prepunion.c

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/*-------------------------------------------------------------------------
 *
 * prepunion.c
 *    Routines to plan set-operation queries.  The filename is a leftover
 *    from a time when only UNIONs were implemented.
 *
 * There are two code paths in the planner for set-operation queries.
 * If a subquery consists entirely of simple UNION ALL operations, it
 * is converted into an "append relation".  Otherwise, it is handled
 * by the general code in this module (plan_set_operations and its
 * subroutines).  There is some support code here for the append-relation
 * case, but most of the heavy lifting for that is done elsewhere,
 * notably in prepjointree.c and allpaths.c.
 *
 * There is also some code here to support planning of queries that use
 * inheritance (SELECT FROM foo*).  Inheritance trees are converted into
 * append relations, and thenceforth share code with the UNION ALL case.
 *
 *
 * Portions Copyright (c) 1996-2018, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *    src/backend/optimizer/prep/prepunion.c
 *
 *-------------------------------------------------------------------------
 */
#include "postgres.h"

#include <limits.h>

#include "access/heapam.h"
#include "access/htup_details.h"
#include "access/sysattr.h"
#include "catalog/partition.h"
#include "catalog/pg_inherits.h"
#include "catalog/pg_type.h"
#include "miscadmin.h"
#include "nodes/makefuncs.h"
#include "nodes/nodeFuncs.h"
#include "optimizer/cost.h"
#include "optimizer/pathnode.h"
#include "optimizer/paths.h"
#include "optimizer/planmain.h"
#include "optimizer/planner.h"
#include "optimizer/prep.h"
#include "optimizer/tlist.h"
#include "parser/parse_coerce.h"
#include "parser/parsetree.h"
#include "utils/lsyscache.h"
#include "utils/rel.h"
#include "utils/selfuncs.h"


typedef struct
{
    PlannerInfo *root;
    int         nappinfos;
    AppendRelInfo **appinfos;
} adjust_appendrel_attrs_context;

static RelOptInfo *recurse_set_operations(Node *setOp, PlannerInfo *root,
                       List *colTypes, List *colCollations,
                       bool junkOK,
                       int flag, List *refnames_tlist,
                       List **pTargetList,
                       double *pNumGroups);
static RelOptInfo *generate_recursion_path(SetOperationStmt *setOp,
                        PlannerInfo *root,
                        List *refnames_tlist,
                        List **pTargetList);
static RelOptInfo *generate_union_paths(SetOperationStmt *op, PlannerInfo *root,
                     List *refnames_tlist,
                     List **pTargetList);
static RelOptInfo *generate_nonunion_paths(SetOperationStmt *op, PlannerInfo *root,
                        List *refnames_tlist,
                        List **pTargetList);
static List *plan_union_children(PlannerInfo *root,
                    SetOperationStmt *top_union,
                    List *refnames_tlist,
                    List **tlist_list);
static Path *make_union_unique(SetOperationStmt *op, Path *path, List *tlist,
                  PlannerInfo *root);
static void postprocess_setop_rel(PlannerInfo *root, RelOptInfo *rel);
static bool choose_hashed_setop(PlannerInfo *root, List *groupClauses,
                    Path *input_path,
                    double dNumGroups, double dNumOutputRows,
                    const char *construct);
static List *generate_setop_tlist(List *colTypes, List *colCollations,
                     int flag,
                     Index varno,
                     bool hack_constants,
                     List *input_tlist,
                     List *refnames_tlist);
static List *generate_append_tlist(List *colTypes, List *colCollations,
                      bool flag,
                      List *input_tlists,
                      List *refnames_tlist);
static List *generate_setop_grouplist(SetOperationStmt *op, List *targetlist);
static void expand_inherited_rtentry(PlannerInfo *root, RangeTblEntry *rte,
                         Index rti);
static void expand_partitioned_rtentry(PlannerInfo *root,
                           RangeTblEntry *parentrte,
                           Index parentRTindex, Relation parentrel,
                           PlanRowMark *top_parentrc, LOCKMODE lockmode,
                           List **appinfos);
static void expand_single_inheritance_child(PlannerInfo *root,
                                RangeTblEntry *parentrte,
                                Index parentRTindex, Relation parentrel,
                                PlanRowMark *top_parentrc, Relation childrel,
                                List **appinfos, RangeTblEntry **childrte_p,
                                Index *childRTindex_p);
static void make_inh_translation_list(Relation oldrelation,
                          Relation newrelation,
                          Index newvarno,
                          List **translated_vars);
static Bitmapset *translate_col_privs(const Bitmapset *parent_privs,
                    List *translated_vars);
static Node *adjust_appendrel_attrs_mutator(Node *node,
                               adjust_appendrel_attrs_context *context);
static Relids adjust_child_relids(Relids relids, int nappinfos,
                    AppendRelInfo **appinfos);
static List *adjust_inherited_tlist(List *tlist,
                       AppendRelInfo *context);


