postgresql/src/backend/catalog/partition.c

/*-------------------------------------------------------------------------
 *
 * partition.c
 *		  Partitioning related data structures and functions.
 *
 * Portions Copyright (c) 1996-2017, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *		  src/backend/catalog/partition.c
 *
 *-------------------------------------------------------------------------
*/

#include "postgres.h"

#include "access/heapam.h"
#include "access/htup_details.h"
#include "access/nbtree.h"
#include "access/sysattr.h"
#include "catalog/dependency.h"
#include "catalog/indexing.h"
#include "catalog/objectaddress.h"
#include "catalog/partition.h"
#include "catalog/pg_collation.h"
#include "catalog/pg_inherits.h"
#include "catalog/pg_inherits_fn.h"
#include "catalog/pg_opclass.h"
#include "catalog/pg_type.h"
#include "executor/executor.h"
#include "miscadmin.h"
#include "nodes/makefuncs.h"
#include "nodes/nodeFuncs.h"
#include "nodes/parsenodes.h"
#include "optimizer/clauses.h"
#include "optimizer/planmain.h"
#include "optimizer/var.h"
#include "rewrite/rewriteManip.h"
#include "storage/lmgr.h"
#include "utils/array.h"
#include "utils/builtins.h"
#include "utils/datum.h"
#include "utils/memutils.h"
#include "utils/fmgroids.h"
#include "utils/inval.h"
#include "utils/lsyscache.h"
#include "utils/rel.h"
#include "utils/ruleutils.h"
#include "utils/syscache.h"

/*
 * Information about bounds of a partitioned relation
 *
 * A list partition datum that is known to be NULL is never put into the
 * datums array. Instead, it is tracked using the null_index field.
 *
 * In the case of range partitioning, ndatums will typically be far less than
 * 2 * nparts, because a partition's upper bound and the next partition's lower
 * bound are the same in most common cases, and we only store one of them (the
 * upper bound).
 *
 * In the case of list partitioning, the indexes array stores one entry for
 * every datum, which is the index of the partition that accepts a given datum.
 * In case of range partitioning, it stores one entry per distinct range
 * datum, which is the index of the partition for which a given datum
 * is an upper bound.
 */

typedef struct PartitionBoundInfoData
{
	char		strategy;		/* list or range bounds? */
	int			ndatums;		/* Length of the datums following array */
	Datum	  **datums;			/* Array of datum-tuples with key->partnatts
								 * datums each */
	PartitionRangeDatumKind **kind; /* The kind of each range bound datum;
									 * NULL for list partitioned tables */
	int		   *indexes;		/* Partition indexes; one entry per member of
								 * the datums array (plus one if range
								 * partitioned table) */
	int			null_index;		/* Index of the null-accepting partition; -1
								 * if there isn't one */
} PartitionBoundInfoData;

#define partition_bound_accepts_nulls(bi) ((bi)->null_index != -1)

/*
 * When qsort'ing partition bounds after reading from the catalog, each bound
 * is represented with one of the following structs.
 */

/* One value coming from some (index'th) list partition */
typedef struct PartitionListValue
{
	int			index;
	Datum		value;
} PartitionListValue;

/* One bound of a range partition */
typedef struct PartitionRangeBound
{
	int			index;
	Datum	   *datums;			/* range bound datums */
	PartitionRangeDatumKind *kind;	/* the kind of each datum */
	bool		lower;			/* this is the lower (vs upper) bound */
} PartitionRangeBound;

static int32 qsort_partition_list_value_cmp(const void *a, const void *b,
							   void *arg);
static int32 qsort_partition_rbound_cmp(const void *a, const void *b,
						   void *arg);

static Oid get_partition_operator(PartitionKey key, int col,
					   StrategyNumber strategy, bool *need_relabel);
static Expr *make_partition_op_expr(PartitionKey key, int keynum,
					   uint16 strategy, Expr *arg1, Expr *arg2);
static void get_range_key_properties(PartitionKey key, int keynum,
						 PartitionRangeDatum *ldatum,
						 PartitionRangeDatum *udatum,
						 ListCell **partexprs_item,
						 Expr **keyCol,
						 Const **lower_val, Const **upper_val);
static List *get_qual_for_list(PartitionKey key, PartitionBoundSpec *spec);
static List *get_qual_for_range(PartitionKey key, PartitionBoundSpec *spec);
static List *generate_partition_qual(Relation rel);

static PartitionRangeBound *make_one_range_bound(PartitionKey key, int index,
					 List *datums, bool lower);
static int32 partition_rbound_cmp(PartitionKey key,
					 Datum *datums1, PartitionRangeDatumKind *kind1,
					 bool lower1, PartitionRangeBound *b2);
static int32 partition_rbound_datum_cmp(PartitionKey key,
						   Datum *rb_datums, PartitionRangeDatumKind *rb_kind,
						   Datum *tuple_datums);

static int32 partition_bound_cmp(PartitionKey key,
					PartitionBoundInfo boundinfo,
					int offset, void *probe, bool probe_is_bound);
static int partition_bound_bsearch(PartitionKey key,
						PartitionBoundInfo boundinfo,
						void *probe, bool probe_is_bound, bool *is_equal);

/*
 * RelationBuildPartitionDesc
 *		Form rel's partition descriptor
 *
 * Not flushed from the cache by RelationClearRelation() unless changed because
 * of addition or removal of partition.
 */
void
RelationBuildPartitionDesc(Relation rel)
{
	List	   *inhoids,
			   *partoids;
	Oid		   *oids = NULL;
	List	   *boundspecs = NIL;
	ListCell   *cell;
	int			i,
				nparts;
	PartitionKey key = RelationGetPartitionKey(rel);
	PartitionDesc result;
	MemoryContext oldcxt;

	int			ndatums = 0;

	/* List partitioning specific */
	PartitionListValue **all_values = NULL;
	int			null_index = -1;

	/* Range partitioning specific */
	PartitionRangeBound **rbounds = NULL;

	/*
	 * The following could happen in situations where rel has a pg_class entry
	 * but not the pg_partitioned_table entry yet.
	 */
	if (key == NULL)
		return;

	/* Get partition oids from pg_inherits */
	inhoids = find_inheritance_children(RelationGetRelid(rel), NoLock);

	/* Collect bound spec nodes in a list */
	i = 0;
	partoids = NIL;
	foreach(cell, inhoids)
	{
		Oid			inhrelid = lfirst_oid(cell);
		HeapTuple	tuple;
		Datum		datum;
		bool		isnull;
		Node	   *boundspec;

		tuple = SearchSysCache1(RELOID, inhrelid);
		if (!HeapTupleIsValid(tuple))
			elog(ERROR, "cache lookup failed for relation %u", inhrelid);

		/*
		 * It is possible that the pg_class tuple of a partition has not been
		 * updated yet to set its relpartbound field.  The only case where
		 * this happens is when we open the parent relation to check using its
		 * partition descriptor that a new partition's bound does not overlap
		 * some existing partition.
		 */
		if (!((Form_pg_class) GETSTRUCT(tuple))->relispartition)
		{
			ReleaseSysCache(tuple);
			continue;
		}

		datum = SysCacheGetAttr(RELOID, tuple,
								Anum_pg_class_relpartbound,
								&isnull);
		Assert(!isnull);
		boundspec = (Node *) stringToNode(TextDatumGetCString(datum));
		boundspecs = lappend(boundspecs, boundspec);
		partoids = lappend_oid(partoids, inhrelid);
		ReleaseSysCache(tuple);
	}

	nparts = list_length(partoids);

	if (nparts > 0)
	{
		oids = (Oid *) palloc(nparts * sizeof(Oid));
		i = 0;
		foreach(cell, partoids)
			oids[i++] = lfirst_oid(cell);

		/* Convert from node to the internal representation */
		if (key->strategy == PARTITION_STRATEGY_LIST)
		{
			List	   *non_null_values = NIL;

			/*
			 * Create a unified list of non-null values across all partitions.
			 */
			i = 0;
			null_index = -1;
			foreach(cell, boundspecs)
			{
				PartitionBoundSpec *spec = castNode(PartitionBoundSpec,
													lfirst(cell));
				ListCell   *c;

				if (spec->strategy != PARTITION_STRATEGY_LIST)
					elog(ERROR, "invalid strategy in partition bound spec");

				foreach(c, spec->listdatums)
				{
					Const	   *val = castNode(Const, lfirst(c));
					PartitionListValue *list_value = NULL;

					if (!val->constisnull)
					{
						list_value = (PartitionListValue *)
							palloc0(sizeof(PartitionListValue));
						list_value->index = i;
						list_value->value = val->constvalue;
					}
					else
					{
						/*
						 * Never put a null into the values array, flag
						 * instead for the code further down below where we
						 * construct the actual relcache struct.
						 */
						if (null_index != -1)
							elog(ERROR, "found null more than once");
						null_index = i;
					}

					if (list_value)
						non_null_values = lappend(non_null_values,
												  list_value);
				}

				i++;
			}

			ndatums = list_length(non_null_values);

