Retrieve byte from datum, indexed by 'level': 0 for MSB, 7 for LSB
    2572                 :             :  */
    2573                 :             : static inline uint8
    2574                 :    26194133 : current_byte(Datum key, int level)
    2575                 :             : {
    2576                 :    26194133 :     int         shift = (sizeof(Datum) - 1 - level) * BITS_PER_BYTE;
    2577                 :             : 
    2578                 :    26194133 :     return (key >> shift) & 0xFF;
    2579                 :             : }
    2580                 :             : 
    2581                 :             : /*
    2582                 :             :  * Normalize datum such that unsigned comparison is order-preserving,
    2583                 :             :  * taking ASC/DESC into account as well.
    2584                 :             :  */
    2585                 :             : static inline Datum
    2586                 :    26240689 : normalize_datum(Datum orig, SortSupport ssup)
    2587                 :             : {
    2588                 :             :     Datum       norm_datum1;
    2589                 :             : 
    2590         [ +  + ]:    26240689 :     if (ssup->comparator == ssup_datum_signed_cmp)
    2591                 :             :     {
    2592                 :     1099950 :         norm_datum1 = orig + (Int64GetDatum(PG_INT64_MAX)) + 1;
    2593                 :             :     }
    2594         [ +  + ]:    25140739 :     else if (ssup->comparator == ssup_datum_int32_cmp)
    2595                 :             :     {
    2596                 :             :         /*
    2597                 :             :          * First truncate to uint32. Technically, we don't need to do this,
    2598                 :             :          * but it forces the upper half of the datum to be zero regardless of
    2599                 :             :          * sign.
    2600                 :             :          */
    2601                 :     7731082 :         uint32      u32 = DatumGetUInt32(orig) + ((uint32) PG_INT32_MAX) + 1;
    2602                 :             : 
    2603                 :     7731082 :         norm_datum1 = UInt32GetDatum(u32);
    2604                 :             :     }
    2605                 :             :     else
    2606                 :             :     {
    2607                 :             :         Assert(ssup->comparator == ssup_datum_unsigned_cmp);
    2608                 :    17409657 :         norm_datum1 = orig;
    2609                 :             :     }
    2610                 :             : 
    2611         [ +  + ]:    26240689 :     if (ssup->ssup_reverse)
    2612                 :      804815 :         norm_datum1 = ~norm_datum1;
    2613                 :             : 
    2614                 :    26240689 :     return norm_datum1;
    2615                 :             : }
    2616                 :             : 
    2617                 :             : /*
    2618                 :             :  * radix_sort_recursive
    2619                 :             :  *
    2620                 :             :  * Radix sort by (pass-by-value) datum1, diverting to qsort_tuple()
    2621                 :             :  * for tiebreaks.
    2622                 :             :  *
    2623                 :             :  * This is a modification of ska_byte_sort() from
    2624                 :             :  * https://github.com/skarupke/ska_sort
    2625                 :             :  * The original copyright notice follows:
    2626                 :             :  *
    2627                 :             :  * Copyright Malte Skarupke 2016.
    2628                 :             :  * Distributed under the Boost Software License, Version 1.0.
    2629                 :             :  *
    2630                 :             :  * Boost Software License - Version 1.0 - August 17th, 2003
    2631                 :             :  *
    2632                 :             :  * Permission is hereby granted, free of charge, to any person or organization
    2633                 :             :  * obtaining a copy of the software and accompanying documentation covered by
    2634                 :             :  * this license (the "Software") to use, reproduce, display, distribute,
    2635                 :             :  * execute, and transmit the Software, and to prepare derivative works of the
    2636                 :             :  * Software, and to permit third-parties to whom the Software is furnished to
    2637                 :             :  * do so, all subject to the following:
    2638                 :             :  *
    2639                 :             :  * The copyright notices in the Software and this entire statement, including
    2640                 :             :  * the above license grant, this restriction and the following disclaimer,
    2641                 :             :  * must be included in all copies of the Software, in whole or in part, and
    2642                 :             :  * all derivative works of the Software, unless such copies or derivative
    2643                 :             :  * works are solely in the form of machine-executable object code generated by
    2644                 :             :  * a source language processor.
    2645                 :             :  *
    2646                 :             :  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
    2647                 :             :  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
    2648                 :             :  * FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT
    2649                 :             :  * SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE
    2650                 :             :  * FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE,
    2651                 :             :  * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
    2652                 :             :  * DEALINGS IN THE SOFTWARE.
    2653                 :             :  */
    2654                 :             : static void
    2655                 :       46556 : radix_sort_recursive(SortTuple *begin, size_t n_elems, int level, Tuplesortstate *state)
    2656                 :             : {
    2657                 :       46556 :     RadixSortInfo partitions[256] = {0};
    2658                 :             :     uint8       remaining_partitions[256];
    2659                 :       46556 :     size_t      total = 0;
    2660                 :       46556 :     int         num_partitions = 0;
    2661                 :             :     int         num_remaining;
    2662                 :       46556 :     SortSupport ssup = &state->base.sortKeys[0];
    2663                 :             :     Datum       ref_datum;
    2664                 :       46556 :     Datum       common_upper_bits = 0;
    2665                 :       46556 :     size_t      start_offset = 0;
    2666                 :       46556 :     SortTuple  *partition_begin = begin;
    2667                 :             :     int         next_level;
    2668                 :             : 
    2669                 :             :     /* count number of occurrences of each byte */
    2670                 :       46556 :     ref_datum = normalize_datum(begin[0].datum1, ssup);
    2671         [ +  + ]:    26240689 :     for (SortTuple *st = begin; st < begin + n_elems; st++)
    2672                 :             :     {
    2673                 :             :         Datum       this_datum;
    2674                 :             :         uint8       this_partition;
    2675                 :             : 
    2676                 :    26194133 :         this_datum = normalize_datum(st->datum1, ssup);
    2677                 :             :         /* accumulate bits different from the reference datum */
    2678                 :    26194133 :         common_upper_bits |= ref_datum ^ this_datum;
    2679                 :             : 
    2680                 :             :         /* extract the byte for this level from the normalized datum */
    2681                 :    26194133 :         this_partition = current_byte(this_datum, level);
    2682                 :             : 
    2683                 :             :         /* save it for the permutation step */
    2684                 :    26194133 :         st->curbyte = this_partition;
    2685                 :             : 
    2686                 :    26194133 :         partitions[this_partition].count++;
    2687                 :             : 
    2688         [ +  + ]:    26194133 :         CHECK_FOR_INTERRUPTS();
    2689                 :             :     }
    2690                 :             : 
    2691                 :             :     /* compute partition offsets */
    2692         [ +  + ]:    11964892 :     for (int i = 0; i < 256; i++)
    2693                 :             :     {
    2694                 :    11918336 :         size_t      count = partitions[i].count;
    2695                 :             : 
    2696         [ +  + ]:    11918336 :         if (count != 0)
    2697                 :             :         {
    2698                 :     2619806 :             partitions[i].offset = total;
    2699                 :     2619806 :             total += count;
    2700                 :     2619806 :             remaining_partitions[num_partitions] = i;
    2701                 :     2619806 :             num_partitions++;
    2702                 :             :         }
    2703                 :    11918336 :         partitions[i].next_offset = total;
    2704                 :             :     }
    2705                 :             : 
    2706                 :             :     /*
    2707                 :             :      * Swap tuples to correct partition.
