postgresql/src/backend/optimizer/path/allpaths.c

/*-------------------------------------------------------------------------
 *
 * allpaths.c
 *	  Routines to find possible search paths for processing a query
 *
 * Portions Copyright (c) 1996-2002, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *	  $Header: /cvsroot/pgsql/src/backend/optimizer/path/allpaths.c,v 1.96 2003/02/08 20:20:54 tgl Exp $
 *
 *-------------------------------------------------------------------------
 */

#include "postgres.h"

#ifdef OPTIMIZER_DEBUG
#include "nodes/print.h"
#endif
#include "optimizer/clauses.h"
#include "optimizer/cost.h"
#include "optimizer/geqo.h"
#include "optimizer/pathnode.h"
#include "optimizer/paths.h"
#include "optimizer/plancat.h"
#include "optimizer/planner.h"
#include "optimizer/prep.h"
#include "parser/parsetree.h"
#include "rewrite/rewriteManip.h"


/* These parameters are set by GUC */
bool		enable_geqo = false;	/* just in case GUC doesn't set it */
int			geqo_threshold;


static void set_base_rel_pathlists(Query *root);
static void set_plain_rel_pathlist(Query *root, RelOptInfo *rel,
					   RangeTblEntry *rte);
static void set_inherited_rel_pathlist(Query *root, RelOptInfo *rel,
						   Index rti, RangeTblEntry *rte,
						   List *inheritlist);
static void set_subquery_pathlist(Query *root, RelOptInfo *rel,
					  Index rti, RangeTblEntry *rte);
static void set_function_pathlist(Query *root, RelOptInfo *rel,
					  RangeTblEntry *rte);
static RelOptInfo *make_one_rel_by_joins(Query *root, int levels_needed,
					  List *initial_rels);
static bool subquery_is_pushdown_safe(Query *subquery, Query *topquery);
static bool recurse_pushdown_safe(Node *setOp, Query *topquery);
static void subquery_push_qual(Query *subquery, Index rti, Node *qual);
static void recurse_push_qual(Node *setOp, Query *topquery,
				  Index rti, Node *qual);


/*
 * make_one_rel
 *	  Finds all possible access paths for executing a query, returning a
 *	  single rel that represents the join of all base rels in the query.
 */
RelOptInfo *
make_one_rel(Query *root)
{
	RelOptInfo *rel;

	/*
	 * Generate access paths for the base rels.
	 */
	set_base_rel_pathlists(root);

	/*
	 * Generate access paths for the entire join tree.
	 */
	Assert(root->jointree != NULL && IsA(root->jointree, FromExpr));

	rel = make_fromexpr_rel(root, root->jointree);

	/*
	 * The result should join all the query's base rels.
	 */
	Assert(bms_num_members(rel->relids) == length(root->base_rel_list));

	return rel;
}

/*
 * set_base_rel_pathlists
 *	  Finds all paths available for scanning each base-relation entry.
 *	  Sequential scan and any available indices are considered.
 *	  Each useful path is attached to its relation's 'pathlist' field.
 */
static void
set_base_rel_pathlists(Query *root)
{
	List	   *rellist;

	foreach(rellist, root->base_rel_list)
	{
		RelOptInfo *rel = (RelOptInfo *) lfirst(rellist);
		Index		rti = rel->relid;
		RangeTblEntry *rte;
		List	   *inheritlist;

		Assert(rti > 0);		/* better be base rel */
		rte = rt_fetch(rti, root->rtable);

		if (rel->rtekind == RTE_SUBQUERY)
		{
			/* Subquery --- generate a separate plan for it */
			set_subquery_pathlist(root, rel, rti, rte);
		}
		else if (rel->rtekind == RTE_FUNCTION)
		{
			/* RangeFunction --- generate a separate plan for it */
			set_function_pathlist(root, rel, rte);
		}
		else if ((inheritlist = expand_inherted_rtentry(root, rti, true))
				 != NIL)
		{
			/* Relation is root of an inheritance tree, process specially */
			set_inherited_rel_pathlist(root, rel, rti, rte, inheritlist);
		}
		else
		{
			/* Plain relation */
			set_plain_rel_pathlist(root, rel, rte);
		}

#ifdef OPTIMIZER_DEBUG
		debug_print_rel(root, rel);
#endif
	}
}

/*
 * set_plain_rel_pathlist
 *	  Build access paths for a plain relation (no subquery, no inheritance)
 */
static void
set_plain_rel_pathlist(Query *root, RelOptInfo *rel, RangeTblEntry *rte)
{
	/* Mark rel with estimated output rows, width, etc */
	set_baserel_size_estimates(root, rel);