			/*
			 * Collect all list values in one array. Alongside the value, we
			 * also save the index of partition the value comes from.
			 */
			all_values = (PartitionListValue **) palloc(ndatums *
														sizeof(PartitionListValue *));
			i = 0;
			foreach(cell, non_null_values)
			{
				PartitionListValue *src = lfirst(cell);

				all_values[i] = (PartitionListValue *)
					palloc(sizeof(PartitionListValue));
				all_values[i]->value = src->value;
				all_values[i]->index = src->index;
				i++;
			}

			qsort_arg(all_values, ndatums, sizeof(PartitionListValue *),
					  qsort_partition_list_value_cmp, (void *) key);
		}
		else if (key->strategy == PARTITION_STRATEGY_RANGE)
		{
			int			k;
			PartitionRangeBound **all_bounds,
					   *prev;

			all_bounds = (PartitionRangeBound **) palloc0(2 * nparts *
														  sizeof(PartitionRangeBound *));

			/*
			 * Create a unified list of range bounds across all the
			 * partitions.
			 */
			i = ndatums = 0;
			foreach(cell, boundspecs)
			{
				PartitionBoundSpec *spec = castNode(PartitionBoundSpec,
													lfirst(cell));
				PartitionRangeBound *lower,
						   *upper;

				if (spec->strategy != PARTITION_STRATEGY_RANGE)
					elog(ERROR, "invalid strategy in partition bound spec");

				lower = make_one_range_bound(key, i, spec->lowerdatums,
											 true);
				upper = make_one_range_bound(key, i, spec->upperdatums,
											 false);
				all_bounds[ndatums++] = lower;
				all_bounds[ndatums++] = upper;
				i++;
			}

			Assert(ndatums == nparts * 2);

			/* Sort all the bounds in ascending order */
			qsort_arg(all_bounds, 2 * nparts,
					  sizeof(PartitionRangeBound *),
					  qsort_partition_rbound_cmp,
					  (void *) key);

			/* Save distinct bounds from all_bounds into rbounds. */
			rbounds = (PartitionRangeBound **)
				palloc(ndatums * sizeof(PartitionRangeBound *));
			k = 0;
			prev = NULL;
			for (i = 0; i < ndatums; i++)
			{
				PartitionRangeBound *cur = all_bounds[i];
				bool		is_distinct = false;
				int			j;

				/* Is the current bound distinct from the previous one? */
				for (j = 0; j < key->partnatts; j++)
				{
					Datum		cmpval;

					if (prev == NULL || cur->kind[j] != prev->kind[j])
					{
						is_distinct = true;
						break;
					}

					/*
					 * If the bounds are both MINVALUE or MAXVALUE, stop now
					 * and treat them as equal, since any values after this
					 * point must be ignored.
					 */
					if (cur->kind[j] != PARTITION_RANGE_DATUM_VALUE)
						break;

					cmpval = FunctionCall2Coll(&key->partsupfunc[j],
											   key->partcollation[j],
											   cur->datums[j],
											   prev->datums[j]);
					if (DatumGetInt32(cmpval) != 0)
					{
						is_distinct = true;
						break;
					}
				}

				/*
				 * Only if the bound is distinct save it into a temporary
				 * array i.e. rbounds which is later copied into boundinfo
				 * datums array.
				 */
				if (is_distinct)
					rbounds[k++] = all_bounds[i];

				prev = cur;
			}

			/* Update ndatums to hold the count of distinct datums. */
			ndatums = k;
		}
		else
			elog(ERROR, "unexpected partition strategy: %d",
				 (int) key->strategy);
	}

	/* Now build the actual relcache partition descriptor */
	rel->rd_pdcxt = AllocSetContextCreate(CacheMemoryContext,
										  RelationGetRelationName(rel),
										  ALLOCSET_DEFAULT_SIZES);
	oldcxt = MemoryContextSwitchTo(rel->rd_pdcxt);

	result = (PartitionDescData *) palloc0(sizeof(PartitionDescData));
	result->nparts = nparts;
	if (nparts > 0)
	{
		PartitionBoundInfo boundinfo;
		int		   *mapping;
		int			next_index = 0;

		result->oids = (Oid *) palloc0(nparts * sizeof(Oid));

		boundinfo = (PartitionBoundInfoData *)
			palloc0(sizeof(PartitionBoundInfoData));
		boundinfo->strategy = key->strategy;
		boundinfo->ndatums = ndatums;
		boundinfo->null_index = -1;
		boundinfo->datums = (Datum **) palloc0(ndatums * sizeof(Datum *));

		/* Initialize mapping array with invalid values */
		mapping = (int *) palloc(sizeof(int) * nparts);
		for (i = 0; i < nparts; i++)
			mapping[i] = -1;

		switch (key->strategy)
		{
			case PARTITION_STRATEGY_LIST:
				{
					boundinfo->indexes = (int *) palloc(ndatums * sizeof(int));

					/*
					 * Copy values.  Indexes of individual values are mapped
					 * to canonical values so that they match for any two list
					 * partitioned tables with same number of partitions and
					 * same lists per partition.  One way to canonicalize is
					 * to assign the index in all_values[] of the smallest
					 * value of each partition, as the index of all of the
					 * partition's values.
					 */
					for (i = 0; i < ndatums; i++)
					{
						boundinfo->datums[i] = (Datum *) palloc(sizeof(Datum));
						boundinfo->datums[i][0] = datumCopy(all_values[i]->value,
															key->parttypbyval[0],
															key->parttyplen[0]);

						/* If the old index has no mapping, assign one */
						if (mapping[all_values[i]->index] == -1)
							mapping[all_values[i]->index] = next_index++;

						boundinfo->indexes[i] = mapping[all_values[i]->index];
					}

					/*
					 * If null-accepting partition has no mapped index yet,
					 * assign one.  This could happen if such partition
					 * accepts only null and hence not covered in the above
					 * loop which only handled non-null values.
					 */
					if (null_index != -1)
					{
						Assert(null_index >= 0);
						if (mapping[null_index] == -1)
							mapping[null_index] = next_index++;
						boundinfo->null_index = mapping[null_index];
					}

					/* All partition must now have a valid mapping */
					Assert(next_index == nparts);
					break;
				}

			case PARTITION_STRATEGY_RANGE:
				{
					boundinfo->kind = (PartitionRangeDatumKind **)
						palloc(ndatums *
							   sizeof(PartitionRangeDatumKind *));
					boundinfo->indexes = (int *) palloc((ndatums + 1) *
														sizeof(int));

					for (i = 0; i < ndatums; i++)
					{
						int			j;

						boundinfo->datums[i] = (Datum *) palloc(key->partnatts *
																sizeof(Datum));
						boundinfo->kind[i] = (PartitionRangeDatumKind *)
							palloc(key->partnatts *
								   sizeof(PartitionRangeDatumKind));
						for (j = 0; j < key->partnatts; j++)
						{
							if (rbounds[i]->kind[j] == PARTITION_RANGE_DATUM_VALUE)
								boundinfo->datums[i][j] =
									datumCopy(rbounds[i]->datums[j],
											  key->parttypbyval[j],
											  key->parttyplen[j]);
							boundinfo->kind[i][j] = rbounds[i]->kind[j];
						}

						/*
						 * There is no mapping for invalid indexes.
						 *
						 * Any lower bounds in the rbounds array have invalid
						 * indexes assigned, because the values between the
						 * previous bound (if there is one) and this (lower)
						 * bound are not part of the range of any existing
						 * partition.
						 */
						if (rbounds[i]->lower)
							boundinfo->indexes[i] = -1;
						else
						{
							int			orig_index = rbounds[i]->index;

							/* If the old index has no mapping, assign one */
							if (mapping[orig_index] == -1)
								mapping[orig_index] = next_index++;

							boundinfo->indexes[i] = mapping[orig_index];
						}
					}
					boundinfo->indexes[i] = -1;
					break;
				}

			default:
				elog(ERROR, "unexpected partition strategy: %d",
					 (int) key->strategy);
		}

		result->boundinfo = boundinfo;

		/*
		 * Now assign OIDs from the original array into mapped indexes of the
		 * result array.  Order of OIDs in the former is defined by the
		 * catalog scan that retrieved them, whereas that in the latter is
		 * defined by canonicalized representation of the list values or the
		 * range bounds.
		 */
		for (i = 0; i < nparts; i++)
			result->oids[mapping[i]] = oids[i];
		pfree(mapping);
	}

	MemoryContextSwitchTo(oldcxt);
	rel->rd_partdesc = result;
}

/*
 * Are two partition bound collections logically equal?
 *
 * Used in the keep logic of relcache.c (ie, in RelationClearRelation()).
 * This is also useful when b1 and b2 are bound collections of two separate
 * relations, respectively, because PartitionBoundInfo is a canonical
 * representation of partition bounds.
 */
bool
partition_bounds_equal(int partnatts, int16 *parttyplen, bool *parttypbyval,
					   PartitionBoundInfo b1, PartitionBoundInfo b2)
{
	int			i;

	if (b1->strategy != b2->strategy)
		return false;

	if (b1->ndatums != b2->ndatums)
		return false;

	if (b1->null_index != b2->null_index)
		return false;

	for (i = 0; i < b1->ndatums; i++)
	{
		int			j;

		for (j = 0; j < partnatts; j++)
		{
			/* For range partitions, the bounds might not be finite. */
			if (b1->kind != NULL)
			{
				/* The different kinds of bound all differ from each other */
				if (b1->kind[i][j] != b2->kind[i][j])
					return false;

