/*------------------------------------------------------------------------- * * tuplesort.h * Generalized tuple sorting routines. * * This module handles sorting of heap tuples, index tuples, or single * Datums (and could easily support other kinds of sortable objects, * if necessary). It works efficiently for both small and large amounts * of data. Small amounts are sorted in-memory using qsort(). Large * amounts are sorted using temporary files and a standard external sort * algorithm. Parallel sorts use a variant of this external sort * algorithm, and are typically only used for large amounts of data. * * Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * src/include/utils/tuplesort.h * *------------------------------------------------------------------------- */ #ifndef TUPLESORT_H #define TUPLESORT_H #include "access/itup.h" #include "executor/tuptable.h" #include "storage/dsm.h" #include "utils/relcache.h" /* * Tuplesortstate and Sharedsort are opaque types whose details are not * known outside tuplesort.c. */ typedef struct Tuplesortstate Tuplesortstate; typedef struct Sharedsort Sharedsort; /* * Tuplesort parallel coordination state, allocated by each participant in * local memory. Participant caller initializes everything. See usage notes * below. */ typedef struct SortCoordinateData { /* Worker process? If not, must be leader. */ bool isWorker; /* * Leader-process-passed number of participants known launched (workers * set this to -1). Includes state within leader needed for it to * participate as a worker, if any. */ int nParticipants; /* Private opaque state (points to shared memory) */ Sharedsort *sharedsort; } SortCoordinateData; typedef struct SortCoordinateData *SortCoordinate; /* * Data structures for reporting sort statistics. Note that * TuplesortInstrumentation can't contain any pointers because we * sometimes put it in shared memory. * * The parallel-sort infrastructure relies on having a zero TuplesortMethod * to indicate that a worker never did anything, so we assign zero to * SORT_TYPE_STILL_IN_PROGRESS. The other values of this enum can be * OR'ed together to represent a situation where different workers used * different methods, so we need a separate bit for each one. Keep the * NUM_TUPLESORTMETHODS constant in sync with the number of bits! */ typedef enum { SORT_TYPE_STILL_IN_PROGRESS = 0, SORT_TYPE_TOP_N_HEAPSORT = 1 << 0, SORT_TYPE_QUICKSORT = 1 << 1, SORT_TYPE_EXTERNAL_SORT = 1 << 2, SORT_TYPE_EXTERNAL_MERGE = 1 << 3 } TuplesortMethod; #define NUM_TUPLESORTMETHODS 4 typedef enum { SORT_SPACE_TYPE_DISK, SORT_SPACE_TYPE_MEMORY } TuplesortSpaceType; /* Bitwise option flags for tuple sorts */ #define TUPLESORT_NONE 0 /* specifies whether non-sequential access to the sort result is required */ #define TUPLESORT_RANDOMACCESS (1 << 0) /* specifies if the tuplesort is able to support bounded sorts */ #define TUPLESORT_ALLOWBOUNDED (1 << 1) typedef struct TuplesortInstrumentation { TuplesortMethod sortMethod; /* sort algorithm used */ TuplesortSpaceType spaceType; /* type of space spaceUsed represents */ int64 spaceUsed; /* space consumption, in kB */ } TuplesortInstrumentation; /* * We provide multiple interfaces to what is essentially the same code, * since different callers have different data to be sorted and want to * specify the sort key information differently. There are two APIs for * sorting HeapTuples and two more for sorting IndexTuples. Yet another * API supports sorting bare Datums. * * Serial sort callers should pass NULL for their coordinate argument. * * The "heap" API actually stores/sorts MinimalTuples, which means it doesn't * preserve the system columns (tuple identity and transaction visibility * info). The sort keys are specified by column numbers within the tuples * and sort operator OIDs. We save some cycles by passing and returning the * tuples in TupleTableSlots, rather than forming actual HeapTuples (which'd * have to be converted to MinimalTuples). This API works well for sorts * executed as parts of plan trees. * * The "cluster" API stores/sorts full HeapTuples including all visibility * info. The sort keys are specified by reference to a btree index that is * defined on the relation to be sorted. Note that putheaptuple/getheaptuple * go with this API, not the "begin_heap" one! * * The "index_btree" API stores/sorts IndexTuples (preserving all their * header fields). The sort keys are specified by a btree index definition. * * The "index_hash" API is similar to index_btree, but the tuples are * actually sorted by their hash codes not the raw data. * * Parallel sort callers are required to coordinate multiple tuplesort states * in a leader process and one or more worker processes. The leader process * must launch workers, and have each perform an independent "partial" * tuplesort, typically fed by the parallel heap interface. The leader later * produces the final output (internally, it merges runs output by workers). * * Callers must do the following to perform a sort in parallel using multiple * worker processes: * * 1. Request tuplesort-private shared memory for n workers. Use * tuplesort_estimate_shared() to get the required size. * 2. Have leader process initialize allocated shared memory using * tuplesort_initialize_shared(). Launch workers. * 3. Initialize a coordinate argument within both the leader process, and * for each worker process. This has a pointer to the shared * tuplesort-private structure, as well as some caller-initialized fields. * Leader's coordinate argument reliably indicates number of workers * launched (this is unused by workers). * 4. Begin a tuplesort using some appropriate tuplesort_begin* routine, * (passing the coordinate argument) within each worker. The workMem * arguments need not be identical. All other arguments should match * exactly, though. * 5. tuplesort_attach_shared() should be called by all workers. Feed tuples * to each worker, and call tuplesort_performsort() within each when input * is