path: root/src/backend/executor/execGrouping.c

/*-------------------------------------------------------------------------
 *
 * execGrouping.c
 *	  executor utility routines for grouping, hashing, and aggregation
 *
 * Note: we currently assume that equality and hashing functions are not
 * collation-sensitive, so the code in this file has no support for passing
 * collation settings through from callers.  That may have to change someday.
 *
 * Portions Copyright (c) 1996-2017, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *	  src/backend/executor/execGrouping.c
 *
 *-------------------------------------------------------------------------
 */
#include "postgres.h"

#include "access/hash.h"
#include "access/parallel.h"
#include "executor/executor.h"
#include "miscadmin.h"
#include "utils/lsyscache.h"
#include "utils/memutils.h"

static uint32 TupleHashTableHash(struct tuplehash_hash *tb, const MinimalTuple tuple);
static int	TupleHashTableMatch(struct tuplehash_hash *tb, const MinimalTuple tuple1, const MinimalTuple tuple2);

/*
 * Define parameters for tuple hash table code generation. The interface is
 * *also* declared in execnodes.h (to generate the types, which are externally
 * visible).
 */
#define SH_PREFIX tuplehash
#define SH_ELEMENT_TYPE TupleHashEntryData
#define SH_KEY_TYPE MinimalTuple
#define SH_KEY firstTuple
#define SH_HASH_KEY(tb, key) TupleHashTableHash(tb, key)
#define SH_EQUAL(tb, a, b) TupleHashTableMatch(tb, a, b) == 0
#define SH_SCOPE extern
#define SH_STORE_HASH
#define SH_GET_HASH(tb, a) a->hash
#define SH_DEFINE
#include "lib/simplehash.h"


/*****************************************************************************
 *		Utility routines for grouping tuples together
 *****************************************************************************/

/*
 * execTuplesMatch
 *		Return true if two tuples match in all the indicated fields.
 *
 * This actually implements SQL's notion of "not distinct".  Two nulls
 * match, a null and a not-null don't match.
 *
 * slot1, slot2: the tuples to compare (must have same columns!)
 * numCols: the number of attributes to be examined
 * matchColIdx: array of attribute column numbers
 * eqFunctions: array of fmgr lookup info for the equality functions to use
 * evalContext: short-term memory context for executing the functions
 *
 * NB: evalContext is reset each time!
 */
bool
execTuplesMatch(TupleTableSlot *slot1,
				TupleTableSlot *slot2,
				int numCols,
				AttrNumber *matchColIdx,
				FmgrInfo *eqfunctions,
				MemoryContext evalContext)
{
	MemoryContext oldContext;
	bool		result;
	int			i;

	/* Reset and switch into the temp context. */
	MemoryContextReset(evalContext);
	oldContext = MemoryContextSwitchTo(evalContext);

	/*
	 * We cannot report a match without checking all the fields, but we can
	 * report a non-match as soon as we find unequal fields.  So, start
	 * comparing at the last field (least significant sort key). That's the
	 * most likely to be different if we are dealing with sorted input.
	 */
	result = true;

	for (i = numCols; --i >= 0;)
	{
		AttrNumber	att = matchColIdx[i];
		Datum		attr1,
					attr2;
		bool		isNull1,
					isNull2;

		attr1 = slot_getattr(slot1, att, &isNull1);

		attr2 = slot_getattr(slot2, att, &isNull2);

		if (isNull1 != isNull2)
		{
			result = false;		/* one null and one not; they aren't equal */
			break;
		}

		if (isNull1)
			continue;			/* both are null, treat as equal */

		/* Apply the type-specific equality function */

		if (!DatumGetBool(FunctionCall2(&eqfunctions[i],
										attr1, attr2)))
		{
			result = false;		/* they aren't equal */
			break;
		}
	}

	MemoryContextSwitchTo(oldContext);

	return result;
}

/*
 * execTuplesUnequal
 *		Return true if two tuples are definitely unequal in the indicated
 *		fields.
 *
 * Nulls are neither equal nor unequal to anything else.  A true result
 * is obtained only if there are non-null fields that compare not-equal.
 *
 * Parameters are identical to execTuplesMatch.
 */
bool
execTuplesUnequal(TupleTableSlot *slot1,
				  TupleTableSlot *slot2,
				  int numCols,
				  AttrNumber *matchColIdx,
				  FmgrInfo *eqfunctions,
				  MemoryContext evalContext)
{
	MemoryContext oldContext;
	bool		result;
	int			i;