				/* Non-finite bounds are equal without further examination. */
				if (b1->kind[i][j] != PARTITION_RANGE_DATUM_VALUE)
					continue;
			}

			/*
			 * Compare the actual values. Note that it would be both incorrect
			 * and unsafe to invoke the comparison operator derived from the
			 * partitioning specification here.  It would be incorrect because
			 * we want the relcache entry to be updated for ANY change to the
			 * partition bounds, not just those that the partitioning operator
			 * thinks are significant.  It would be unsafe because we might
			 * reach this code in the context of an aborted transaction, and
			 * an arbitrary partitioning operator might not be safe in that
			 * context.  datumIsEqual() should be simple enough to be safe.
			 */
			if (!datumIsEqual(b1->datums[i][j], b2->datums[i][j],
							  parttypbyval[j], parttyplen[j]))
				return false;
		}

		if (b1->indexes[i] != b2->indexes[i])
			return false;
	}

	/* There are ndatums+1 indexes in case of range partitions */
	if (b1->strategy == PARTITION_STRATEGY_RANGE &&
		b1->indexes[i] != b2->indexes[i])
		return false;

	return true;
}

/*
 * check_new_partition_bound
 *
 * Checks if the new partition's bound overlaps any of the existing partitions
 * of parent.  Also performs additional checks as necessary per strategy.
 */
void
check_new_partition_bound(char *relname, Relation parent,
						  PartitionBoundSpec *spec)
{
	PartitionKey key = RelationGetPartitionKey(parent);
	PartitionDesc partdesc = RelationGetPartitionDesc(parent);
	ParseState *pstate = make_parsestate(NULL);
	int			with = -1;
	bool		overlap = false;

	switch (key->strategy)
	{
		case PARTITION_STRATEGY_LIST:
			{
				Assert(spec->strategy == PARTITION_STRATEGY_LIST);

				if (partdesc->nparts > 0)
				{
					PartitionBoundInfo boundinfo = partdesc->boundinfo;
					ListCell   *cell;

					Assert(boundinfo &&
						   boundinfo->strategy == PARTITION_STRATEGY_LIST &&
						   (boundinfo->ndatums > 0 ||
							partition_bound_accepts_nulls(boundinfo)));

					foreach(cell, spec->listdatums)
					{
						Const	   *val = castNode(Const, lfirst(cell));

						if (!val->constisnull)
						{
							int			offset;
							bool		equal;

							offset = partition_bound_bsearch(key, boundinfo,
															 &val->constvalue,
															 true, &equal);
							if (offset >= 0 && equal)
							{
								overlap = true;
								with = boundinfo->indexes[offset];
								break;
							}
						}
						else if (partition_bound_accepts_nulls(boundinfo))
						{
							overlap = true;
							with = boundinfo->null_index;
							break;
						}
					}
				}

				break;
			}

		case PARTITION_STRATEGY_RANGE:
			{
				PartitionRangeBound *lower,
						   *upper;

				Assert(spec->strategy == PARTITION_STRATEGY_RANGE);
				lower = make_one_range_bound(key, -1, spec->lowerdatums, true);
				upper = make_one_range_bound(key, -1, spec->upperdatums, false);

				/*
				 * First check if the resulting range would be empty with
				 * specified lower and upper bounds
				 */
				if (partition_rbound_cmp(key, lower->datums, lower->kind, true,
										 upper) >= 0)
				{
					ereport(ERROR,
							(errcode(ERRCODE_INVALID_OBJECT_DEFINITION),
							 errmsg("empty range bound specified for partition \"%s\"",
									relname),
							 errdetail("Specified lower bound %s is greater than or equal to upper bound %s.",
									   get_range_partbound_string(spec->lowerdatums),
									   get_range_partbound_string(spec->upperdatums)),
							 parser_errposition(pstate, spec->location)));
				}

				if (partdesc->nparts > 0)
				{
					PartitionBoundInfo boundinfo = partdesc->boundinfo;
					int			offset;
					bool		equal;

					Assert(boundinfo && boundinfo->ndatums > 0 &&
						   boundinfo->strategy == PARTITION_STRATEGY_RANGE);

					/*
					 * Test whether the new lower bound (which is treated
					 * inclusively as part of the new partition) lies inside
					 * an existing partition, or in a gap.
					 *
					 * If it's inside an existing partition, the bound at
					 * offset + 1 will be the upper bound of that partition,
					 * and its index will be >= 0.
					 *
					 * If it's in a gap, the bound at offset + 1 will be the
					 * lower bound of the next partition, and its index will
					 * be -1. This is also true if there is no next partition,
					 * since the index array is initialised with an extra -1
					 * at the end.
					 */
					offset = partition_bound_bsearch(key, boundinfo, lower,
													 true, &equal);

					if (boundinfo->indexes[offset + 1] < 0)
					{
						/*
						 * Check that the new partition will fit in the gap.
						 * For it to fit, the new upper bound must be less
						 * than or equal to the lower bound of the next
						 * partition, if there is one.
						 */
						if (offset + 1 < boundinfo->ndatums)
						{
							int32		cmpval;

							cmpval = partition_bound_cmp(key, boundinfo,
														 offset + 1, upper,
														 true);
							if (cmpval < 0)
							{
								/*
								 * The new partition overlaps with the
								 * existing partition between offset + 1 and
								 * offset + 2.
								 */
								overlap = true;
								with = boundinfo->indexes[offset + 2];
							}
						}
					}
					else
					{
						/*
						 * The new partition overlaps with the existing
						 * partition between offset and offset + 1.
						 */
						overlap = true;
						with = boundinfo->indexes[offset + 1];
					}
				}

				break;
			}

		default:
			elog(ERROR, "unexpected partition strategy: %d",
				 (int) key->strategy);
	}

	if (overlap)
	{
		Assert(with >= 0);
		ereport(ERROR,
				(errcode(ERRCODE_INVALID_OBJECT_DEFINITION),
				 errmsg("partition \"%s\" would overlap partition \"%s\"",
						relname, get_rel_name(partdesc->oids[with])),
				 parser_errposition(pstate, spec->location)));
	}
}

/*
 * get_partition_parent
 *
 * Returns inheritance parent of a partition by scanning pg_inherits
 *
 * Note: Because this function assumes that the relation whose OID is passed
 * as an argument will have precisely one parent, it should only be called
 * when it is known that the relation is a partition.
 */
Oid
get_partition_parent(Oid relid)
{
	Form_pg_inherits form;
	Relation	catalogRelation;
	SysScanDesc scan;
	ScanKeyData key[2];
	HeapTuple	tuple;
	Oid			result;

	catalogRelation = heap_open(InheritsRelationId, AccessShareLock);

	ScanKeyInit(&key[0],
				Anum_pg_inherits_inhrelid,
				BTEqualStrategyNumber, F_OIDEQ,
				ObjectIdGetDatum(relid));
	ScanKeyInit(&key[1],
				Anum_pg_inherits_inhseqno,
				BTEqualStrategyNumber, F_INT4EQ,
				Int32GetDatum(1));

	scan = systable_beginscan(catalogRelation, InheritsRelidSeqnoIndexId, true,
							  NULL, 2, key);

	tuple = systable_getnext(scan);
	if (!HeapTupleIsValid(tuple))
		elog(ERROR, "could not find tuple for parent of relation %u", relid);

	form = (Form_pg_inherits) GETSTRUCT(tuple);
	result = form->inhparent;

	systable_endscan(scan);
	heap_close(catalogRelation, AccessShareLock);

	return result;
}

/*
 * get_qual_from_partbound
 *		Given a parser node for partition bound, return the list of executable
 *		expressions as partition constraint
 */
List *
get_qual_from_partbound(Relation rel, Relation parent,
						PartitionBoundSpec *spec)
{
	PartitionKey key = RelationGetPartitionKey(parent);
	List	   *my_qual = NIL;