    2708                 :             :      *
    2709                 :             :      * In traditional American flag sort, a swap sends the current element to
    2710                 :             :      * the correct partition, but the array pointer only advances if the
    2711                 :             :      * partner of the swap happens to be an element that belongs in the
    2712                 :             :      * current partition. That only requires one pass through the array, but
    2713                 :             :      * the disadvantage is we don't know if the pointer can advance until the
    2714                 :             :      * swap completes. Here lies the most interesting innovation from the
    2715                 :             :      * upstream ska_byte_sort: After initiating the swap, we immediately
    2716                 :             :      * proceed to the next element. This makes better use of CPU pipelining,
    2717                 :             :      * but also means that we will often need multiple iterations of this
    2718                 :             :      * loop. ska_byte_sort() maintains a separate list of which partitions
    2719                 :             :      * haven't finished, which is updated every loop iteration. Here we simply
    2720                 :             :      * check each partition during every iteration.
    2721                 :             :      *
    2722                 :             :      * If we started with a single partition, there is nothing to do. If a
    2723                 :             :      * previous loop iteration results in only one partition that hasn't been
    2724                 :             :      * counted as sorted, we know it's actually sorted and can exit the loop.
    2725                 :             :      */
    2726                 :       46556 :     num_remaining = num_partitions;
    2727         [ +  + ]:      192832 :     while (num_remaining > 1)
    2728                 :             :     {
    2729                 :             :         /* start the count over */
    2730                 :      146276 :         num_remaining = num_partitions;
    2731                 :             : 
    2732         [ +  + ]:    11630627 :         for (int i = 0; i < num_partitions; i++)
    2733                 :             :         {
    2734                 :    11484351 :             uint8       idx = remaining_partitions[i];
    2735                 :             : 
    2736                 :    11484351 :             for (SortTuple *st = begin + partitions[idx].offset;
    2737         [ +  + ]:    28433415 :                  st < begin + partitions[idx].next_offset;
    2738                 :    16949064 :                  st++)
    2739                 :             :             {
    2740                 :    16949064 :                 size_t      offset = partitions[st->curbyte].offset++;
    2741                 :             :                 SortTuple   tmp;
    2742                 :             : 
    2743                 :             :                 /* swap current tuple with destination position */
    2744                 :             :                 Assert(offset < n_elems);
    2745                 :    16949064 :                 tmp = *st;
    2746                 :    16949064 :                 *st = begin[offset];
    2747                 :    16949064 :                 begin[offset] = tmp;
    2748                 :             : 
    2749         [ +  + ]:    16949064 :                 CHECK_FOR_INTERRUPTS();
    2750                 :             :             };
    2751                 :             : 
    2752                 :             :             /* Is this partition sorted? */
    2753         [ +  + ]:    11484351 :             if (partitions[idx].offset == partitions[idx].next_offset)
    2754                 :     8856995 :                 num_remaining--;
    2755                 :             :         }
    2756                 :             :     }
    2757                 :             : 
    2758                 :             :     /* recurse */
    2759                 :             : 
    2760         [ +  + ]:       46556 :     if (num_partitions == 1)
    2761                 :             :     {
    2762                 :             :         /*
    2763                 :             :          * There is only one distinct byte at the current level. It can happen
    2764                 :             :          * that some subsequent bytes are also the same for all input values,
    2765                 :             :          * such as the upper bytes of small integers. To skip unproductive
    2766                 :             :          * passes for that case, we compute the level where the input has more
    2767                 :             :          * than one distinct byte, so that the next recursion can start there.
    2768                 :             :          */
    2769         [ +  + ]:        9099 :         if (common_upper_bits == 0)
    2770                 :         963 :             next_level = sizeof(Datum);
    2771                 :             :         else
    2772                 :             :         {
    2773                 :             :             int         diffpos;
    2774                 :             : 
    2775                 :             :             /*
    2776                 :             :              * The upper bits of common_upper_bits are zero where all datums
    2777                 :             :              * have the same bits.