	/* Reset and switch into the temp context. */
	MemoryContextReset(evalContext);
	oldContext = MemoryContextSwitchTo(evalContext);

	/*
	 * We cannot report a match without checking all the fields, but we can
	 * report a non-match as soon as we find unequal fields.  So, start
	 * comparing at the last field (least significant sort key). That's the
	 * most likely to be different if we are dealing with sorted input.
	 */
	result = false;

	for (i = numCols; --i >= 0;)
	{
		AttrNumber	att = matchColIdx[i];
		Datum		attr1,
					attr2;
		bool		isNull1,
					isNull2;

		attr1 = slot_getattr(slot1, att, &isNull1);

		if (isNull1)
			continue;			/* can't prove anything here */

		attr2 = slot_getattr(slot2, att, &isNull2);

		if (isNull2)
			continue;			/* can't prove anything here */

		/* Apply the type-specific equality function */

		if (!DatumGetBool(FunctionCall2(&eqfunctions[i],
										attr1, attr2)))
		{
			result = true;		/* they are unequal */
			break;
		}
	}

	MemoryContextSwitchTo(oldContext);

	return result;
}


/*
 * execTuplesMatchPrepare
 *		Look up the equality functions needed for execTuplesMatch or
 *		execTuplesUnequal, given an array of equality operator OIDs.
 *
 * The result is a palloc'd array.
 */
FmgrInfo *
execTuplesMatchPrepare(int numCols,
					   Oid *eqOperators)
{
	FmgrInfo   *eqFunctions = (FmgrInfo *) palloc(numCols * sizeof(FmgrInfo));
	int			i;

	for (i = 0; i < numCols; i++)
	{
		Oid			eq_opr = eqOperators[i];
		Oid			eq_function;

		eq_function = get_opcode(eq_opr);
		fmgr_info(eq_function, &eqFunctions[i]);
	}

	return eqFunctions;
}

/*
 * execTuplesHashPrepare
 *		Look up the equality and hashing functions needed for a TupleHashTable.
 *
 * This is similar to execTuplesMatchPrepare, but we also need to find the
 * hash functions associated with the equality operators.  *eqFunctions and
 * *hashFunctions receive the palloc'd result arrays.
 *
 * Note: we expect that the given operators are not cross-type comparisons.
 */
void
execTuplesHashPrepare(int numCols,
					  Oid *eqOperators,
					  FmgrInfo **eqFunctions,
					  FmgrInfo **hashFunctions)
{
	int			i;

	*eqFunctions = (FmgrInfo *) palloc(numCols * sizeof(FmgrInfo));
	*hashFunctions = (FmgrInfo *) palloc(numCols * sizeof(FmgrInfo));

	for (i = 0; i < numCols; i++)
	{
		Oid			eq_opr = eqOperators[i];
		Oid			eq_function;
		Oid			left_hash_function;
		Oid			right_hash_function;

		eq_function = get_opcode(eq_opr);
		if (!get_op_hash_functions(eq_opr,
								   &left_hash_function, &right_hash_function))
			elog(ERROR, "could not find hash function for hash operator %u",
				 eq_opr);
		/* We're not supporting cross-type cases here */
		Assert(left_hash_function == right_hash_function);
		fmgr_info(eq_function, &(*eqFunctions)[i]);
		fmgr_info(right_hash_function, &(*hashFunctions)[i]);
	}
}


/*****************************************************************************
 *		Utility routines for all-in-memory hash tables
 *
 * These routines build hash tables for grouping tuples together (eg, for
 * hash aggregation).  There is one entry for each not-distinct set of tuples
 * presented.
 *****************************************************************************/

/*
 * Construct an empty TupleHashTable
 *
 *	numCols, keyColIdx: identify the tuple fields to use as lookup key
 *	eqfunctions: equality comparison functions to use
 *	hashfunctions: datatype-specific hashing functions to use
 *	nbuckets: initial estimate of hashtable size
 *	additionalsize: size of data stored in ->additional
 *	tablecxt: memory context in which to store table and table entries
 *	tempcxt: short-lived context for evaluation hash and comparison functions
 *
 * The function arrays may be made with execTuplesHashPrepare().  Note they
 * are not cross-type functions, but expect to see the table datatype(s)
 * on both sides.
 *
 * Note that keyColIdx, eqfunctions, and hashfunctions must be allocated in
 * storage that will live as long as the hashtable does.
 */
TupleHashTable
BuildTupleHashTable(int numCols, AttrNumber *keyColIdx,
					FmgrInfo *eqfunctions,
					FmgrInfo *hashfunctions,
					long nbuckets, Size additionalsize,
					MemoryContext tablecxt, MemoryContext tempcxt,
					bool use_variable_hash_iv)
{
	TupleHashTable hashtable;
	Size		entrysize = sizeof(TupleHashEntryData) + additionalsize;