	Assert(key != NULL);

	switch (key->strategy)
	{
		case PARTITION_STRATEGY_LIST:
			Assert(spec->strategy == PARTITION_STRATEGY_LIST);
			my_qual = get_qual_for_list(key, spec);
			break;

		case PARTITION_STRATEGY_RANGE:
			Assert(spec->strategy == PARTITION_STRATEGY_RANGE);
			my_qual = get_qual_for_range(key, spec);
			break;

		default:
			elog(ERROR, "unexpected partition strategy: %d",
				 (int) key->strategy);
	}

	return my_qual;
}

/*
 * map_partition_varattnos - maps varattno of any Vars in expr from the
 * parent attno to partition attno.
 *
 * We must allow for cases where physical attnos of a partition can be
 * different from the parent's.
 *
 * If found_whole_row is not NULL, *found_whole_row returns whether a
 * whole-row variable was found in the input expression.
 *
 * Note: this will work on any node tree, so really the argument and result
 * should be declared "Node *".  But a substantial majority of the callers
 * are working on Lists, so it's less messy to do the casts internally.
 */
List *
map_partition_varattnos(List *expr, int target_varno,
						Relation partrel, Relation parent,
						bool *found_whole_row)
{
	AttrNumber *part_attnos;
	bool		my_found_whole_row;

	if (expr == NIL)
		return NIL;

	part_attnos = convert_tuples_by_name_map(RelationGetDescr(partrel),
											 RelationGetDescr(parent),
											 gettext_noop("could not convert row type"));
	expr = (List *) map_variable_attnos((Node *) expr,
										target_varno, 0,
										part_attnos,
										RelationGetDescr(parent)->natts,
										RelationGetForm(partrel)->reltype,
										&my_found_whole_row);
	if (found_whole_row)
		*found_whole_row = my_found_whole_row;

	return expr;
}

/*
 * RelationGetPartitionQual
 *
 * Returns a list of partition quals
 */
List *
RelationGetPartitionQual(Relation rel)
{
	/* Quick exit */
	if (!rel->rd_rel->relispartition)
		return NIL;

	return generate_partition_qual(rel);
}

/*
 * get_partition_qual_relid
 *
 * Returns an expression tree describing the passed-in relation's partition
 * constraint.
 */
Expr *
get_partition_qual_relid(Oid relid)
{
	Relation	rel = heap_open(relid, AccessShareLock);
	Expr	   *result = NULL;
	List	   *and_args;

	/* Do the work only if this relation is a partition. */
	if (rel->rd_rel->relispartition)
	{
		and_args = generate_partition_qual(rel);
		if (list_length(and_args) > 1)
			result = makeBoolExpr(AND_EXPR, and_args, -1);
		else
			result = linitial(and_args);
	}

	/* Keep the lock. */
	heap_close(rel, NoLock);

	return result;
}

/*
 * Append OIDs of rel's partitions to the list 'partoids' and for each OID,
 * append pointer rel to the list 'parents'.
 */
#define APPEND_REL_PARTITION_OIDS(rel, partoids, parents) \
	do\
	{\
		int		i;\
		for (i = 0; i < (rel)->rd_partdesc->nparts; i++)\
		{\
			(partoids) = lappend_oid((partoids), (rel)->rd_partdesc->oids[i]);\
			(parents) = lappend((parents), (rel));\
		}\
	} while(0)

/*
 * RelationGetPartitionDispatchInfo
 *		Returns information necessary to route tuples down a partition tree
 *
 * The number of elements in the returned array (that is, the number of
 * PartitionDispatch objects for the partitioned tables in the partition tree)
 * is returned in *num_parted and a list of the OIDs of all the leaf
 * partitions of rel is returned in *leaf_part_oids.
 *
 * All the relations in the partition tree (including 'rel') must have been
 * locked (using at least the AccessShareLock) by the caller.
 */
PartitionDispatch *
RelationGetPartitionDispatchInfo(Relation rel,
								 int *num_parted, List **leaf_part_oids)
{
	PartitionDispatchData **pd;
	List	   *all_parts = NIL,
			   *all_parents = NIL,
			   *parted_rels,
			   *parted_rel_parents;
	ListCell   *lc1,
			   *lc2;
	int			i,
				k,
				offset;

	/*
	 * We rely on the relcache to traverse the partition tree to build both
	 * the leaf partition OIDs list and the array of PartitionDispatch objects
	 * for the partitioned tables in the tree.  That means every partitioned
	 * table in the tree must be locked, which is fine since we require the
	 * caller to lock all the partitions anyway.
	 *
	 * For every partitioned table in the tree, starting with the root
	 * partitioned table, add its relcache entry to parted_rels, while also
	 * queuing its partitions (in the order in which they appear in the
	 * partition descriptor) to be looked at later in the same loop.  This is
	 * a bit tricky but works because the foreach() macro doesn't fetch the
	 * next list element until the bottom of the loop.
	 */
	*num_parted = 1;
	parted_rels = list_make1(rel);
	/* Root partitioned table has no parent, so NULL for parent */
	parted_rel_parents = list_make1(NULL);
	APPEND_REL_PARTITION_OIDS(rel, all_parts, all_parents);
	forboth(lc1, all_parts, lc2, all_parents)
	{
		Oid			partrelid = lfirst_oid(lc1);
		Relation	parent = lfirst(lc2);

		if (get_rel_relkind(partrelid) == RELKIND_PARTITIONED_TABLE)
		{
			/*
			 * Already locked by the caller.  Note that it is the
			 * responsibility of the caller to close the below relcache entry,
			 * once done using the information being collected here (for
			 * example, in ExecEndModifyTable).
			 */
			Relation	partrel = heap_open(partrelid, NoLock);

			(*num_parted)++;
			parted_rels = lappend(parted_rels, partrel);
			parted_rel_parents = lappend(parted_rel_parents, parent);
			APPEND_REL_PARTITION_OIDS(partrel, all_parts, all_parents);
		}
	}

	/*
	 * We want to create two arrays - one for leaf partitions and another for
	 * partitioned tables (including the root table and internal partitions).
	 * While we only create the latter here, leaf partition array of suitable
	 * objects (such as, ResultRelInfo) is created by the caller using the
	 * list of OIDs we return.  Indexes into these arrays get assigned in a
	 * breadth-first manner, whereby partitions of any given level are placed
	 * consecutively in the respective arrays.
	 */
	pd = (PartitionDispatchData **) palloc(*num_parted *
										   sizeof(PartitionDispatchData *));
	*leaf_part_oids = NIL;
	i = k = offset = 0;
	forboth(lc1, parted_rels, lc2, parted_rel_parents)
	{
		Relation	partrel = lfirst(lc1);
		Relation	parent = lfirst(lc2);
		PartitionKey partkey = RelationGetPartitionKey(partrel);
		TupleDesc	tupdesc = RelationGetDescr(partrel);
		PartitionDesc partdesc = RelationGetPartitionDesc(partrel);
		int			j,
					m;

		pd[i] = (PartitionDispatch) palloc(sizeof(PartitionDispatchData));
		pd[i]->reldesc = partrel;
		pd[i]->key = partkey;
		pd[i]->keystate = NIL;
		pd[i]->partdesc = partdesc;
		if (parent != NULL)
		{
			/*
			 * For every partitioned table other than root, we must store a
			 * tuple table slot initialized with its tuple descriptor and a
			 * tuple conversion map to convert a tuple from its parent's
			 * rowtype to its own. That is to make sure that we are looking at
			 * the correct row using the correct tuple descriptor when
			 * computing its partition key for tuple routing.
			 */
			pd[i]->tupslot = MakeSingleTupleTableSlot(tupdesc);
			pd[i]->tupmap = convert_tuples_by_name(RelationGetDescr(parent),
												   tupdesc,
												   gettext_noop("could not convert row type"));
		}
		else
		{
			/* Not required for the root partitioned table */
			pd[i]->tupslot = NULL;
			pd[i]->tupmap = NULL;
		}
		pd[i]->indexes = (int *) palloc(partdesc->nparts * sizeof(int));

		/*
		 * Indexes corresponding to the internal partitions are multiplied by
		 * -1 to distinguish them from those of leaf partitions.  Encountering
		 * an index >= 0 means we found a leaf partition, which is immediately
		 * returned as the partition we are looking for.  A negative index
		 * means we found a partitioned table, whose PartitionDispatch object
		 * is located at the above index multiplied back by -1.  Using the
		 * PartitionDispatch object, search is continued further down the
		 * partition tree.
		 */
		m = 0;
		for (j = 0; j < partdesc->nparts; j++)
		{
			Oid			partrelid = partdesc->oids[j];

			if (get_rel_relkind(partrelid) != RELKIND_PARTITIONED_TABLE)
			{
				*leaf_part_oids = lappend_oid(*leaf_part_oids, partrelid);
				pd[i]->indexes[j] = k++;
			}
			else
			{
				/*
				 * offset denotes the number of partitioned tables of upper
				 * levels including those of the current level.  Any partition
				 * of this table must belong to the next level and hence will
				 * be placed after the last partitioned table of this level.
				 */
				pd[i]->indexes[j] = -(1 + offset + m);
				m++;
			}
		}
		i++;

		/*
		 * This counts the number of partitioned tables at upper levels
		 * including those of the current level.
		 */
		offset += m;
	}

	return pd;
}

/* Module-local functions */

/*
 * get_partition_operator
 *
 * Return oid of the operator of given strategy for a given partition key
 * column.
 */
static Oid
get_partition_operator(PartitionKey key, int col, StrategyNumber strategy,
					   bool *need_relabel)
{
	Oid			operoid;

	/*
	 * First check if there exists an operator of the given strategy, with
	 * this column's type as both its lefttype and righttype, in the
	 * partitioning operator family specified for the column.
	 */
	operoid = get_opfamily_member(key->partopfamily[col],
								  key->parttypid[col],
								  key->parttypid[col],
								  strategy);