    2778                 :             :              */
    2779                 :        8136 :             diffpos = pg_leftmost_one_pos64(DatumGetUInt64(common_upper_bits));
    2780                 :        8136 :             next_level = sizeof(Datum) - 1 - (diffpos / BITS_PER_BYTE);
    2781                 :             :         }
    2782                 :             :     }
    2783                 :             :     else
    2784                 :       37457 :         next_level = level + 1;
    2785                 :             : 
    2786                 :             :     Assert(next_level > level);
    2787                 :             : 
    2788                 :       46556 :     for (uint8 *rp = remaining_partitions;
    2789         [ +  + ]:     2666362 :          rp < remaining_partitions + num_partitions;
    2790                 :     2619806 :          rp++)
    2791                 :             :     {
    2792                 :     2619806 :         size_t      end_offset = partitions[*rp].next_offset;
    2793                 :     2619806 :         SortTuple  *partition_end = begin + end_offset;
    2794                 :     2619806 :         size_t      num_elements = end_offset - start_offset;
    2795                 :             : 
    2796         [ +  + ]:     2619806 :         if (num_elements > 1)
    2797                 :             :         {
    2798         [ +  + ]:      868736 :             if (next_level < sizeof(Datum))
    2799                 :             :             {
    2800         [ +  + ]:      681625 :                 if (num_elements < QSORT_THRESHOLD)
    2801                 :             :                 {
    2802                 :      640365 :                     qsort_tuple(partition_begin,
    2803                 :             :                                 num_elements,
    2804                 :             :                                 state->base.comparetup,
    2805                 :             :                                 state);
    2806                 :             :                 }
    2807                 :             :                 else
    2808                 :             :                 {
    2809                 :       41260 :                     radix_sort_recursive(partition_begin,
    2810                 :             :                                          num_elements,
    2811                 :             :                                          next_level,
    2812                 :             :                                          state);
    2813                 :             :                 }
    2814                 :             :             }
    2815         [ +  + ]:      187111 :             else if (state->base.onlyKey == NULL)
    2816                 :             :             {
    2817                 :             :                 /*
    2818                 :             :                  * We've finished radix sort on all bytes of the pass-by-value
    2819                 :             :                  * datum (possibly abbreviated), now sort using the tiebreak
    2820                 :             :                  * comparator.
    2821                 :             :                  */
    2822                 :       93272 :                 qsort_tuple(partition_begin,
    2823                 :             :                             num_elements,
    2824                 :             :                             state->base.comparetup_tiebreak,
    2825                 :             :                             state);
    2826                 :             :             }
    2827                 :             :         }
    2828                 :             : 
    2829                 :     2619806 :         start_offset = end_offset;
    2830                 :     2619806 :         partition_begin = partition_end;
    2831                 :             :     }
    2832                 :       46556 : }
    2833                 :             : 
    2834                 :             : /*
    2835                 :             :  * Entry point for radix_sort_recursive
    2836                 :             :  *
    2837                 :             :  * Partition tuples by isnull1, then sort both partitions, using
    2838                 :             :  * radix sort on the NOT NULL partition if it's large enough.
    2839                 :             :  */
    2840                 :             : static void
    2841                 :        7111 : radix_sort_tuple(SortTuple *data, size_t n, Tuplesortstate *state)
    2842                 :             : {
    2843                 :        7111 :     bool        nulls_first = state->base.sortKeys[0].ssup_nulls_first;
    2844                 :             :     SortTuple  *null_start;
    2845                 :             :     SortTuple  *not_null_start;
    2846                 :        7111 :     size_t      d1 = 0,
    2847                 :             :                 d2,
    2848                 :             :                 null_count,
    2849                 :             :                 not_null_count;
    2850                 :             : 
    2851                 :             :     /*
    2852                 :             :      * Find the first NOT NULL if NULLS FIRST, or first NULL if NULLS LAST.
    2853                 :             :      * This also serves as a quick check for the common case where all tuples
    2854                 :             :      * are NOT NULL in the first sort key with the default order ASC NULLS
    2855                 :             :      * LAST.
    2856                 :             :      */
    2857   [ +  +  +  + ]:    12916466 :     while (d1 < n && data[d1].isnull1 == nulls_first)
    2858                 :             :     {
    2859                 :    12909355 :         d1++;
    2860         [ -  + ]:    12909355 :         CHECK_FOR_INTERRUPTS();
    2861                 :             :     }
    2862                 :             : 
    2863                 :             :     /*
    2864                 :             :      * If we have more than one tuple left after the quick check, partition
    2865                 :             :      * the remainder using branchless cyclic permutation, based on
    2866                 :             :      * https://orlp.net/blog/branchless-lomuto-partitioning/
    2867                 :             :      */
    2868                 :             :     Assert(n > 0);
    2869         [ +  + ]:        7111 :     if (d1 < n - 1)
    2870                 :             :     {
    2871                 :         737 :         size_t      i = d1,
    2872                 :         737 :                     j = d1;
    2873                 :         737 :         SortTuple   tmp = data[d1]; /* create gap at front */
    2874                 :             : 
    2875         [ +  + ]:      443839 :         while (j < n - 1)
    2876                 :             :         {
    2877                 :             :             /* gap is at j, move i's element to gap */
    2878                 :      443102 :             data[j] = data[i];
    2879                 :             :             /* advance j to the first unknown element */
    2880                 :      443102 :             j += 1;
    2881                 :             :             /* move the first unknown element back to i */
    2882                 :      443102 :             data[i] = data[j];
    2883                 :             :             /* advance i if this element belongs in the left partition */
    2884                 :      443102 :             i += (data[i].isnull1 == nulls_first);
    2885                 :             : 
    2886         [ -  + ]:      443102 :             CHECK_FOR_INTERRUPTS();
    2887                 :             :         }
    2888                 :             : 
    2889                 :             :         /* place gap between left and right partitions */
    2890                 :         737 :         data[j] = data[i];
    2891                 :             :         /* restore the saved element */
    2892                 :         737 :         data[i] = tmp;
    2893                 :             :         /* assign it to the correct partition */
    2894                 :         737 :         i += (data[i].isnull1 == nulls_first);
    2895                 :             : 
    2896                 :             :         /* d1 is now the number of elements in the left partition */
    2897                 :         737 :         d1 = i;
    2898                 :             :     }
    2899                 :             : 
    2900                 :        7111 :     d2 = n - d1;
    2901                 :             : 
    2902                 :             :     /* set pointers and counts for each partition */
    2903         [ +  + ]:        7111 :     if (nulls_first)
    2904                 :             :     {
    2905                 :         632 :         null_start = data;
    2906                 :         632 :         null_count = d1;
    2907                 :         632 :         not_null_start = data + d1;
    2908                 :         632 :         not_null_count = d2;
    2909                 :             :     }
    2910                 :             :     else
    2911                 :             :     {
    2912                 :        6479 :         not_null_start = data;
    2913                 :        6479 :         not_null_count = d1;
    2914                 :        6479 :         null_start = data + d1;
    2915                 :        6479 :         null_count = d2;
    2916                 :             :     }
    2917                 :             : 
    2918                 :        7111 :     for (SortTuple *st = null_start;
    2919         [ +  + ]:        9518 :          st < null_start + null_count;
    2920                 :        2407 :          st++)
    2921                 :             :         Assert(st->isnull1 == true);
    2922                 :        7111 :     for (SortTuple *st = not_null_start;
    2923         [ +  + ]:    13357902 :          st < not_null_start + not_null_count;
    2924                 :    13350791 :          st++)
    2925                 :             :         Assert(st->isnull1 == false);
    2926                 :             : 
    2927                 :             :     /*
    2928                 :             :      * Sort the NULL partition using tiebreak comparator, if necessary.