	/*
	 * Generate paths and add them to the rel's pathlist.
	 *
	 * Note: add_path() will discard any paths that are dominated by another
	 * available path, keeping only those paths that are superior along at
	 * least one dimension of cost or sortedness.
	 */

	/* Consider sequential scan */
	add_path(rel, create_seqscan_path(root, rel));

	/* Consider TID scans */
	create_tidscan_paths(root, rel);

	/* Consider index paths for both simple and OR index clauses */
	create_index_paths(root, rel);

	/* create_index_paths must be done before create_or_index_paths */
	create_or_index_paths(root, rel);

	/* Now find the cheapest of the paths for this rel */
	set_cheapest(rel);
}

/*
 * set_inherited_rel_pathlist
 *	  Build access paths for a inheritance tree rooted at rel
 *
 * inheritlist is a list of RT indexes of all tables in the inheritance tree,
 * including a duplicate of the parent itself.	Note we will not come here
 * unless there's at least one child in addition to the parent.
 *
 * NOTE: the passed-in rel and RTE will henceforth represent the appended
 * result of the whole inheritance tree.  The members of inheritlist represent
 * the individual tables --- in particular, the inheritlist member that is a
 * duplicate of the parent RTE represents the parent table alone.
 * We will generate plans to scan the individual tables that refer to
 * the inheritlist RTEs, whereas Vars elsewhere in the plan tree that
 * refer to the original RTE are taken to refer to the append output.
 * In particular, this means we have separate RelOptInfos for the parent
 * table and for the append output, which is a good thing because they're
 * not the same size.
 */
static void
set_inherited_rel_pathlist(Query *root, RelOptInfo *rel,
						   Index rti, RangeTblEntry *rte,
						   List *inheritlist)
{
	int			parentRTindex = rti;
	Oid			parentOID = rte->relid;
	List	   *subpaths = NIL;
	List	   *il;

	/*
	 * XXX for now, can't handle inherited expansion of FOR UPDATE; can we
	 * do better?
	 */
	if (intMember(parentRTindex, root->rowMarks))
		elog(ERROR, "SELECT FOR UPDATE is not supported for inherit queries");

	/*
	 * The executor will check the parent table's access permissions when
	 * it examines the parent's inheritlist entry.  There's no need to
	 * check twice, so turn off access check bits in the original RTE.
	 */
	rte->checkForRead = false;
	rte->checkForWrite = false;

	/*
	 * Initialize to compute size estimates for whole inheritance tree
	 */
	rel->rows = 0;
	rel->width = 0;

	/*
	 * Generate access paths for each table in the tree (parent AND
	 * children), and pick the cheapest path for each table.
	 */
	foreach(il, inheritlist)
	{
		int			childRTindex = lfirsti(il);
		RangeTblEntry *childrte;
		Oid			childOID;
		RelOptInfo *childrel;

		childrte = rt_fetch(childRTindex, root->rtable);
		childOID = childrte->relid;

		/*
		 * Make a RelOptInfo for the child so we can do planning.  Do NOT
		 * attach the RelOptInfo to the query's base_rel_list, however,
		 * since the child is not part of the main join tree.  Instead,
		 * the child RelOptInfo is added to other_rel_list.
		 */
		childrel = build_other_rel(root, childRTindex);

		/*
		 * Copy the parent's targetlist and restriction quals to the
		 * child, with attribute-number adjustment as needed.  We don't
		 * bother to copy the join quals, since we can't do any joining of
		 * the individual tables.
		 */
		childrel->targetlist = (List *)
			adjust_inherited_attrs((Node *) rel->targetlist,
								   parentRTindex,
								   parentOID,
								   childRTindex,
								   childOID);
		childrel->baserestrictinfo = (List *)
			adjust_inherited_attrs((Node *) rel->baserestrictinfo,
								   parentRTindex,
								   parentOID,
								   childRTindex,
								   childOID);
		childrel->baserestrictcost = rel->baserestrictcost;

		/*
		 * Now compute child access paths, and save the cheapest.
		 */
		set_plain_rel_pathlist(root, childrel, childrte);

		subpaths = lappend(subpaths, childrel->cheapest_total_path);