/*
 * plan_set_operations
 *
 *    Plans the queries for a tree of set operations (UNION/INTERSECT/EXCEPT)
 *
 * This routine only deals with the setOperations tree of the given query.
 * Any top-level ORDER BY requested in root->parse->sortClause will be handled
 * when we return to grouping_planner; likewise for LIMIT.
 *
 * What we return is an "upperrel" RelOptInfo containing at least one Path
 * that implements the set-operation tree.  In addition, root->processed_tlist
 * receives a targetlist representing the output of the topmost setop node.
 */
RelOptInfo *
plan_set_operations(PlannerInfo *root)
{
    Query      *parse = root->parse;
    SetOperationStmt *topop = castNode(SetOperationStmt, parse->setOperations);
    Node       *node;
    RangeTblEntry *leftmostRTE;
    Query      *leftmostQuery;
    RelOptInfo *setop_rel;
    List       *top_tlist;

    Assert(topop);

    /* check for unsupported stuff */
    Assert(parse->jointree->fromlist == NIL);
    Assert(parse->jointree->quals == NULL);
    Assert(parse->groupClause == NIL);
    Assert(parse->havingQual == NULL);
    Assert(parse->windowClause == NIL);
    Assert(parse->distinctClause == NIL);

    /*
     * We'll need to build RelOptInfos for each of the leaf subqueries, which
     * are RTE_SUBQUERY rangetable entries in this Query.  Prepare the index
     * arrays for that.
     */
    setup_simple_rel_arrays(root);

    /*
     * Find the leftmost component Query.  We need to use its column names for
     * all generated tlists (else SELECT INTO won't work right).
     */
    node = topop->larg;
    while (node && IsA(node, SetOperationStmt))
        node = ((SetOperationStmt *) node)->larg;
    Assert(node && IsA(node, RangeTblRef));
    leftmostRTE = root->simple_rte_array[((RangeTblRef *) node)->rtindex];
    leftmostQuery = leftmostRTE->subquery;
    Assert(leftmostQuery != NULL);

    /*
     * If the topmost node is a recursive union, it needs special processing.
     */
    if (root->hasRecursion)
    {
        setop_rel = generate_recursion_path(topop, root,
                                            leftmostQuery->targetList,
                                            &top_tlist);
    }
    else
    {
        /*
         * Recurse on setOperations tree to generate paths for set ops. The
         * final output paths should have just the column types shown as the
         * output from the top-level node, plus possibly resjunk working
         * columns (we can rely on upper-level nodes to deal with that).
         */
        setop_rel = recurse_set_operations((Node *) topop, root,
                                           topop->colTypes, topop->colCollations,
                                           true, -1,
                                           leftmostQuery->targetList,
                                           &top_tlist,
                                           NULL);
    }

    /* Must return the built tlist into root->processed_tlist. */
    root->processed_tlist = top_tlist;

    return setop_rel;
}

/*
 * recurse_set_operations
 *    Recursively handle one step in a tree of set operations
 *
 * colTypes: OID list of set-op's result column datatypes
 * colCollations: OID list of set-op's result column collations
 * junkOK: if true, child resjunk columns may be left in the result
 * flag: if >= 0, add a resjunk output column indicating value of flag
 * refnames_tlist: targetlist to take column names from
 *
 * Returns a RelOptInfo for the subtree, as well as these output parameters:
 * *pTargetList: receives the fully-fledged tlist for the subtree's top plan
 * *pNumGroups: if not NULL, we estimate the number of distinct groups
 *      in the result, and store it there
 *
 * The pTargetList output parameter is mostly redundant with the pathtarget
 * of the returned RelOptInfo, but for the moment we need it because much of
 * the logic in this file depends on flag columns being marked resjunk.
 * Pending a redesign of how that works, this is the easy way out.
 *
 * We don't have to care about typmods here: the only allowed difference
 * between set-op input and output typmods is input is a specific typmod
 * and output is -1, and that does not require a coercion.
 */
static RelOptInfo *
recurse_set_operations(Node *setOp, PlannerInfo *root,
                       List *colTypes, List *colCollations,
                       bool junkOK,
                       int flag, List *refnames_tlist,
                       List **pTargetList,
                       double *pNumGroups)
{
    RelOptInfo *rel = NULL;     /* keep compiler quiet */