    2929                 :             :      */
    2930   [ +  +  +  + ]:        7111 :     if (state->base.onlyKey == NULL && null_count > 1)
    2931                 :             :     {
    2932                 :         111 :         qsort_tuple(null_start,
    2933                 :             :                     null_count,
    2934                 :             :                     state->base.comparetup_tiebreak,
    2935                 :             :                     state);
    2936                 :             :     }
    2937                 :             : 
    2938                 :             :     /*
    2939                 :             :      * Sort the NOT NULL partition, using radix sort if large enough,
    2940                 :             :      * otherwise fall back to quicksort.
    2941                 :             :      */
    2942         [ +  + ]:        7111 :     if (not_null_count < QSORT_THRESHOLD)
    2943                 :             :     {
    2944                 :          14 :         qsort_tuple(not_null_start,
    2945                 :             :                     not_null_count,
    2946                 :             :                     state->base.comparetup,
    2947                 :             :                     state);
    2948                 :             :     }
    2949                 :             :     else
    2950                 :             :     {
    2951                 :        7097 :         bool        presorted = true;
    2952                 :             : 
    2953                 :        7097 :         for (SortTuple *st = not_null_start + 1;
    2954         [ +  + ]:     4733100 :              st < not_null_start + not_null_count;
    2955                 :     4726003 :              st++)
    2956                 :             :         {
    2957         [ +  + ]:     4731299 :             if (COMPARETUP(state, st - 1, st) > 0)
    2958                 :             :             {
    2959                 :        5296 :                 presorted = false;
    2960                 :        5296 :                 break;
    2961                 :             :             }
    2962                 :             : 
    2963         [ -  + ]:     4726003 :             CHECK_FOR_INTERRUPTS();
    2964                 :             :         }
    2965                 :             : 
    2966         [ +  + ]:        7097 :         if (presorted)
    2967                 :        1801 :             return;
    2968                 :             :         else
    2969                 :             :         {
    2970                 :        5296 :             radix_sort_recursive(not_null_start,
    2971                 :             :                                  not_null_count,
    2972                 :             :                                  0,
    2973                 :             :                                  state);
    2974                 :             :         }
    2975                 :             :     }
    2976                 :             : }
    2977                 :             : 
    2978                 :             : /* Verify in-memory sort using standard comparator. */
    2979                 :             : static void
    2980                 :        7111 : verify_memtuples_sorted(Tuplesortstate *state)
    2981                 :             : {
    2982                 :             : #ifdef USE_ASSERT_CHECKING
    2983                 :             :     for (SortTuple *st = state->memtuples + 1;
    2984                 :             :          st < state->memtuples + state->memtupcount;
    2985                 :             :          st++)
    2986                 :             :         Assert(COMPARETUP(state, st - 1, st) <= 0);
    2987                 :             : #endif
    2988                 :        7111 : }
    2989                 :             : 
    2990                 :             : /*
    2991                 :             :  * Sort all memtuples using specialized routines.
    2992                 :             :  *
    2993                 :             :  * Quicksort or radix sort is used for small in-memory sorts,
    2994                 :             :  * and external sort runs.
    2995                 :             :  */
    2996                 :             : static void
    2997                 :      151167 : tuplesort_sort_memtuples(Tuplesortstate *state)
    2998                 :             : {
    2999                 :             :     Assert(!LEADER(state));
    3000                 :             : 
    3001         [ +  + ]:      151167 :     if (state->memtupcount > 1)
    3002                 :             :     {
    3003                 :             :         /*
    3004                 :             :          * Do we have the leading column's value or abbreviation in datum1?
    3005                 :             :          */
    3006   [ +  +  +  + ]:       44742 :         if (state->base.haveDatum1 && state->base.sortKeys)
    3007                 :             :         {
    3008                 :       44669 :             SortSupport ssup = &state->base.sortKeys[0];
    3009                 :             : 
    3010                 :             :             /* Does it compare as an integer? */
    3011         [ +  + ]:       44669 :             if (state->memtupcount >= QSORT_THRESHOLD &&
    3012         [ +  + ]:        8186 :                 (ssup->comparator == ssup_datum_unsigned_cmp ||
    3013         [ +  + ]:        4187 :                  ssup->comparator == ssup_datum_signed_cmp ||
    3014         [ +  + ]:        4012 :                  ssup->comparator == ssup_datum_int32_cmp))
    3015                 :             :             {
    3016                 :        7111 :                 radix_sort_tuple(state->memtuples,
    3017                 :        7111 :                                  state->memtupcount,
    3018                 :             :                                  state);
    3019                 :        7111 :                 verify_memtuples_sorted(state);
    3020                 :        7111 :                 return;
    3021                 :             :             }
    3022                 :             :         }
    3023                 :             : 
    3024                 :             :         /* Can we use the single-key sort function? */
    3025         [ +  + ]:       37631 :         if (state->base.onlyKey != NULL)
    3026                 :             :         {
    3027                 :       26307 :             qsort_ssup(state->memtuples, state->memtupcount,
    3028                 :       26307 :                        state->base.onlyKey);
    3029                 :             :         }
    3030                 :             :         else
    3031                 :             :         {
    3032                 :       11324 :             qsort_tuple(state->memtuples,
    3033                 :       11324 :                         state->memtupcount,
    3034                 :             :                         state->base.comparetup,
    3035                 :             :                         state);
    3036                 :             :         }
    3037                 :             :     }
    3038                 :             : }
    3039                 :             : 
    3040                 :             : /*
    3041                 :             :  * Insert a new tuple into an empty or existing heap, maintaining the
    3042                 :             :  * heap invariant.  Caller is responsible for ensuring there's room.