		/* Also update total size estimates */
		rel->rows += childrel->rows;
		if (childrel->width > rel->width)
			rel->width = childrel->width;
	}

	/*
	 * Finally, build Append path and install it as the only access path
	 * for the parent rel.
	 */
	add_path(rel, (Path *) create_append_path(rel, subpaths));

	/* Select cheapest path (pretty easy in this case...) */
	set_cheapest(rel);
}

/*
 * set_subquery_pathlist
 *		Build the (single) access path for a subquery RTE
 */
static void
set_subquery_pathlist(Query *root, RelOptInfo *rel,
					  Index rti, RangeTblEntry *rte)
{
	Query	   *subquery = rte->subquery;

	/*
	 * If there are any restriction clauses that have been attached to the
	 * subquery relation, consider pushing them down to become HAVING
	 * quals of the subquery itself.  (Not WHERE clauses, since they may
	 * refer to subquery outputs that are aggregate results.  But
	 * planner.c will transfer them into the subquery's WHERE if they do
	 * not.)  This transformation is useful because it may allow us to
	 * generate a better plan for the subquery than evaluating all the
	 * subquery output rows and then filtering them.
	 *
	 * There are several cases where we cannot push down clauses.
	 * Restrictions involving the subquery are checked by
	 * subquery_is_pushdown_safe().  Also, we do not push down clauses
	 * that contain subselects, mainly because I'm not sure it will work
	 * correctly (the subplan hasn't yet transformed sublinks to
	 * subselects).
	 *
	 * Non-pushed-down clauses will get evaluated as qpquals of the
	 * SubqueryScan node.
	 *
	 * XXX Are there any cases where we want to make a policy decision not to
	 * push down, because it'd result in a worse plan?
	 */
	if (rel->baserestrictinfo != NIL &&
		subquery_is_pushdown_safe(subquery, subquery))
	{
		/* OK to consider pushing down individual quals */
		List	   *upperrestrictlist = NIL;
		List	   *lst;

		foreach(lst, rel->baserestrictinfo)
		{
			RestrictInfo *rinfo = (RestrictInfo *) lfirst(lst);
			Node	   *clause = (Node *) rinfo->clause;

			if (contain_subplans(clause))
			{
				/* Keep it in the upper query */
				upperrestrictlist = lappend(upperrestrictlist, rinfo);
			}
			else
			{
				/* Push it down */
				subquery_push_qual(subquery, rti, clause);
			}
		}
		rel->baserestrictinfo = upperrestrictlist;
	}

	/* Generate the plan for the subquery */
	rel->subplan = subquery_planner(subquery,
									-1.0 /* default case */ );

	/* Copy number of output rows from subplan */
	rel->tuples = rel->subplan->plan_rows;

	/* Mark rel with estimated output rows, width, etc */
	set_baserel_size_estimates(root, rel);

	/* Generate appropriate path */
	add_path(rel, create_subqueryscan_path(rel));

	/* Select cheapest path (pretty easy in this case...) */
	set_cheapest(rel);
}

/*
 * set_function_pathlist
 *		Build the (single) access path for a function RTE
 */
static void
set_function_pathlist(Query *root, RelOptInfo *rel, RangeTblEntry *rte)
{
	/* Mark rel with estimated output rows, width, etc */
	set_function_size_estimates(root, rel);

	/* Generate appropriate path */
	add_path(rel, create_functionscan_path(root, rel));

	/* Select cheapest path (pretty easy in this case...) */
	set_cheapest(rel);
}

/*
 * make_fromexpr_rel
 *	  Build access paths for a FromExpr jointree node.
 */
RelOptInfo *
make_fromexpr_rel(Query *root, FromExpr *from)
{
	int			levels_needed;
	List	   *initial_rels = NIL;
	List	   *jt;

	/*
	 * Count the number of child jointree nodes.  This is the depth of the
	 * dynamic-programming algorithm we must employ to consider all ways
	 * of joining the child nodes.
	 */
	levels_needed = length(from->fromlist);

	if (levels_needed <= 0)
		return NULL;			/* nothing to do? */

	/*
	 * Construct a list of rels corresponding to the child jointree nodes.
	 * This may contain both base rels and rels constructed according to
	 * explicit JOIN directives.
	 */
	foreach(jt, from->fromlist)
	{
		Node	   *jtnode = (Node *) lfirst(jt);

		initial_rels = lappend(initial_rels,
							   make_jointree_rel(root, jtnode));
	}

	if (levels_needed == 1)
	{
		/*
		 * Single jointree node, so we're done.
		 */
		return (RelOptInfo *) lfirst(initial_rels);
	}
	else
	{
		/*
		 * Consider the different orders in which we could join the rels,
		 * using either GEQO or regular optimizer.
		 */
		if (enable_geqo && levels_needed >= geqo_threshold)
			return geqo(root, levels_needed, initial_rels);
		else
			return make_one_rel_by_joins(root, levels_needed, initial_rels);
	}
}