    /* Guard against stack overflow due to overly complex setop nests */
    check_stack_depth();

    if (IsA(setOp, RangeTblRef))
    {
        RangeTblRef *rtr = (RangeTblRef *) setOp;
        RangeTblEntry *rte = root->simple_rte_array[rtr->rtindex];
        Query      *subquery = rte->subquery;
        PlannerInfo *subroot;
        RelOptInfo *final_rel;
        Path       *subpath;
        Path       *path;
        List       *tlist;

        Assert(subquery != NULL);

        /* Build a RelOptInfo for this leaf subquery. */
        rel = build_simple_rel(root, rtr->rtindex, NULL);

        /* plan_params should not be in use in current query level */
        Assert(root->plan_params == NIL);

        /* Generate a subroot and Paths for the subquery */
        subroot = rel->subroot = subquery_planner(root->glob, subquery,
                                                  root,
                                                  false,
                                                  root->tuple_fraction);

        /*
         * It should not be possible for the primitive query to contain any
         * cross-references to other primitive queries in the setop tree.
         */
        if (root->plan_params)
            elog(ERROR, "unexpected outer reference in set operation subquery");

        /* Figure out the appropriate target list for this subquery. */
        tlist = generate_setop_tlist(colTypes, colCollations,
                                     flag,
                                     rtr->rtindex,
                                     true,
                                     subroot->processed_tlist,
                                     refnames_tlist);
        rel->reltarget = create_pathtarget(root, tlist);

        /* Return the fully-fledged tlist to caller, too */
        *pTargetList = tlist;

        /*
         * Mark rel with estimated output rows, width, etc.  Note that we have
         * to do this before generating outer-query paths, else
         * cost_subqueryscan is not happy.
         */
        set_subquery_size_estimates(root, rel);

        /*
         * Since we may want to add a partial path to this relation, we must
         * set its consider_parallel flag correctly.
         */
        final_rel = fetch_upper_rel(subroot, UPPERREL_FINAL, NULL);
        rel->consider_parallel = final_rel->consider_parallel;

        /*
         * For the moment, we consider only a single Path for the subquery.
         * This should change soon (make it look more like
         * set_subquery_pathlist).
         */
        subpath = get_cheapest_fractional_path(final_rel,
                                               root->tuple_fraction);

        /*
         * Stick a SubqueryScanPath atop that.
         *
         * We don't bother to determine the subquery's output ordering since
         * it won't be reflected in the set-op result anyhow; so just label
         * the SubqueryScanPath with nil pathkeys.  (XXX that should change
         * soon too, likely.)
         */
        path = (Path *) create_subqueryscan_path(root, rel, subpath,
                                                 NIL, NULL);

        add_path(rel, path);

        /*
         * If we have a partial path for the child relation, we can use that
         * to build a partial path for this relation.  But there's no point in
         * considering any path but the cheapest.
         */
        if (rel->consider_parallel && bms_is_empty(rel->lateral_relids) &&
            final_rel->partial_pathlist != NIL)
        {
            Path       *partial_subpath;
            Path       *partial_path;

            partial_subpath = linitial(final_rel->partial_pathlist);
            partial_path = (Path *)
                create_subqueryscan_path(root, rel, partial_subpath,
                                         NIL, NULL);
            add_partial_path(rel, partial_path);
        }