	Assert(nbuckets > 0);

	/* Limit initial table size request to not more than work_mem */
	nbuckets = Min(nbuckets, (long) ((work_mem * 1024L) / entrysize));

	hashtable = (TupleHashTable)
		MemoryContextAlloc(tablecxt, sizeof(TupleHashTableData));

	hashtable->numCols = numCols;
	hashtable->keyColIdx = keyColIdx;
	hashtable->tab_hash_funcs = hashfunctions;
	hashtable->tab_eq_funcs = eqfunctions;
	hashtable->tablecxt = tablecxt;
	hashtable->tempcxt = tempcxt;
	hashtable->entrysize = entrysize;
	hashtable->tableslot = NULL;	/* will be made on first lookup */
	hashtable->inputslot = NULL;
	hashtable->in_hash_funcs = NULL;
	hashtable->cur_eq_funcs = NULL;

	/*
	 * If parallelism is in use, even if the master backend is performing the
	 * scan itself, we don't want to create the hashtable exactly the same way
	 * in all workers. As hashtables are iterated over in keyspace-order,
	 * doing so in all processes in the same way is likely to lead to
	 * "unbalanced" hashtables when the table size initially is
	 * underestimated.
	 */
	if (use_variable_hash_iv)
		hashtable->hash_iv = hash_uint32(ParallelWorkerNumber);
	else
		hashtable->hash_iv = 0;

	hashtable->hashtab = tuplehash_create(tablecxt, nbuckets, hashtable);

	return hashtable;
}

/*
 * Find or create a hashtable entry for the tuple group containing the
 * given tuple.  The tuple must be the same type as the hashtable entries.
 *
 * If isnew is NULL, we do not create new entries; we return NULL if no
 * match is found.
 *
 * If isnew isn't NULL, then a new entry is created if no existing entry
 * matches.  On return, *isnew is true if the entry is newly created,
 * false if it existed already.  ->additional_data in the new entry has
 * been zeroed.
 */
TupleHashEntry
LookupTupleHashEntry(TupleHashTable hashtable, TupleTableSlot *slot,
					 bool *isnew)
{
	TupleHashEntryData *entry;
	MemoryContext oldContext;
	bool		found;
	MinimalTuple key;

	/* If first time through, clone the input slot to make table slot */
	if (hashtable->tableslot == NULL)
	{
		TupleDesc	tupdesc;

		oldContext = MemoryContextSwitchTo(hashtable->tablecxt);

		/*
		 * We copy the input tuple descriptor just for safety --- we assume
		 * all input tuples will have equivalent descriptors.
		 */
		tupdesc = CreateTupleDescCopy(slot->tts_tupleDescriptor);
		hashtable->tableslot = MakeSingleTupleTableSlot(tupdesc);
		MemoryContextSwitchTo(oldContext);
	}

	/* Need to run the hash functions in short-lived context */
	oldContext = MemoryContextSwitchTo(hashtable->tempcxt);

	/* set up data needed by hash and match functions */
	hashtable->inputslot = slot;
	hashtable->in_hash_funcs = hashtable->tab_hash_funcs;
	hashtable->cur_eq_funcs = hashtable->tab_eq_funcs;

	key = NULL;					/* flag to reference inputslot */

	if (isnew)
	{
		entry = tuplehash_insert(hashtable->hashtab, key, &found);

		if (found)
		{
			/* found pre-existing entry */
			*isnew = false;
		}
		else
		{
			/* created new entry */
			*isnew = true;
			/* zero caller data */
			entry->additional = NULL;
			MemoryContextSwitchTo(hashtable->tablecxt);
			/* Copy the first tuple into the table context */
			entry->firstTuple = ExecCopySlotMinimalTuple(slot);
		}
	}
	else
	{
		entry = tuplehash_lookup(hashtable->hashtab, key);
	}

	MemoryContextSwitchTo(oldContext);

	return entry;
}

/*
 * Search for a hashtable entry matching the given tuple.  No entry is
 * created if there's not a match.  This is similar to the non-creating
 * case of LookupTupleHashEntry, except that it supports cross-type
 * comparisons, in which the given tuple is not of the same type as the
 * table entries.  The caller must provide the hash functions to use for
 * the input tuple, as well as the equality functions, since these may be
 * different from the table's internal functions.
 */
TupleHashEntry
FindTupleHashEntry(TupleHashTable hashtable, TupleTableSlot *slot,
				   FmgrInfo *eqfunctions,
				   FmgrInfo *hashfunctions)
{
	TupleHashEntry entry;
	MemoryContext oldContext;
	MinimalTuple key;