	/*
	 * If one doesn't exist, we must resort to using an operator in the same
	 * operator family but with the operator class declared input type.  It is
	 * OK to do so, because the column's type is known to be binary-coercible
	 * with the operator class input type (otherwise, the operator class in
	 * question would not have been accepted as the partitioning operator
	 * class).  We must however inform the caller to wrap the non-Const
	 * expression with a RelabelType node to denote the implicit coercion. It
	 * ensures that the resulting expression structurally matches similarly
	 * processed expressions within the optimizer.
	 */
	if (!OidIsValid(operoid))
	{
		operoid = get_opfamily_member(key->partopfamily[col],
									  key->partopcintype[col],
									  key->partopcintype[col],
									  strategy);
		if (!OidIsValid(operoid))
			elog(ERROR, "missing operator %d(%u,%u) in opfamily %u",
				 strategy, key->partopcintype[col], key->partopcintype[col],
				 key->partopfamily[col]);
		*need_relabel = true;
	}
	else
		*need_relabel = false;

	return operoid;
}

/*
 * make_partition_op_expr
 *		Returns an Expr for the given partition key column with arg1 and
 *		arg2 as its leftop and rightop, respectively
 */
static Expr *
make_partition_op_expr(PartitionKey key, int keynum,
					   uint16 strategy, Expr *arg1, Expr *arg2)
{
	Oid			operoid;
	bool		need_relabel = false;
	Expr	   *result = NULL;

	/* Get the correct btree operator for this partitioning column */
	operoid = get_partition_operator(key, keynum, strategy, &need_relabel);

	/*
	 * Chosen operator may be such that the non-Const operand needs to be
	 * coerced, so apply the same; see the comment in
	 * get_partition_operator().
	 */
	if (!IsA(arg1, Const) &&
		(need_relabel ||
		 key->partcollation[keynum] != key->parttypcoll[keynum]))
		arg1 = (Expr *) makeRelabelType(arg1,
										key->partopcintype[keynum],
										-1,
										key->partcollation[keynum],
										COERCE_EXPLICIT_CAST);

	/* Generate the actual expression */
	switch (key->strategy)
	{
		case PARTITION_STRATEGY_LIST:
			{
				ScalarArrayOpExpr *saopexpr;

				/* Build leftop = ANY (rightop) */
				saopexpr = makeNode(ScalarArrayOpExpr);
				saopexpr->opno = operoid;
				saopexpr->opfuncid = get_opcode(operoid);
				saopexpr->useOr = true;
				saopexpr->inputcollid = key->partcollation[keynum];
				saopexpr->args = list_make2(arg1, arg2);
				saopexpr->location = -1;

				result = (Expr *) saopexpr;
				break;
			}

		case PARTITION_STRATEGY_RANGE:
			result = make_opclause(operoid,
								   BOOLOID,
								   false,
								   arg1, arg2,
								   InvalidOid,
								   key->partcollation[keynum]);
			break;

		default:
			elog(ERROR, "invalid partitioning strategy");
			break;
	}

	return result;
}

/*
 * get_qual_for_list
 *
 * Returns an implicit-AND list of expressions to use as a list partition's
 * constraint, given the partition key and bound structures.
 */
static List *
get_qual_for_list(PartitionKey key, PartitionBoundSpec *spec)
{
	List	   *result;
	Expr	   *keyCol;
	ArrayExpr  *arr;
	Expr	   *opexpr;
	NullTest   *nulltest;
	ListCell   *cell;
	List	   *arrelems = NIL;
	bool		list_has_null = false;

	/*
	 * Only single-column list partitioning is supported, so we are worried
	 * only about the partition key with index 0.
	 */
	Assert(key->partnatts == 1);

	/* Construct Var or expression representing the partition column */
	if (key->partattrs[0] != 0)
		keyCol = (Expr *) makeVar(1,
								  key->partattrs[0],
								  key->parttypid[0],
								  key->parttypmod[0],
								  key->parttypcoll[0],
								  0);
	else
		keyCol = (Expr *) copyObject(linitial(key->partexprs));

	/* Create list of Consts for the allowed values, excluding any nulls */
	foreach(cell, spec->listdatums)
	{
		Const	   *val = castNode(Const, lfirst(cell));

		if (val->constisnull)
			list_has_null = true;
		else
			arrelems = lappend(arrelems, copyObject(val));
	}

	if (arrelems)
	{
		/* Construct an ArrayExpr for the non-null partition values */
		arr = makeNode(ArrayExpr);
		arr->array_typeid = !type_is_array(key->parttypid[0])
			? get_array_type(key->parttypid[0])
			: key->parttypid[0];
		arr->array_collid = key->parttypcoll[0];
		arr->element_typeid = key->parttypid[0];
		arr->elements = arrelems;
		arr->multidims = false;
		arr->location = -1;

		/* Generate the main expression, i.e., keyCol = ANY (arr) */
		opexpr = make_partition_op_expr(key, 0, BTEqualStrategyNumber,
										keyCol, (Expr *) arr);
	}
	else
	{
		/* If there are no partition values, we don't need an = ANY expr */
		opexpr = NULL;
	}

	if (!list_has_null)
	{
		/*
		 * Gin up a "col IS NOT NULL" test that will be AND'd with the main
		 * expression.  This might seem redundant, but the partition routing
		 * machinery needs it.
		 */
		nulltest = makeNode(NullTest);
		nulltest->arg = keyCol;
		nulltest->nulltesttype = IS_NOT_NULL;
		nulltest->argisrow = false;
		nulltest->location = -1;

		result = opexpr ? list_make2(nulltest, opexpr) : list_make1(nulltest);
	}
	else
	{
		/*
		 * Gin up a "col IS NULL" test that will be OR'd with the main
		 * expression.
		 */
		nulltest = makeNode(NullTest);
		nulltest->arg = keyCol;
		nulltest->nulltesttype = IS_NULL;
		nulltest->argisrow = false;
		nulltest->location = -1;

		if (opexpr)
		{
			Expr	   *or;

			or = makeBoolExpr(OR_EXPR, list_make2(nulltest, opexpr), -1);
			result = list_make1(or);
		}
		else
			result = list_make1(nulltest);
	}

	return result;
}

/*
 * get_range_key_properties
 *		Returns range partition key information for a given column
 *
 * This is a subroutine for get_qual_for_range, and its API is pretty
 * specialized to that caller.
 *
 * Constructs an Expr for the key column (returned in *keyCol) and Consts
 * for the lower and upper range limits (returned in *lower_val and
 * *upper_val).  For MINVALUE/MAXVALUE limits, NULL is returned instead of
 * a Const.  All of these structures are freshly palloc'd.
 *
 * *partexprs_item points to the cell containing the next expression in
 * the key->partexprs list, or NULL.  It may be advanced upon return.
 */
static void
get_range_key_properties(PartitionKey key, int keynum,
						 PartitionRangeDatum *ldatum,
						 PartitionRangeDatum *udatum,
						 ListCell **partexprs_item,
						 Expr **keyCol,
						 Const **lower_val, Const **upper_val)
{
	/* Get partition key expression for this column */
	if (key->partattrs[keynum] != 0)
	{
		*keyCol = (Expr *) makeVar(1,
								   key->partattrs[keynum],
								   key->parttypid[keynum],
								   key->parttypmod[keynum],
								   key->parttypcoll[keynum],
								   0);
	}
	else
	{
		if (*partexprs_item == NULL)
			elog(ERROR, "wrong number of partition key expressions");
		*keyCol = copyObject(lfirst(*partexprs_item));
		*partexprs_item = lnext(*partexprs_item);
	}

	/* Get appropriate Const nodes for the bounds */
	if (ldatum->kind == PARTITION_RANGE_DATUM_VALUE)
		*lower_val = castNode(Const, copyObject(ldatum->value));
	else
		*lower_val = NULL;

	if (udatum->kind == PARTITION_RANGE_DATUM_VALUE)
		*upper_val = castNode(Const, copyObject(udatum->value));
	else
		*upper_val = NULL;
}

/*
 * get_qual_for_range
 *
 * Returns an implicit-AND list of expressions to use as a range partition's
 * constraint, given the partition key and bound structures.
 *
 * For a multi-column range partition key, say (a, b, c), with (al, bl, cl)
 * as the lower bound tuple and (au, bu, cu) as the upper bound tuple, we
 * generate an expression tree of the following form:
 *
 *	(a IS NOT NULL) and (b IS NOT NULL) and (c IS NOT NULL)
 *		AND
 *	(a > al OR (a = al AND b > bl) OR (a = al AND b = bl AND c >= cl))
 *		AND
 *	(a < au OR (a = au AND b < bu) OR (a = au AND b = bu AND c < cu))
 *
 * It is often the case that a prefix of lower and upper bound tuples contains
 * the same values, for example, (al = au), in which case, we will emit an
 * expression tree of the following form:
 *
 *	(a IS NOT NULL) and (b IS NOT NULL) and (c IS NOT NULL)
 *		AND
 *	(a = al)
 *		AND
 *	(b > bl OR (b = bl AND c >= cl))
 *		AND
 *	(b < bu) OR (b = bu AND c < cu))
 *
 * If a bound datum is either MINVALUE or MAXVALUE, these expressions are
 * simplified using the fact that any value is greater than MINVALUE and less
 * than MAXVALUE. So, for example, if cu = MAXVALUE, c < cu is automatically
 * true, and we need not emit any expression for it, and the last line becomes
 *
 *	(b < bu) OR (b = bu), which is simplified to (b <= bu)
 *
 * In most common cases with only one partition column, say a, the following
 * expression tree will be generated: a IS NOT NULL AND a >= al AND a < au
 *
 * If we end up with an empty result list, we return a single-member list
 * containing a constant TRUE, because callers expect a non-empty list.
 */
static List *
get_qual_for_range(PartitionKey key, PartitionBoundSpec *spec)
{
	List	   *result = NIL;
	ListCell   *cell1,
			   *cell2,
			   *partexprs_item,
			   *partexprs_item_saved;
	int			i,
				j;
	PartitionRangeDatum *ldatum,
			   *udatum;
	Expr	   *keyCol;
	Const	   *lower_val,
			   *upper_val;
	NullTest   *nulltest;
	List	   *lower_or_arms,
			   *upper_or_arms;
	int			num_or_arms,
				current_or_arm;
	ListCell   *lower_or_start_datum,
			   *upper_or_start_datum;
	bool		need_next_lower_arm,
				need_next_upper_arm;

	lower_or_start_datum = list_head(spec->lowerdatums);
	upper_or_start_datum = list_head(spec->upperdatums);
	num_or_arms = key->partnatts;