    3043                 :             :  *
    3044                 :             :  * Note: For some callers, tuple points to a memtuples[] entry above the
    3045                 :             :  * end of the heap.  This is safe as long as it's not immediately adjacent
    3046                 :             :  * to the end of the heap (ie, in the [memtupcount] array entry) --- if it
    3047                 :             :  * is, it might get overwritten before being moved into the heap!
    3048                 :             :  */
    3049                 :             : static void
    3050                 :       12767 : tuplesort_heap_insert(Tuplesortstate *state, SortTuple *tuple)
    3051                 :             : {
    3052                 :             :     SortTuple  *memtuples;
    3053                 :             :     int         j;
    3054                 :             : 
    3055                 :       12767 :     memtuples = state->memtuples;
    3056                 :             :     Assert(state->memtupcount < state->memtupsize);
    3057                 :             : 
    3058         [ +  + ]:       12767 :     CHECK_FOR_INTERRUPTS();
    3059                 :             : 
    3060                 :             :     /*
    3061                 :             :      * Sift-up the new entry, per Knuth 5.2.3 exercise 16. Note that Knuth is
    3062                 :             :      * using 1-based array indexes, not 0-based.
    3063                 :             :      */
    3064                 :       12767 :     j = state->memtupcount++;
    3065         [ +  + ]:       36124 :     while (j > 0)
    3066                 :             :     {
    3067                 :       31995 :         int         i = (j - 1) >> 1;
    3068                 :             : 
    3069         [ +  + ]:       31995 :         if (COMPARETUP(state, tuple, &memtuples[i]) >= 0)
    3070                 :        8638 :             break;
    3071                 :       23357 :         memtuples[j] = memtuples[i];
    3072                 :       23357 :         j = i;
    3073                 :             :     }
    3074                 :       12767 :     memtuples[j] = *tuple;
    3075                 :       12767 : }
    3076                 :             : 
    3077                 :             : /*
    3078                 :             :  * Remove the tuple at state->memtuples[0] from the heap.  Decrement
    3079                 :             :  * memtupcount, and sift up to maintain the heap invariant.
    3080                 :             :  *
    3081                 :             :  * The caller has already free'd the tuple the top node points to,
    3082                 :             :  * if necessary.
    3083                 :             :  */
    3084                 :             : static void
    3085                 :       12479 : tuplesort_heap_delete_top(Tuplesortstate *state)
    3086                 :             : {
    3087                 :       12479 :     SortTuple  *memtuples = state->memtuples;
    3088                 :             :     SortTuple  *tuple;
    3089                 :             : 
    3090         [ +  + ]:       12479 :     if (--state->memtupcount <= 0)
    3091                 :         217 :         return;
    3092                 :             : 
    3093                 :             :     /*
    3094                 :             :      * Remove the last tuple in the heap, and re-insert it, by replacing the
    3095                 :             :      * current top node with it.
    3096                 :             :      */
    3097                 :       12262 :     tuple = &memtuples[state->memtupcount];
    3098                 :       12262 :     tuplesort_heap_replace_top(state, tuple);
    3099                 :             : }
    3100                 :             : 
    3101                 :             : /*
    3102                 :             :  * Replace the tuple at state->memtuples[0] with a new tuple.  Sift up to
    3103                 :             :  * maintain the heap invariant.
    3104                 :             :  *
    3105                 :             :  * This corresponds to Knuth's "sift-up" algorithm (Algorithm 5.2.3H,
    3106                 :             :  * Heapsort, steps H3-H8).
    3107                 :             :  */
    3108                 :             : static void
    3109                 :     3677238 : tuplesort_heap_replace_top(Tuplesortstate *state, SortTuple *tuple)
    3110                 :             : {
    3111                 :     3677238 :     SortTuple  *memtuples = state->memtuples;
    3112                 :             :     unsigned int i,
    3113                 :             :                 n;
    3114                 :             : 
    3115                 :             :     Assert(state->memtupcount >= 1);
    3116                 :             : 
    3117         [ +  + ]:     3677238 :     CHECK_FOR_INTERRUPTS();
    3118                 :             : 
    3119                 :             :     /*
    3120                 :             :      * state->memtupcount is "int", but we use "unsigned int" for i, j, n.
    3121                 :             :      * This prevents overflow in the "2 * i + 1" calculation, since at the top
    3122                 :             :      * of the loop we must have i < n <= INT_MAX <= UINT_MAX/2.