	/* Need to run the hash functions in short-lived context */
	oldContext = MemoryContextSwitchTo(hashtable->tempcxt);

	/* Set up data needed by hash and match functions */
	hashtable->inputslot = slot;
	hashtable->in_hash_funcs = hashfunctions;
	hashtable->cur_eq_funcs = eqfunctions;

	/* Search the hash table */
	key = NULL;					/* flag to reference inputslot */
	entry = tuplehash_lookup(hashtable->hashtab, key);
	MemoryContextSwitchTo(oldContext);

	return entry;
}

/*
 * Compute the hash value for a tuple
 *
 * The passed-in key is a pointer to TupleHashEntryData.  In an actual hash
 * table entry, the firstTuple field points to a tuple (in MinimalTuple
 * format).  LookupTupleHashEntry sets up a dummy TupleHashEntryData with a
 * NULL firstTuple field --- that cues us to look at the inputslot instead.
 * This convention avoids the need to materialize virtual input tuples unless
 * they actually need to get copied into the table.
 *
 * Also, the caller must select an appropriate memory context for running
 * the hash functions. (dynahash.c doesn't change CurrentMemoryContext.)
 */
static uint32
TupleHashTableHash(struct tuplehash_hash *tb, const MinimalTuple tuple)
{
	TupleHashTable hashtable = (TupleHashTable) tb->private_data;
	int			numCols = hashtable->numCols;
	AttrNumber *keyColIdx = hashtable->keyColIdx;
	uint32		hashkey = hashtable->hash_iv;
	TupleTableSlot *slot;
	FmgrInfo   *hashfunctions;
	int			i;

	if (tuple == NULL)
	{
		/* Process the current input tuple for the table */
		slot = hashtable->inputslot;
		hashfunctions = hashtable->in_hash_funcs;
	}
	else
	{
		/*
		 * Process a tuple already stored in the table.
		 *
		 * (this case never actually occurs due to the way simplehash.h is
		 * used, as the hash-value is stored in the entries)
		 */
		slot = hashtable->tableslot;
		ExecStoreMinimalTuple(tuple, slot, false);
		hashfunctions = hashtable->tab_hash_funcs;
	}

	for (i = 0; i < numCols; i++)
	{
		AttrNumber	att = keyColIdx[i];
		Datum		attr;
		bool		isNull;

		/* rotate hashkey left 1 bit at each step */
		hashkey = (hashkey << 1) | ((hashkey & 0x80000000) ? 1 : 0);

		attr = slot_getattr(slot, att, &isNull);

		if (!isNull)			/* treat nulls as having hash key 0 */
		{
			uint32		hkey;

			hkey = DatumGetUInt32(FunctionCall1(&hashfunctions[i],
												attr));
			hashkey ^= hkey;
		}
	}

	return hashkey;
}

/*
 * See whether two tuples (presumably of the same hash value) match
 *
 * As above, the passed pointers are pointers to TupleHashEntryData.
 *
 * Also, the caller must select an appropriate memory context for running
 * the compare functions.  (dynahash.c doesn't change CurrentMemoryContext.)
 */
static int
TupleHashTableMatch(struct tuplehash_hash *tb, const MinimalTuple tuple1, const MinimalTuple tuple2)
{
	TupleTableSlot *slot1;
	TupleTableSlot *slot2;
	TupleHashTable hashtable = (TupleHashTable) tb->private_data;

	/*
	 * We assume that simplehash.h will only ever call us with the first
	 * argument being an actual table entry, and the second argument being
	 * LookupTupleHashEntry's dummy TupleHashEntryData.  The other direction
	 * could be supported too, but is not currently required.
	 */
	Assert(tuple1 != NULL);
	slot1 = hashtable->tableslot;
	ExecStoreMinimalTuple(tuple1, slot1, false);
	Assert(tuple2 == NULL);
	slot2 = hashtable->inputslot;

	/* For crosstype comparisons, the inputslot must be first */
	if (execTuplesMatch(slot2,
						slot1,
						hashtable->numCols,
						hashtable->keyColIdx,
						hashtable->cur_eq_funcs,
						hashtable->tempcxt))
		return 0;
	else
		return 1;
}