exhausted. * 6. Call tuplesort_end() in each worker process. Worker processes can shut * down once tuplesort_end() returns. * 7. Begin a tuplesort in the leader using the same tuplesort_begin* * routine, passing a leader-appropriate coordinate argument (this can * happen as early as during step 3, actually, since we only need to know * the number of workers successfully launched). The leader must now wait * for workers to finish. Caller must use own mechanism for ensuring that * next step isn't reached until all workers have called and returned from * tuplesort_performsort(). (Note that it's okay if workers have already * also called tuplesort_end() by then.) * 8. Call tuplesort_performsort() in leader. Consume output using the * appropriate tuplesort_get* routine. Leader can skip this step if * tuplesort turns out to be unnecessary. * 9. Call tuplesort_end() in leader. * * This division of labor assumes nothing about how input tuples are produced, * but does require that caller combine the state of multiple tuplesorts for * any purpose other than producing the final output. For example, callers * must consider that tuplesort_get_stats() reports on only one worker's role * in a sort (or the leader's role), and not statistics for the sort as a * whole. * * Note that callers may use the leader process to sort runs as if it was an * independent worker process (prior to the process performing a leader sort * to produce the final sorted output). Doing so only requires a second * "partial" tuplesort within the leader process, initialized like that of a * worker process. The steps above don't touch on this directly. The only * difference is that the tuplesort_attach_shared() call is never needed within * leader process, because the backend as a whole holds the shared fileset * reference. A worker Tuplesortstate in leader is expected to do exactly the * same amount of total initial processing work as a worker process * Tuplesortstate, since the leader process has nothing else to do before * workers finish. * * Note that only a very small amount of memory will be allocated prior to * the leader state first consuming input, and that workers will free the * vast majority of their memory upon returning from tuplesort_performsort(). * Callers can rely on this to arrange for memory to be used in a way that * respects a workMem-style budget across an entire parallel sort operation. * * Callers are responsible for parallel safety in general. However, they * can at least rely on there being no parallel safety hazards within * tuplesort, because tuplesort thinks of the sort as several independent * sorts whose results are combined. Since, in general, the behavior of * sort operators is immutable, caller need only worry about the parallel * safety of whatever the process is through which input tuples are * generated (typically, caller uses a parallel heap scan). */ extern Tuplesortstate *tuplesort_begin_heap(TupleDesc tupDesc, int nkeys, AttrNumber *attNums, Oid *sortOperators, Oid *sortCollations, bool *nullsFirstFlags, int workMem, SortCoordinate coordinate, int sortopt); extern Tuplesortstate *tuplesort_begin_cluster(TupleDesc tupDesc, Relation indexRel, int workMem, SortCoordinate coordinate, int sortopt); extern Tuplesortstate *tuplesort_begin_index_btree(Relation heapRel, Relation indexRel, bool enforceUnique, bool uniqueNullsNotDistinct, int workMem, SortCoordinate coordinate, int sortopt); extern Tuplesortstate *tuplesort_begin_index_hash(Relation heapRel, Relation indexRel, uint32 high_mask, uint32 low_mask, uint32 max_buckets, int workMem, SortCoordinate coordinate, int sortopt); extern Tuplesortstate *tuplesort_begin_index_gist(Relation heapRel, Relation indexRel, int workMem, SortCoordinate coordinate, int sortopt); extern Tuplesortstate *tuplesort_begin_datum(Oid datumType, Oid sortOperator, Oid sortCollation, bool nullsFirstFlag, int workMem, SortCoordinate coordinate, int sortopt); extern void tuplesort_set_bound(Tuplesortstate *state, int64 bound); extern bool tuplesort_used_bound(Tuplesortstate *state); extern void tuplesort_puttupleslot(Tuplesortstate *state, TupleTableSlot *slot); extern void tuplesort_putheaptuple(Tuplesortstate *state, HeapTuple tup); extern void tuplesort_putindextuplevalues(Tuplesortstate *state, Relation rel, ItemPointer self, Datum *values, bool *isnull); extern void tuplesort_putdatum(Tuplesortstate *state, Datum val, bool isNull); extern void tuplesort_performsort(Tuplesortstate *state); extern bool tuplesort_gettupleslot(Tuplesortstate *state, bool forward, bool copy, TupleTableSlot *slot, Datum *abbrev); extern HeapTuple tuplesort_getheaptuple(Tuplesortstate *state, bool forward); extern IndexTuple tuplesort_getindextuple(Tuplesortstate *state, bool forward); extern bool tuplesort_getdatum(Tuplesortstate *state, bool forward, Datum *val, bool *isNull, Datum *abbrev); extern bool tuplesort_skiptuples(Tuplesortstate *state, int64 ntuples, bool forward); extern void tuplesort_end(Tuplesortstate *state); extern void tuplesort_reset(Tuplesortstate *state); extern void tuplesort_get_stats(Tuplesortstate *state, TuplesortInstrumentation *stats); extern const char *tuplesort_method_name(TuplesortMethod m); extern const char *tuplesort_space_type_name(TuplesortSpaceType t); extern int tuplesort_merge_order(int64 allowedMem); extern Size tuplesort_estimate_shared(int nworkers); extern void tuplesort_initialize_shared(Sharedsort *shared, int nWorkers, dsm_segment *seg); extern void tuplesort_attach_shared(Sharedsort *shared, dsm_segment *seg); /* * These routines may only be called if TUPLESORT_RANDOMACCESS was specified * during tuplesort_begin_*. Additionally backwards scan in gettuple/getdatum * also require TUPLESORT_RANDOMACCESS. Note that parallel sorts do not * support random access. */ extern void tuplesort_rescan(Tuplesortstate *state); extern void tuplesort_markpos(Tuplesortstate *state); extern void tuplesort_restorepos(Tuplesortstate *state); #endif /* TUPLESORT_H */