    3123                 :             :      */
    3124                 :     3677238 :     n = state->memtupcount;
    3125                 :     3677238 :     i = 0;                      /* i is where the "hole" is */
    3126                 :             :     for (;;)
    3127                 :     1167423 :     {
    3128                 :     4844661 :         unsigned int j = 2 * i + 1;
    3129                 :             : 
    3130         [ +  + ]:     4844661 :         if (j >= n)
    3131                 :      749226 :             break;
    3132   [ +  +  +  + ]:     5730245 :         if (j + 1 < n &&
    3133                 :     1634810 :             COMPARETUP(state, &memtuples[j], &memtuples[j + 1]) > 0)
    3134                 :      646164 :             j++;
    3135         [ +  + ]:     4095435 :         if (COMPARETUP(state, tuple, &memtuples[j]) <= 0)
    3136                 :     2928012 :             break;
    3137                 :     1167423 :         memtuples[i] = memtuples[j];
    3138                 :     1167423 :         i = j;
    3139                 :             :     }
    3140                 :     3677238 :     memtuples[i] = *tuple;
    3141                 :     3677238 : }
    3142                 :             : 
    3143                 :             : /*
    3144                 :             :  * Function to reverse the sort direction from its current state
    3145                 :             :  *
    3146                 :             :  * It is not safe to call this when performing hash tuplesorts
    3147                 :             :  */
    3148                 :             : static void
    3149                 :         512 : reversedirection(Tuplesortstate *state)
    3150                 :             : {
    3151                 :         512 :     SortSupport sortKey = state->base.sortKeys;
    3152                 :             :     int         nkey;
    3153                 :             : 
    3154         [ +  + ]:        1248 :     for (nkey = 0; nkey < state->base.nKeys; nkey++, sortKey++)
    3155                 :             :     {
    3156                 :         736 :         sortKey->ssup_reverse = !sortKey->ssup_reverse;
    3157                 :         736 :         sortKey->ssup_nulls_first = !sortKey->ssup_nulls_first;
    3158                 :             :     }
    3159                 :         512 : }
    3160                 :             : 
    3161                 :             : 
    3162                 :             : /*
    3163                 :             :  * Tape interface routines
    3164                 :             :  */
    3165                 :             : 
    3166                 :             : static unsigned int
    3167                 :     3523058 : getlen(LogicalTape *tape, bool eofOK)
    3168                 :             : {
    3169                 :             :     unsigned int len;
    3170                 :             : 
    3171         [ -  + ]:     3523058 :     if (LogicalTapeRead(tape,
    3172                 :             :                         &len, sizeof(len)) != sizeof(len))
    3173         [ #  # ]:           0 :         elog(ERROR, "unexpected end of tape");
    3174   [ +  +  -  + ]:     3523058 :     if (len == 0 && !eofOK)
    3175         [ #  # ]:           0 :         elog(ERROR, "unexpected end of data");
    3176                 :     3523058 :     return len;
    3177                 :             : }
    3178                 :             : 
    3179                 :             : static void
    3180                 :        1200 : markrunend(LogicalTape *tape)
    3181                 :             : {
    3182                 :        1200 :     unsigned int len = 0;
    3183                 :             : 
    3184                 :        1200 :     LogicalTapeWrite(tape, &len, sizeof(len));
    3185                 :        1200 : }
    3186                 :             : 
    3187                 :             : /*
    3188                 :             :  * Get memory for tuple from within READTUP() routine.
    3189                 :             :  *
    3190                 :             :  * We use next free slot from the slab allocator, or palloc() if the tuple
    3191                 :             :  * is too large for that.
    3192                 :             :  */
    3193                 :             : void *
    3194                 :     3266817 : tuplesort_readtup_alloc(Tuplesortstate *state, Size tuplen)
    3195                 :             : {
    3196                 :             :     SlabSlot   *buf;
    3197                 :             : 
    3198                 :             :     /*
    3199                 :             :      * We pre-allocate enough slots in the slab arena that we should never run
    3200                 :             :      * out.
    3201                 :             :      */
    3202                 :             :     Assert(state->slabFreeHead);
    3203                 :             : 
    3204   [ +  +  -  + ]:     3266817 :     if (tuplen > SLAB_SLOT_SIZE || !state->slabFreeHead)
    3205                 :           4 :         return MemoryContextAlloc(state->base.sortcontext, tuplen);
    3206                 :             :     else
    3207                 :             :     {
    3208                 :     3266813 :         buf = state->slabFreeHead;
    3209                 :             :         /* Reuse this slot */
    3210                 :     3266813 :         state->slabFreeHead = buf->nextfree;
    3211                 :             : 
    3212                 :     3266813 :         return buf;
    3213                 :             :     }
    3214                 :             : }
    3215                 :             : 
    3216                 :             : 
    3217                 :             : /*
    3218                 :             :  * Parallel sort routines
    3219                 :             :  */
    3220                 :             : 
    3221                 :             : /*
    3222                 :             :  * tuplesort_estimate_shared - estimate required shared memory allocation
    3223                 :             :  *
    3224                 :             :  * nWorkers is an estimate of the number of workers (it's the number that
    3225                 :             :  * will be requested).
    3226                 :             :  */
    3227                 :             : Size
    3228                 :         131 : tuplesort_estimate_shared(int nWorkers)
    3229                 :             : {
    3230                 :             :     Size        tapesSize;
    3231                 :             : 
    3232                 :             :     Assert(nWorkers > 0);
    3233                 :             : 
    3234                 :             :     /* Make sure that BufFile shared state is MAXALIGN'd */
    3235                 :         131 :     tapesSize = mul_size(sizeof(TapeShare), nWorkers);
    3236                 :         131 :     tapesSize = MAXALIGN(add_size(tapesSize, offsetof(Sharedsort, tapes)));
    3237                 :             : 
    3238                 :         131 :     return tapesSize;
    3239                 :             : }
    3240                 :             : 
    3241                 :             : /*
    3242                 :             :  * tuplesort_initialize_shared - initialize shared tuplesort state
    3243                 :             :  *
    3244                 :             :  * Must be called from leader process before workers are launched, to
    3245                 :             :  * establish state needed up-front for worker tuplesortstates.  nWorkers
    3246                 :             :  * should match the argument passed to tuplesort_estimate_shared().