	/*
	 * A range-partitioned table does not currently allow partition keys to be
	 * null, so emit an IS NOT NULL expression for each key column.
	 */
	partexprs_item = list_head(key->partexprs);
	for (i = 0; i < key->partnatts; i++)
	{
		Expr	   *keyCol;

		if (key->partattrs[i] != 0)
		{
			keyCol = (Expr *) makeVar(1,
									  key->partattrs[i],
									  key->parttypid[i],
									  key->parttypmod[i],
									  key->parttypcoll[i],
									  0);
		}
		else
		{
			if (partexprs_item == NULL)
				elog(ERROR, "wrong number of partition key expressions");
			keyCol = copyObject(lfirst(partexprs_item));
			partexprs_item = lnext(partexprs_item);
		}

		nulltest = makeNode(NullTest);
		nulltest->arg = keyCol;
		nulltest->nulltesttype = IS_NOT_NULL;
		nulltest->argisrow = false;
		nulltest->location = -1;
		result = lappend(result, nulltest);
	}

	/*
	 * Iterate over the key columns and check if the corresponding lower and
	 * upper datums are equal using the btree equality operator for the
	 * column's type.  If equal, we emit single keyCol = common_value
	 * expression.  Starting from the first column for which the corresponding
	 * lower and upper bound datums are not equal, we generate OR expressions
	 * as shown in the function's header comment.
	 */
	i = 0;
	partexprs_item = list_head(key->partexprs);
	partexprs_item_saved = partexprs_item;	/* placate compiler */
	forboth(cell1, spec->lowerdatums, cell2, spec->upperdatums)
	{
		EState	   *estate;
		MemoryContext oldcxt;
		Expr	   *test_expr;
		ExprState  *test_exprstate;
		Datum		test_result;
		bool		isNull;

		ldatum = castNode(PartitionRangeDatum, lfirst(cell1));
		udatum = castNode(PartitionRangeDatum, lfirst(cell2));

		/*
		 * Since get_range_key_properties() modifies partexprs_item, and we
		 * might need to start over from the previous expression in the later
		 * part of this function, save away the current value.
		 */
		partexprs_item_saved = partexprs_item;

		get_range_key_properties(key, i, ldatum, udatum,
								 &partexprs_item,
								 &keyCol,
								 &lower_val, &upper_val);

		/*
		 * If either value is NULL, the corresponding partition bound is
		 * either MINVALUE or MAXVALUE, and we treat them as unequal, because
		 * even if they're the same, there is no common value to equate the
		 * key column with.
		 */
		if (!lower_val || !upper_val)
			break;

		/* Create the test expression */
		estate = CreateExecutorState();
		oldcxt = MemoryContextSwitchTo(estate->es_query_cxt);
		test_expr = make_partition_op_expr(key, i, BTEqualStrategyNumber,
										   (Expr *) lower_val,
										   (Expr *) upper_val);
		fix_opfuncids((Node *) test_expr);
		test_exprstate = ExecInitExpr(test_expr, NULL);
		test_result = ExecEvalExprSwitchContext(test_exprstate,
												GetPerTupleExprContext(estate),
												&isNull);
		MemoryContextSwitchTo(oldcxt);
		FreeExecutorState(estate);

		/* If not equal, go generate the OR expressions */
		if (!DatumGetBool(test_result))
			break;

		/*
		 * The bounds for the last key column can't be equal, because such a
		 * range partition would never be allowed to be defined (it would have
		 * an empty range otherwise).
		 */
		if (i == key->partnatts - 1)
			elog(ERROR, "invalid range bound specification");

		/* Equal, so generate keyCol = lower_val expression */
		result = lappend(result,
						 make_partition_op_expr(key, i, BTEqualStrategyNumber,
												keyCol, (Expr *) lower_val));

		i++;
	}

	/* First pair of lower_val and upper_val that are not equal. */
	lower_or_start_datum = cell1;
	upper_or_start_datum = cell2;

	/* OR will have as many arms as there are key columns left. */
	num_or_arms = key->partnatts - i;
	current_or_arm = 0;
	lower_or_arms = upper_or_arms = NIL;
	need_next_lower_arm = need_next_upper_arm = true;
	while (current_or_arm < num_or_arms)
	{
		List	   *lower_or_arm_args = NIL,
				   *upper_or_arm_args = NIL;

		/* Restart scan of columns from the i'th one */
		j = i;
		partexprs_item = partexprs_item_saved;

		for_both_cell(cell1, lower_or_start_datum, cell2, upper_or_start_datum)
		{
			PartitionRangeDatum *ldatum_next = NULL,
					   *udatum_next = NULL;

			ldatum = castNode(PartitionRangeDatum, lfirst(cell1));
			if (lnext(cell1))
				ldatum_next = castNode(PartitionRangeDatum,
									   lfirst(lnext(cell1)));
			udatum = castNode(PartitionRangeDatum, lfirst(cell2));
			if (lnext(cell2))
				udatum_next = castNode(PartitionRangeDatum,
									   lfirst(lnext(cell2)));
			get_range_key_properties(key, j, ldatum, udatum,
									 &partexprs_item,
									 &keyCol,
									 &lower_val, &upper_val);

			if (need_next_lower_arm && lower_val)
			{
				uint16		strategy;

				/*
				 * For the non-last columns of this arm, use the EQ operator.
				 * For the last column of this arm, use GT, unless this is the
				 * last column of the whole bound check, or the next bound
				 * datum is MINVALUE, in which case use GE.
				 */
				if (j - i < current_or_arm)
					strategy = BTEqualStrategyNumber;
				else if (j == key->partnatts - 1 ||
						 (ldatum_next &&
						  ldatum_next->kind == PARTITION_RANGE_DATUM_MINVALUE))
					strategy = BTGreaterEqualStrategyNumber;
				else
					strategy = BTGreaterStrategyNumber;

				lower_or_arm_args = lappend(lower_or_arm_args,
											make_partition_op_expr(key, j,
																   strategy,
																   keyCol,
																   (Expr *) lower_val));
			}

			if (need_next_upper_arm && upper_val)
			{
				uint16		strategy;

				/*
				 * For the non-last columns of this arm, use the EQ operator.
				 * For the last column of this arm, use LT, unless the next
				 * bound datum is MAXVALUE, in which case use LE.
				 */
				if (j - i < current_or_arm)
					strategy = BTEqualStrategyNumber;
				else if (udatum_next &&
						 udatum_next->kind == PARTITION_RANGE_DATUM_MAXVALUE)
					strategy = BTLessEqualStrategyNumber;
				else
					strategy = BTLessStrategyNumber;

				upper_or_arm_args = lappend(upper_or_arm_args,
											make_partition_op_expr(key, j,
																   strategy,
																   keyCol,
																   (Expr *) upper_val));
			}

			/*
			 * Did we generate enough of OR's arguments?  First arm considers
			 * the first of the remaining columns, second arm considers first
			 * two of the remaining columns, and so on.
			 */
			++j;
			if (j - i > current_or_arm)
			{
				/*
				 * We must not emit any more arms if the new column that will
				 * be considered is unbounded, or this one was.
				 */
				if (!lower_val || !ldatum_next ||
					ldatum_next->kind != PARTITION_RANGE_DATUM_VALUE)
					need_next_lower_arm = false;
				if (!upper_val || !udatum_next ||
					udatum_next->kind != PARTITION_RANGE_DATUM_VALUE)
					need_next_upper_arm = false;
				break;
			}
		}

		if (lower_or_arm_args != NIL)
			lower_or_arms = lappend(lower_or_arms,
									list_length(lower_or_arm_args) > 1
									? makeBoolExpr(AND_EXPR, lower_or_arm_args, -1)
									: linitial(lower_or_arm_args));

		if (upper_or_arm_args != NIL)
			upper_or_arms = lappend(upper_or_arms,
									list_length(upper_or_arm_args) > 1
									? makeBoolExpr(AND_EXPR, upper_or_arm_args, -1)
									: linitial(upper_or_arm_args));