/*
 * make_one_rel_by_joins
 *	  Find all possible joinpaths for a query by successively finding ways
 *	  to join component relations into join relations.
 *
 * 'levels_needed' is the number of iterations needed, ie, the number of
 *		independent jointree items in the query.  This is > 1.
 *
 * 'initial_rels' is a list of RelOptInfo nodes for each independent
 *		jointree item.	These are the components to be joined together.
 *
 * Returns the final level of join relations, i.e., the relation that is
 * the result of joining all the original relations together.
 */
static RelOptInfo *
make_one_rel_by_joins(Query *root, int levels_needed, List *initial_rels)
{
	List	  **joinitems;
	int			lev;
	RelOptInfo *rel;

	/*
	 * We employ a simple "dynamic programming" algorithm: we first find
	 * all ways to build joins of two jointree items, then all ways to
	 * build joins of three items (from two-item joins and single items),
	 * then four-item joins, and so on until we have considered all ways
	 * to join all the items into one rel.
	 *
	 * joinitems[j] is a list of all the j-item rels.  Initially we set
	 * joinitems[1] to represent all the single-jointree-item relations.
	 */
	joinitems = (List **) palloc0((levels_needed + 1) * sizeof(List *));

	joinitems[1] = initial_rels;

	for (lev = 2; lev <= levels_needed; lev++)
	{
		List	   *x;

		/*
		 * Determine all possible pairs of relations to be joined at this
		 * level, and build paths for making each one from every available
		 * pair of lower-level relations.
		 */
		joinitems[lev] = make_rels_by_joins(root, lev, joinitems);

		/*
		 * Do cleanup work on each just-processed rel.
		 */
		foreach(x, joinitems[lev])
		{
			rel = (RelOptInfo *) lfirst(x);

#ifdef NOT_USED

			/*
			 * * for each expensive predicate in each path in each
			 * distinct rel, * consider doing pullup  -- JMH
			 */
			if (XfuncMode != XFUNC_NOPULL && XfuncMode != XFUNC_OFF)
				xfunc_trypullup(rel);
#endif

			/* Find and save the cheapest paths for this rel */
			set_cheapest(rel);

#ifdef OPTIMIZER_DEBUG
			debug_print_rel(root, rel);
#endif
		}
	}

	/*
	 * We should have a single rel at the final level.
	 */
	Assert(length(joinitems[levels_needed]) == 1);

	rel = (RelOptInfo *) lfirst(joinitems[levels_needed]);

	return rel;
}

/*****************************************************************************
 *			PUSHING QUALS DOWN INTO SUBQUERIES
 *****************************************************************************/

/*
 * subquery_is_pushdown_safe - is a subquery safe for pushing down quals?
 *
 * subquery is the particular component query being checked.  topquery
 * is the top component of a set-operations tree (the same Query if no
 * set-op is involved).
 *
 * Conditions checked here:
 *
 * 1. If the subquery has a LIMIT clause or a DISTINCT ON clause, we must
 * not push down any quals, since that could change the set of rows
 * returned.  (Actually, we could push down quals into a DISTINCT ON
 * subquery if they refer only to DISTINCT-ed output columns, but
 * checking that seems more work than it's worth.  In any case, a
 * plain DISTINCT is safe to push down past.)
 *
 * 2. If the subquery has any functions returning sets in its target list,
 * we do not push down any quals, since the quals
 * might refer to those tlist items, which would mean we'd introduce
 * functions-returning-sets into the subquery's WHERE/HAVING quals.
 * (It'd be sufficient to not push down quals that refer to those
 * particular tlist items, but that's much clumsier to check.)
 *
 * 3. If the subquery contains EXCEPT or EXCEPT ALL set ops we cannot push
 * quals into it, because that would change the results.  For subqueries
 * using UNION/UNION ALL/INTERSECT/INTERSECT ALL, we can push the quals
 * into each component query, so long as all the component queries share
 * identical output types.	(That restriction could probably be relaxed,
 * but it would take much more code to include type coercion code into
 * the quals, and I'm also concerned about possible semantic gotchas.)
 */
static bool
subquery_is_pushdown_safe(Query *subquery, Query *topquery)
{
	SetOperationStmt *topop;