    3247                 :             :  */
    3248                 :             : void
    3249                 :         179 : tuplesort_initialize_shared(Sharedsort *shared, int nWorkers, dsm_segment *seg)
    3250                 :             : {
    3251                 :             :     int         i;
    3252                 :             : 
    3253                 :             :     Assert(nWorkers > 0);
    3254                 :             : 
    3255                 :         179 :     SpinLockInit(&shared->mutex);
    3256                 :         179 :     shared->currentWorker = 0;
    3257                 :         179 :     shared->workersFinished = 0;
    3258                 :         179 :     SharedFileSetInit(&shared->fileset, seg);
    3259                 :         179 :     shared->nTapes = nWorkers;
    3260         [ +  + ]:         562 :     for (i = 0; i < nWorkers; i++)
    3261                 :             :     {
    3262                 :         383 :         shared->tapes[i].firstblocknumber = 0L;
    3263                 :             :     }
    3264                 :         179 : }
    3265                 :             : 
    3266                 :             : /*
    3267                 :             :  * tuplesort_attach_shared - attach to shared tuplesort state
    3268                 :             :  *
    3269                 :             :  * Must be called by all worker processes.
    3270                 :             :  */
    3271                 :             : void
    3272                 :         201 : tuplesort_attach_shared(Sharedsort *shared, dsm_segment *seg)
    3273                 :             : {
    3274                 :             :     /* Attach to SharedFileSet */
    3275                 :         201 :     SharedFileSetAttach(&shared->fileset, seg);
    3276                 :         201 : }
    3277                 :             : 
    3278                 :             : /*
    3279                 :             :  * worker_get_identifier - Assign and return ordinal identifier for worker
    3280                 :             :  *
    3281                 :             :  * The order in which these are assigned is not well defined, and should not
    3282                 :             :  * matter; worker numbers across parallel sort participants need only be
    3283                 :             :  * distinct and gapless.  logtape.c requires this.
    3284                 :             :  *
    3285                 :             :  * Note that the identifiers assigned from here have no relation to
    3286                 :             :  * ParallelWorkerNumber number, to avoid making any assumption about
    3287                 :             :  * caller's requirements.  However, we do follow the ParallelWorkerNumber
    3288                 :             :  * convention of representing a non-worker with worker number -1.  This
    3289                 :             :  * includes the leader, as well as serial Tuplesort processes.
    3290                 :             :  */
    3291                 :             : static int
    3292                 :         379 : worker_get_identifier(Tuplesortstate *state)
    3293                 :             : {
    3294                 :         379 :     Sharedsort *shared = state->shared;
    3295                 :             :     int         worker;
    3296                 :             : 
    3297                 :             :     Assert(WORKER(state));
    3298                 :             : 
    3299                 :         379 :     SpinLockAcquire(&shared->mutex);
    3300                 :         379 :     worker = shared->currentWorker++;
    3301                 :         379 :     SpinLockRelease(&shared->mutex);
    3302                 :             : 
    3303                 :         379 :     return worker;
    3304                 :             : }
    3305                 :             : 
    3306                 :             : /*
    3307                 :             :  * worker_freeze_result_tape - freeze worker's result tape for leader
    3308                 :             :  *
    3309                 :             :  * This is called by workers just after the result tape has been determined,
    3310                 :             :  * instead of calling LogicalTapeFreeze() directly.  They do so because
    3311                 :             :  * workers require a few additional steps over similar serial
    3312                 :             :  * TSS_SORTEDONTAPE external sort cases, which also happen here.  The extra
    3313                 :             :  * steps are around freeing now unneeded resources, and representing to
    3314                 :             :  * leader that worker's input run is available for its merge.
    3315                 :             :  *
    3316                 :             :  * There should only be one final output run for each worker, which consists
    3317                 :             :  * of all tuples that were originally input into worker.
    3318                 :             :  */
    3319                 :             : static void
    3320                 :         379 : worker_freeze_result_tape(Tuplesortstate *state)
    3321                 :             : {
    3322                 :         379 :     Sharedsort *shared = state->shared;
    3323                 :             :     TapeShare   output;
    3324                 :             : 
    3325                 :             :     Assert(WORKER(state));
    3326                 :             :     Assert(state->result_tape != NULL);
    3327                 :             :     Assert(state->memtupcount == 0);
    3328                 :             : 
    3329                 :             :     /*
    3330                 :             :      * Free most remaining memory, in case caller is sensitive to our holding
    3331                 :             :      * on to it.  memtuples may not be a tiny merge heap at this point.
    3332                 :             :      */
    3333                 :         379 :     pfree(state->memtuples);
    3334                 :             :     /* Be tidy */
    3335                 :         379 :     state->memtuples = NULL;
    3336                 :         379 :     state->memtupsize = 0;
    3337                 :             : 
    3338                 :             :     /*
    3339                 :             :      * Parallel worker requires result tape metadata, which is to be stored in
    3340                 :             :      * shared memory for leader
    3341                 :             :      */
    3342                 :         379 :     LogicalTapeFreeze(state->result_tape, &output);
    3343                 :             : 
    3344                 :             :     /* Store properties of output tape, and update finished worker count */
    3345                 :         379 :     SpinLockAcquire(&shared->mutex);
    3346                 :         379 :     shared->tapes[state->worker] = output;
    3347                 :         379 :     shared->workersFinished++;
    3348                 :         379 :     SpinLockRelease(&shared->mutex);
    3349                 :         379 : }
    3350                 :             : 
    3351                 :             : /*
    3352                 :             :  * worker_nomergeruns - dump memtuples in worker, without merging
    3353                 :             :  *
    3354                 :             :  * This called as an alternative to mergeruns() with a worker when no
    3355                 :             :  * merging is required.
    3356                 :             :  */
    3357                 :             : static void
    3358                 :         379 : worker_nomergeruns(Tuplesortstate *state)
    3359                 :             : {
    3360                 :             :     Assert(WORKER(state));
    3361                 :             :     Assert(state->result_tape == NULL);
    3362                 :             :     Assert(state->nOutputRuns == 1);
    3363                 :             : 
    3364                 :         379 :     state->result_tape = state->destTape;
    3365                 :         379 :     worker_freeze_result_tape(state);
    3366                 :         379 : }
    3367                 :             : 
    3368                 :             : /*
    3369                 :             :  * leader_takeover_tapes - create tapeset for leader from worker tapes
    3370                 :             :  *
    3371                 :             :  * So far, leader Tuplesortstate has performed no actual sorting.  By now, all
    3372                 :             :  * sorting has occurred in workers, all of which must have already returned
    3373                 :             :  * from tuplesort_performsort().