		/* If no work to do in the next iteration, break away. */
		if (!need_next_lower_arm && !need_next_upper_arm)
			break;

		++current_or_arm;
	}

	/*
	 * Generate the OR expressions for each of lower and upper bounds (if
	 * required), and append to the list of implicitly ANDed list of
	 * expressions.
	 */
	if (lower_or_arms != NIL)
		result = lappend(result,
						 list_length(lower_or_arms) > 1
						 ? makeBoolExpr(OR_EXPR, lower_or_arms, -1)
						 : linitial(lower_or_arms));
	if (upper_or_arms != NIL)
		result = lappend(result,
						 list_length(upper_or_arms) > 1
						 ? makeBoolExpr(OR_EXPR, upper_or_arms, -1)
						 : linitial(upper_or_arms));

	/* As noted above, caller expects the list to be non-empty. */
	if (result == NIL)
		result = list_make1(makeBoolConst(true, false));

	return result;
}

/*
 * generate_partition_qual
 *
 * Generate partition predicate from rel's partition bound expression
 *
 * Result expression tree is stored CacheMemoryContext to ensure it survives
 * as long as the relcache entry. But we should be running in a less long-lived
 * working context. To avoid leaking cache memory if this routine fails partway
 * through, we build in working memory and then copy the completed structure
 * into cache memory.
 */
static List *
generate_partition_qual(Relation rel)
{
	HeapTuple	tuple;
	MemoryContext oldcxt;
	Datum		boundDatum;
	bool		isnull;
	PartitionBoundSpec *bound;
	List	   *my_qual = NIL,
			   *result = NIL;
	Relation	parent;
	bool		found_whole_row;

	/* Guard against stack overflow due to overly deep partition tree */
	check_stack_depth();

	/* Quick copy */
	if (rel->rd_partcheck != NIL)
		return copyObject(rel->rd_partcheck);

	/* Grab at least an AccessShareLock on the parent table */
	parent = heap_open(get_partition_parent(RelationGetRelid(rel)),
					   AccessShareLock);

	/* Get pg_class.relpartbound */
	tuple = SearchSysCache1(RELOID, RelationGetRelid(rel));
	if (!HeapTupleIsValid(tuple))
		elog(ERROR, "cache lookup failed for relation %u",
			 RelationGetRelid(rel));

	boundDatum = SysCacheGetAttr(RELOID, tuple,
								 Anum_pg_class_relpartbound,
								 &isnull);
	if (isnull)					/* should not happen */
		elog(ERROR, "relation \"%s\" has relpartbound = null",
			 RelationGetRelationName(rel));
	bound = castNode(PartitionBoundSpec,
					 stringToNode(TextDatumGetCString(boundDatum)));
	ReleaseSysCache(tuple);

	my_qual = get_qual_from_partbound(rel, parent, bound);

	/* Add the parent's quals to the list (if any) */
	if (parent->rd_rel->relispartition)
		result = list_concat(generate_partition_qual(parent), my_qual);
	else
		result = my_qual;

	/*
	 * Change Vars to have partition's attnos instead of the parent's. We do
	 * this after we concatenate the parent's quals, because we want every Var
	 * in it to bear this relation's attnos. It's safe to assume varno = 1
	 * here.
	 */
	result = map_partition_varattnos(result, 1, rel, parent,
									 &found_whole_row);
	/* There can never be a whole-row reference here */
	if (found_whole_row)
		elog(ERROR, "unexpected whole-row reference found in partition key");

	/* Save a copy in the relcache */
	oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
	rel->rd_partcheck = copyObject(result);
	MemoryContextSwitchTo(oldcxt);

	/* Keep the parent locked until commit */
	heap_close(parent, NoLock);

	return result;
}

/* ----------------
 *		FormPartitionKeyDatum
 *			Construct values[] and isnull[] arrays for the partition key
 *			of a tuple.
 *
 *	pd				Partition dispatch object of the partitioned table
 *	slot			Heap tuple from which to extract partition key
 *	estate			executor state for evaluating any partition key
 *					expressions (must be non-NULL)
 *	values			Array of partition key Datums (output area)
 *	isnull			Array of is-null indicators (output area)
 *
 * the ecxt_scantuple slot of estate's per-tuple expr context must point to
 * the heap tuple passed in.
 * ----------------
 */
void
FormPartitionKeyDatum(PartitionDispatch pd,
					  TupleTableSlot *slot,
					  EState *estate,
					  Datum *values,
					  bool *isnull)
{
	ListCell   *partexpr_item;
	int			i;

	if (pd->key->partexprs != NIL && pd->keystate == NIL)
	{
		/* Check caller has set up context correctly */
		Assert(estate != NULL &&
			   GetPerTupleExprContext(estate)->ecxt_scantuple == slot);

		/* First time through, set up expression evaluation state */
		pd->keystate = ExecPrepareExprList(pd->key->partexprs, estate);
	}

	partexpr_item = list_head(pd->keystate);
	for (i = 0; i < pd->key->partnatts; i++)
	{
		AttrNumber	keycol = pd->key->partattrs[i];
		Datum		datum;
		bool		isNull;

		if (keycol != 0)
		{
			/* Plain column; get the value directly from the heap tuple */
			datum = slot_getattr(slot, keycol, &isNull);
		}
		else
		{
			/* Expression; need to evaluate it */
			if (partexpr_item == NULL)
				elog(ERROR, "wrong number of partition key expressions");
			datum = ExecEvalExprSwitchContext((ExprState *) lfirst(partexpr_item),
											  GetPerTupleExprContext(estate),
											  &isNull);
			partexpr_item = lnext(partexpr_item);
		}
		values[i] = datum;
		isnull[i] = isNull;
	}

	if (partexpr_item != NULL)
		elog(ERROR, "wrong number of partition key expressions");
}

/*
 * get_partition_for_tuple
 *		Finds a leaf partition for tuple contained in *slot
 *
 * Returned value is the sequence number of the leaf partition thus found,
 * or -1 if no leaf partition is found for the tuple.  *failed_at is set
 * to the OID of the partitioned table whose partition was not found in
 * the latter case.
 */
int
get_partition_for_tuple(PartitionDispatch *pd,
						TupleTableSlot *slot,
						EState *estate,
						PartitionDispatchData **failed_at,
						TupleTableSlot **failed_slot)
{
	PartitionDispatch parent;
	Datum		values[PARTITION_MAX_KEYS];
	bool		isnull[PARTITION_MAX_KEYS];
	int			result;
	ExprContext *ecxt = GetPerTupleExprContext(estate);
	TupleTableSlot *ecxt_scantuple_old = ecxt->ecxt_scantuple;

	/* start with the root partitioned table */
	parent = pd[0];
	while (true)
	{
		PartitionKey key = parent->key;
		PartitionDesc partdesc = parent->partdesc;
		TupleTableSlot *myslot = parent->tupslot;
		TupleConversionMap *map = parent->tupmap;
		int		cur_index = -1;

		if (myslot != NULL && map != NULL)
		{
			HeapTuple	tuple = ExecFetchSlotTuple(slot);

			ExecClearTuple(myslot);
			tuple = do_convert_tuple(tuple, map);
			ExecStoreTuple(tuple, myslot, InvalidBuffer, true);
			slot = myslot;
		}

		/* Quick exit */
		if (partdesc->nparts == 0)
		{
			*failed_at = parent;
			*failed_slot = slot;
			result = -1;
			goto error_exit;
		}

		/*
		 * Extract partition key from tuple. Expression evaluation machinery
		 * that FormPartitionKeyDatum() invokes expects ecxt_scantuple to
		 * point to the correct tuple slot.  The slot might have changed from
		 * what was used for the parent table if the table of the current
		 * partitioning level has different tuple descriptor from the parent.
		 * So update ecxt_scantuple accordingly.
		 */
		ecxt->ecxt_scantuple = slot;
		FormPartitionKeyDatum(parent, slot, estate, values, isnull);

		/* Route as appropriate based on partitioning strategy. */
		switch (key->strategy)
		{
			case PARTITION_STRATEGY_LIST:

				if (isnull[0])
				{
					if (partition_bound_accepts_nulls(partdesc->boundinfo))
						cur_index = partdesc->boundinfo->null_index;
				}
				else
				{
					bool		equal = false;
					int			cur_offset;

					cur_offset = partition_bound_bsearch(key,
														 partdesc->boundinfo,
														 values,
														 false,
														 &equal);
					if (cur_offset >= 0 && equal)
						cur_index = partdesc->boundinfo->indexes[cur_offset];
				}
				break;

			case PARTITION_STRATEGY_RANGE:
				{
					bool		equal = false;
					int			cur_offset;
					int			i;

					/* No range includes NULL. */
					for (i = 0; i < key->partnatts; i++)
					{
						if (isnull[i])
						{
							*failed_at = parent;
							*failed_slot = slot;
							result = -1;
							goto error_exit;
						}
					}

					cur_offset = partition_bound_bsearch(key,
														 partdesc->boundinfo,
														 values,
														 false,
														 &equal);