	/* Check points 1 and 2 */
	if (subquery->limitOffset != NULL ||
		subquery->limitCount != NULL ||
		has_distinct_on_clause(subquery) ||
		expression_returns_set((Node *) subquery->targetList))
		return false;

	/* Are we at top level, or looking at a setop component? */
	if (subquery == topquery)
	{
		/* Top level, so check any component queries */
		if (subquery->setOperations != NULL)
			if (!recurse_pushdown_safe(subquery->setOperations, topquery))
				return false;
	}
	else
	{
		/* Setop component must not have more components (too weird) */
		if (subquery->setOperations != NULL)
			return false;
		/* Setop component output types must match top level */
		topop = (SetOperationStmt *) topquery->setOperations;
		Assert(topop && IsA(topop, SetOperationStmt));
		if (!tlist_same_datatypes(subquery->targetList,
								  topop->colTypes,
								  true))
			return false;

	}
	return true;
}

/*
 * Helper routine to recurse through setOperations tree
 */
static bool
recurse_pushdown_safe(Node *setOp, Query *topquery)
{
	if (IsA(setOp, RangeTblRef))
	{
		RangeTblRef *rtr = (RangeTblRef *) setOp;
		RangeTblEntry *rte = rt_fetch(rtr->rtindex, topquery->rtable);
		Query	   *subquery = rte->subquery;

		Assert(subquery != NULL);
		return subquery_is_pushdown_safe(subquery, topquery);
	}
	else if (IsA(setOp, SetOperationStmt))
	{
		SetOperationStmt *op = (SetOperationStmt *) setOp;

		/* EXCEPT is no good */
		if (op->op == SETOP_EXCEPT)
			return false;
		/* Else recurse */
		if (!recurse_pushdown_safe(op->larg, topquery))
			return false;
		if (!recurse_pushdown_safe(op->rarg, topquery))
			return false;
	}
	else
	{
		elog(ERROR, "recurse_pushdown_safe: unexpected node %d",
			 (int) nodeTag(setOp));
	}
	return true;
}

/*
 * subquery_push_qual - push down a qual that we have determined is safe
 */
static void
subquery_push_qual(Query *subquery, Index rti, Node *qual)
{
	if (subquery->setOperations != NULL)
	{
		/* Recurse to push it separately to each component query */
		recurse_push_qual(subquery->setOperations, subquery, rti, qual);
	}
	else
	{
		/*
		 * We need to replace Vars in the qual (which must refer to
		 * outputs of the subquery) with copies of the subquery's
		 * targetlist expressions.	Note that at this point, any uplevel
		 * Vars in the qual should have been replaced with Params, so they
		 * need no work.
		 *
		 * This step also ensures that when we are pushing into a setop tree,
		 * each component query gets its own copy of the qual.
		 */
		qual = ResolveNew(qual, rti, 0,
						  subquery->targetList,
						  CMD_SELECT, 0);
		subquery->havingQual = make_and_qual(subquery->havingQual,
											 qual);

		/*
		 * We need not change the subquery's hasAggs or hasSublinks flags,
		 * since we can't be pushing down any aggregates that weren't
		 * there before, and we don't push down subselects at all.
		 */
	}
}

/*
 * Helper routine to recurse through setOperations tree
 */
static void
recurse_push_qual(Node *setOp, Query *topquery,
				  Index rti, Node *qual)
{
	if (IsA(setOp, RangeTblRef))
	{
		RangeTblRef *rtr = (RangeTblRef *) setOp;
		RangeTblEntry *rte = rt_fetch(rtr->rtindex, topquery->rtable);
		Query	   *subquery = rte->subquery;

		Assert(subquery != NULL);
		subquery_push_qual(subquery, rti, qual);
	}
	else if (IsA(setOp, SetOperationStmt))
	{
		SetOperationStmt *op = (SetOperationStmt *) setOp;

		recurse_push_qual(op->larg, topquery, rti, qual);
		recurse_push_qual(op->rarg, topquery, rti, qual);
	}
	else
	{
		elog(ERROR, "recurse_push_qual: unexpected node %d",
			 (int) nodeTag(setOp));
	}
}

/*****************************************************************************
 *			DEBUG SUPPORT
 *****************************************************************************/