    3374                 :             :  *
    3375                 :             :  * When this returns, leader process is left in a state that is virtually
    3376                 :             :  * indistinguishable from it having generated runs as a serial external sort
    3377                 :             :  * might have.
    3378                 :             :  */
    3379                 :             : static void
    3380                 :         130 : leader_takeover_tapes(Tuplesortstate *state)
    3381                 :             : {
    3382                 :         130 :     Sharedsort *shared = state->shared;
    3383                 :         130 :     int         nParticipants = state->nParticipants;
    3384                 :             :     int         workersFinished;
    3385                 :             :     int         j;
    3386                 :             : 
    3387                 :             :     Assert(LEADER(state));
    3388                 :             :     Assert(nParticipants >= 1);
    3389                 :             : 
    3390                 :         130 :     SpinLockAcquire(&shared->mutex);
    3391                 :         130 :     workersFinished = shared->workersFinished;
    3392                 :         130 :     SpinLockRelease(&shared->mutex);
    3393                 :             : 
    3394         [ -  + ]:         130 :     if (nParticipants != workersFinished)
    3395         [ #  # ]:           0 :         elog(ERROR, "cannot take over tapes before all workers finish");
    3396                 :             : 
    3397                 :             :     /*
    3398                 :             :      * Create the tapeset from worker tapes, including a leader-owned tape at
    3399                 :             :      * the end.  Parallel workers are far more expensive than logical tapes,
    3400                 :             :      * so the number of tapes allocated here should never be excessive.
    3401                 :             :      */
    3402                 :         130 :     inittapestate(state, nParticipants);
    3403                 :         130 :     state->tapeset = LogicalTapeSetCreate(false, &shared->fileset, -1);
    3404                 :             : 
    3405                 :             :     /*
    3406                 :             :      * Set currentRun to reflect the number of runs we will merge (it's not
    3407                 :             :      * used for anything, this is just pro forma)
    3408                 :             :      */
    3409                 :         130 :     state->currentRun = nParticipants;
    3410                 :             : 
    3411                 :             :     /*
    3412                 :             :      * Initialize the state to look the same as after building the initial
    3413                 :             :      * runs.
    3414                 :             :      *
    3415                 :             :      * There will always be exactly 1 run per worker, and exactly one input
    3416                 :             :      * tape per run, because workers always output exactly 1 run, even when
    3417                 :             :      * there were no input tuples for workers to sort.
    3418                 :             :      */
    3419                 :         130 :     state->inputTapes = NULL;
    3420                 :         130 :     state->nInputTapes = 0;
    3421                 :         130 :     state->nInputRuns = 0;
    3422                 :             : 
    3423                 :         130 :     state->outputTapes = palloc0(nParticipants * sizeof(LogicalTape *));
    3424                 :         130 :     state->nOutputTapes = nParticipants;
    3425                 :         130 :     state->nOutputRuns = nParticipants;
    3426                 :             : 
    3427         [ +  + ]:         413 :     for (j = 0; j < nParticipants; j++)
    3428                 :             :     {
    3429                 :         283 :         state->outputTapes[j] = LogicalTapeImport(state->tapeset, j, &shared->tapes[j]);
    3430                 :             :     }
    3431                 :             : 
    3432                 :         130 :     state->status = TSS_BUILDRUNS;
    3433                 :         130 : }
    3434                 :             : 
    3435                 :             : /*
    3436                 :             :  * Convenience routine to free a tuple previously loaded into sort memory
    3437                 :             :  */
    3438                 :             : static void
    3439                 :     2149159 : free_sort_tuple(Tuplesortstate *state, SortTuple *stup)
    3440                 :             : {
    3441         [ +  + ]:     2149159 :     if (stup->tuple)
    3442                 :             :     {
    3443                 :     2044152 :         FREEMEM(state, GetMemoryChunkSpace(stup->tuple));
    3444                 :     2044152 :         pfree(stup->tuple);
    3445                 :     2044152 :         stup->tuple = NULL;
    3446                 :             :     }
    3447                 :     2149159 : }
    3448                 :             : 
    3449                 :             : int
    3450                 :   122780141 : ssup_datum_unsigned_cmp(Datum x, Datum y, SortSupport ssup)
    3451                 :             : {
    3452         [ +  + ]:   122780141 :     if (x < y)
    3453                 :    29876537 :         return -1;
    3454         [ +  + ]:    92903604 :     else if (x > y)
    3455                 :    30037645 :         return 1;
    3456                 :             :     else
    3457                 :    62865959 :         return 0;
    3458                 :             : }
    3459                 :             : 
    3460                 :             : int
    3461                 :     1732113 : ssup_datum_signed_cmp(Datum x, Datum y, SortSupport ssup)
    3462                 :             : {
    3463                 :     1732113 :     int64       xx = DatumGetInt64(x);
    3464                 :     1732113 :     int64       yy = DatumGetInt64(y);
    3465                 :             : 
    3466         [ +  + ]:     1732113 :     if (xx < yy)
    3467                 :     1263321 :         return -1;
    3468         [ +  + ]:      468792 :     else if (xx > yy)
    3469                 :      231712 :         return 1;
    3470                 :             :     else
    3471                 :      237080 :         return 0;
    3472                 :             : }
    3473                 :             : 
    3474                 :             : int
    3475                 :   157058996 : ssup_datum_int32_cmp(Datum x, Datum y, SortSupport ssup)
    3476                 :             : {
    3477                 :   157058996 :     int32       xx = DatumGetInt32(x);
    3478                 :   157058996 :     int32       yy = DatumGetInt32(y);
    3479                 :             : 
    3480         [ +  + ]:   157058996 :     if (xx < yy)
    3481                 :    34302712 :         return -1;
    3482         [ +  + ]:   122756284 :     else if (xx > yy)
    3483                 :    30771166 :         return 1;
    3484                 :             :     else
    3485                 :    91985118 :         return 0;
    3486                 :             : }
        

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