					/*
					 * The offset returned is such that the bound at cur_offset
					 * is less than or equal to the tuple value, so the bound
					 * at offset+1 is the upper bound.
					 */
					cur_index = partdesc->boundinfo->indexes[cur_offset + 1];
				}
				break;

			default:
				elog(ERROR, "unexpected partition strategy: %d",
					 (int) key->strategy);
		}

		/*
		 * cur_index < 0 means we failed to find a partition of this parent.
		 * cur_index >= 0 means we either found the leaf partition, or the
		 * next parent to find a partition of.
		 */
		if (cur_index < 0)
		{
			result = -1;
			*failed_at = parent;
			*failed_slot = slot;
			break;
		}
		else if (parent->indexes[cur_index] >= 0)
		{
			result = parent->indexes[cur_index];
			break;
		}
		else
			parent = pd[-parent->indexes[cur_index]];
	}

error_exit:
	ecxt->ecxt_scantuple = ecxt_scantuple_old;
	return result;
}

/*
 * qsort_partition_list_value_cmp
 *
 * Compare two list partition bound datums
 */
static int32
qsort_partition_list_value_cmp(const void *a, const void *b, void *arg)
{
	Datum		val1 = (*(const PartitionListValue **) a)->value,
				val2 = (*(const PartitionListValue **) b)->value;
	PartitionKey key = (PartitionKey) arg;

	return DatumGetInt32(FunctionCall2Coll(&key->partsupfunc[0],
										   key->partcollation[0],
										   val1, val2));
}

/*
 * make_one_range_bound
 *
 * Return a PartitionRangeBound given a list of PartitionRangeDatum elements
 * and a flag telling whether the bound is lower or not.  Made into a function
 * because there are multiple sites that want to use this facility.
 */
static PartitionRangeBound *
make_one_range_bound(PartitionKey key, int index, List *datums, bool lower)
{
	PartitionRangeBound *bound;
	ListCell   *lc;
	int			i;

	bound = (PartitionRangeBound *) palloc0(sizeof(PartitionRangeBound));
	bound->index = index;
	bound->datums = (Datum *) palloc0(key->partnatts * sizeof(Datum));
	bound->kind = (PartitionRangeDatumKind *) palloc0(key->partnatts *
													  sizeof(PartitionRangeDatumKind));
	bound->lower = lower;

	i = 0;
	foreach(lc, datums)
	{
		PartitionRangeDatum *datum = castNode(PartitionRangeDatum, lfirst(lc));

		/* What's contained in this range datum? */
		bound->kind[i] = datum->kind;

		if (datum->kind == PARTITION_RANGE_DATUM_VALUE)
		{
			Const	   *val = castNode(Const, datum->value);

			if (val->constisnull)
				elog(ERROR, "invalid range bound datum");
			bound->datums[i] = val->constvalue;
		}

		i++;
	}

	return bound;
}

/* Used when sorting range bounds across all range partitions */
static int32
qsort_partition_rbound_cmp(const void *a, const void *b, void *arg)
{
	PartitionRangeBound *b1 = (*(PartitionRangeBound *const *) a);
	PartitionRangeBound *b2 = (*(PartitionRangeBound *const *) b);
	PartitionKey key = (PartitionKey) arg;

	return partition_rbound_cmp(key, b1->datums, b1->kind, b1->lower, b2);
}

/*
 * partition_rbound_cmp
 *
 * Return for two range bounds whether the 1st one (specified in datum1,
 * kind1, and lower1) is <, =, or > the bound specified in *b2.
 *
 * Note that if the values of the two range bounds compare equal, then we take
 * into account whether they are upper or lower bounds, and an upper bound is
 * considered to be smaller than a lower bound. This is important to the way
 * that RelationBuildPartitionDesc() builds the PartitionBoundInfoData
 * structure, which only stores the upper bound of a common boundary between
 * two contiguous partitions.
 */
static int32
partition_rbound_cmp(PartitionKey key,
					 Datum *datums1, PartitionRangeDatumKind *kind1,
					 bool lower1, PartitionRangeBound *b2)
{
	int32		cmpval = 0;		/* placate compiler */
	int			i;
	Datum	   *datums2 = b2->datums;
	PartitionRangeDatumKind *kind2 = b2->kind;
	bool		lower2 = b2->lower;

	for (i = 0; i < key->partnatts; i++)
	{
		/*
		 * First, handle cases where the column is unbounded, which should not
		 * invoke the comparison procedure, and should not consider any later
		 * columns. Note that the PartitionRangeDatumKind enum elements
		 * compare the same way as the values they represent.
		 */
		if (kind1[i] < kind2[i])
			return -1;
		else if (kind1[i] > kind2[i])
			return 1;
		else if (kind1[i] != PARTITION_RANGE_DATUM_VALUE)

			/*
			 * The column bounds are both MINVALUE or both MAXVALUE. No later
			 * columns should be considered, but we still need to compare
			 * whether they are upper or lower bounds.
			 */
			break;

		cmpval = DatumGetInt32(FunctionCall2Coll(&key->partsupfunc[i],
												 key->partcollation[i],
												 datums1[i],
												 datums2[i]));
		if (cmpval != 0)
			break;
	}

	/*
	 * If the comparison is anything other than equal, we're done. If they
	 * compare equal though, we still have to consider whether the boundaries
	 * are inclusive or exclusive.  Exclusive one is considered smaller of the
	 * two.
	 */
	if (cmpval == 0 && lower1 != lower2)
		cmpval = lower1 ? 1 : -1;

	return cmpval;
}

/*
 * partition_rbound_datum_cmp
 *
 * Return whether range bound (specified in rb_datums, rb_kind, and rb_lower)
 * is <, =, or > partition key of tuple (tuple_datums)
 */
static int32
partition_rbound_datum_cmp(PartitionKey key,
						   Datum *rb_datums, PartitionRangeDatumKind *rb_kind,
						   Datum *tuple_datums)
{
	int			i;
	int32		cmpval = -1;

	for (i = 0; i < key->partnatts; i++)
	{
		if (rb_kind[i] == PARTITION_RANGE_DATUM_MINVALUE)
			return -1;
		else if (rb_kind[i] == PARTITION_RANGE_DATUM_MAXVALUE)
			return 1;

		cmpval = DatumGetInt32(FunctionCall2Coll(&key->partsupfunc[i],
												 key->partcollation[i],
												 rb_datums[i],
												 tuple_datums[i]));
		if (cmpval != 0)
			break;
	}

	return cmpval;
}

/*
 * partition_bound_cmp
 *
 * Return whether the bound at offset in boundinfo is <, =, or > the argument
 * specified in *probe.
 */
static int32
partition_bound_cmp(PartitionKey key, PartitionBoundInfo boundinfo,
					int offset, void *probe, bool probe_is_bound)
{
	Datum	   *bound_datums = boundinfo->datums[offset];
	int32		cmpval = -1;

	switch (key->strategy)
	{
		case PARTITION_STRATEGY_LIST:
			cmpval = DatumGetInt32(FunctionCall2Coll(&key->partsupfunc[0],
													 key->partcollation[0],
													 bound_datums[0],
													 *(Datum *) probe));
			break;

		case PARTITION_STRATEGY_RANGE:
			{
				PartitionRangeDatumKind *kind = boundinfo->kind[offset];

				if (probe_is_bound)
				{
					/*
					 * We need to pass whether the existing bound is a lower
					 * bound, so that two equal-valued lower and upper bounds
					 * are not regarded equal.
					 */
					bool		lower = boundinfo->indexes[offset] < 0;

					cmpval = partition_rbound_cmp(key,
												  bound_datums, kind, lower,
												  (PartitionRangeBound *) probe);
				}
				else
					cmpval = partition_rbound_datum_cmp(key,
														bound_datums, kind,
														(Datum *) probe);
				break;
			}

		default:
			elog(ERROR, "unexpected partition strategy: %d",
				 (int) key->strategy);
	}

	return cmpval;
}

/*
 * Binary search on a collection of partition bounds. Returns greatest
 * bound in array boundinfo->datums which is less than or equal to *probe.
 * If all bounds in the array are greater than *probe, -1 is returned.
 *
 * *probe could either be a partition bound or a Datum array representing
 * the partition key of a tuple being routed; probe_is_bound tells which.
 * We pass that down to the comparison function so that it can interpret the
 * contents of *probe accordingly.
 *
 * *is_equal is set to whether the bound at the returned index is equal with
 * *probe.
 */
static int
partition_bound_bsearch(PartitionKey key, PartitionBoundInfo boundinfo,
						void *probe, bool probe_is_bound, bool *is_equal)
{
	int			lo,
				hi,
				mid;

	lo = -1;
	hi = boundinfo->ndatums - 1;
	while (lo < hi)
	{
		int32		cmpval;

		mid = (lo + hi + 1) / 2;
		cmpval = partition_bound_cmp(key, boundinfo, mid, probe,
									 probe_is_bound);
		if (cmpval <= 0)
		{
			lo = mid;
			*is_equal = (cmpval == 0);

			if (*is_equal)
				break;
		}
		else
			hi = mid - 1;
	}

	return lo;
}