#ifdef OPTIMIZER_DEBUG

static void
print_relids(Relids relids)
{
	Relids		tmprelids;
	int			x;
	bool		first = true;

	tmprelids = bms_copy(relids);
	while ((x = bms_first_member(tmprelids)) >= 0)
	{
		if (!first)
			printf(" ");
		printf("%d", x);
		first = false;
	}
	bms_free(tmprelids);
}

static void
print_restrictclauses(Query *root, List *clauses)
{
	List	   *l;

	foreach(l, clauses)
	{
		RestrictInfo *c = lfirst(l);

		print_expr((Node *) c->clause, root->rtable);
		if (lnext(l))
			printf(", ");
	}
}

static void
print_path(Query *root, Path *path, int indent)
{
	const char *ptype;
	bool		join = false;
	Path	   *subpath = NULL;
	int			i;

	switch (nodeTag(path))
	{
		case T_Path:
			ptype = "SeqScan";
			break;
		case T_IndexPath:
			ptype = "IdxScan";
			break;
		case T_TidPath:
			ptype = "TidScan";
			break;
		case T_AppendPath:
			ptype = "Append";
			break;
		case T_ResultPath:
			ptype = "Result";
			subpath = ((ResultPath *) path)->subpath;
			break;
		case T_MaterialPath:
			ptype = "Material";
			subpath = ((MaterialPath *) path)->subpath;
			break;
		case T_UniquePath:
			ptype = "Unique";
			subpath = ((UniquePath *) path)->subpath;
			break;
		case T_NestPath:
			ptype = "NestLoop";
			join = true;
			break;
		case T_MergePath:
			ptype = "MergeJoin";
			join = true;
			break;
		case T_HashPath:
			ptype = "HashJoin";
			join = true;
			break;
		default:
			ptype = "???Path";
			break;
	}

	for (i = 0; i < indent; i++)
		printf("\t");
	printf("%s", ptype);

	if (path->parent)
	{
		printf("(");
		print_relids(path->parent->relids);
		printf(") rows=%.0f", path->parent->rows);
	}
	printf(" cost=%.2f..%.2f\n", path->startup_cost, path->total_cost);

	if (path->pathkeys)
	{
		for (i = 0; i < indent; i++)
			printf("\t");
		printf("  pathkeys: ");
		print_pathkeys(path->pathkeys, root->rtable);
	}

	if (join)
	{
		JoinPath   *jp = (JoinPath *) path;

		for (i = 0; i < indent; i++)
			printf("\t");
		printf("  clauses: ");
		print_restrictclauses(root, jp->joinrestrictinfo);
		printf("\n");

		if (IsA(path, MergePath))
		{
			MergePath  *mp = (MergePath *) path;

			if (mp->outersortkeys || mp->innersortkeys)
			{
				for (i = 0; i < indent; i++)
					printf("\t");
				printf("  sortouter=%d sortinner=%d\n",
					   ((mp->outersortkeys) ? 1 : 0),
					   ((mp->innersortkeys) ? 1 : 0));
			}
		}

		print_path(root, jp->outerjoinpath, indent + 1);
		print_path(root, jp->innerjoinpath, indent + 1);
	}

	if (subpath)
		print_path(root, subpath, indent + 1);
}

void
debug_print_rel(Query *root, RelOptInfo *rel)
{
	List	   *l;

	printf("RELOPTINFO (");
	print_relids(rel->relids);
	printf("): rows=%.0f width=%d\n", rel->rows, rel->width);

	if (rel->baserestrictinfo)
	{
		printf("\tbaserestrictinfo: ");
		print_restrictclauses(root, rel->baserestrictinfo);
		printf("\n");
	}

	foreach(l, rel->joininfo)
	{
		JoinInfo   *j = (JoinInfo *) lfirst(l);

		printf("\tjoininfo (");
		print_relids(j->unjoined_relids);
		printf("): ");
		print_restrictclauses(root, j->jinfo_restrictinfo);
		printf("\n");
	}

	printf("\tpath list:\n");
	foreach(l, rel->pathlist)
		print_path(root, lfirst(l), 1);
	printf("\n\tcheapest startup path:\n");
	print_path(root, rel->cheapest_startup_path, 1);
	printf("\n\tcheapest total path:\n");
	print_path(root, rel->cheapest_total_path, 1);
	printf("\n");
	fflush(stdout);
}

#endif   /* OPTIMIZER_DEBUG */