        /*
         * Estimate number of groups if caller wants it.  If the subquery used
         * grouping or aggregation, its output is probably mostly unique
         * anyway; otherwise do statistical estimation.
         *
         * XXX you don't really want to know about this: we do the estimation
         * using the subquery's original targetlist expressions, not the
         * subroot->processed_tlist which might seem more appropriate.  The
         * reason is that if the subquery is itself a setop, it may return a
         * processed_tlist containing "varno 0" Vars generated by
         * generate_append_tlist, and those would confuse estimate_num_groups
         * mightily.  We ought to get rid of the "varno 0" hack, but that
         * requires a redesign of the parsetree representation of setops, so
         * that there can be an RTE corresponding to each setop's output.
         */
        if (pNumGroups)
        {
            if (subquery->groupClause || subquery->groupingSets ||
                subquery->distinctClause ||
                subroot->hasHavingQual || subquery->hasAggs)
                *pNumGroups = subpath->rows;
            else
                *pNumGroups = estimate_num_groups(subroot,
                                                  get_tlist_exprs(subquery->targetList, false),
                                                  subpath->rows,
                                                  NULL);
        }
    }
    else if (IsA(setOp, SetOperationStmt))
    {
        SetOperationStmt *op = (SetOperationStmt *) setOp;

        /* UNIONs are much different from INTERSECT/EXCEPT */
        if (op->op == SETOP_UNION)
            rel = generate_union_paths(op, root,
                                       refnames_tlist,
                                       pTargetList);
        else
            rel = generate_nonunion_paths(op, root,
                                          refnames_tlist,
                                          pTargetList);
        if (pNumGroups)
            *pNumGroups = rel->rows;

        /*
         * If necessary, add a Result node to project the caller-requested
         * output columns.
         *
         * XXX you don't really want to know about this: setrefs.c will apply
         * fix_upper_expr() to the Result node's tlist. This would fail if the
         * Vars generated by generate_setop_tlist() were not exactly equal()
         * to the corresponding tlist entries of the subplan. However, since
         * the subplan was generated by generate_union_plan() or
         * generate_nonunion_plan(), and hence its tlist was generated by
         * generate_append_tlist(), this will work.  We just tell
         * generate_setop_tlist() to use varno 0.
         */
        if (flag >= 0 ||
            !tlist_same_datatypes(*pTargetList, colTypes, junkOK) ||
            !tlist_same_collations(*pTargetList, colCollations, junkOK))
        {
            PathTarget *target;
            ListCell   *lc;

            *pTargetList = generate_setop_tlist(colTypes, colCollations,
                                                flag,
                                                0,
                                                false,
                                                *pTargetList,
                                                refnames_tlist);
            target = create_pathtarget(root, *pTargetList);

            /* Apply projection to each path */
            foreach(lc, rel->pathlist)
            {
                Path       *subpath = (Path *) lfirst(lc);
                Path       *path;

                Assert(subpath->param_info == NULL);
                path = apply_projection_to_path(root, subpath->parent,
                                                subpath, target);
                /* If we had to add a Result, path is different from subpath */
                if (path != subpath)
                    lfirst(lc) = path;
            }

            /* Apply projection to each partial path */
            foreach(lc, rel->partial_pathlist)
            {
                Path       *subpath = (Path *) lfirst(lc);
                Path       *path;

                Assert(subpath->param_info == NULL);

                /* avoid apply_projection_to_path, in case of multiple refs */
                path = (Path *) create_projection_path(root, subpath->parent,
                                                       subpath, target);
                lfirst(lc) = path;
            }
        }
    }
    else
    {
        elog(ERROR, "unrecognized node type: %d",
             (int) nodeTag(setOp));
        *pTargetList = NIL;
    }

    postprocess_setop_rel(root, rel);

    return rel;
}

/*
 * Generate paths for a recursive UNION node
 */
static RelOptInfo *
generate_recursion_path(SetOperationStmt *setOp, PlannerInfo *root,
                        List *refnames_tlist,
                        List **pTargetList)
{
    RelOptInfo *result_rel;
    Path       *path;
    RelOptInfo *lrel,
               *rrel;
    Path       *lpath;
    Path       *rpath;
    List       *lpath_tlist;
    List       *rpath_tlist;
    List       *tlist;
    List       *groupList;
    double      dNumGroups;

    /* Parser should have rejected other cases */
    if (setOp->op != SETOP_UNION)
        elog(ERROR, "only UNION queries can be recursive");
    /* Worktable ID should be assigned */
    Assert(root->wt_param_id >= 0);

    /*
     * Unlike a regular UNION node, process the left and right inputs
     * separately without any intention of combining them into one Append.
     */
    lrel = recurse_set_operations(setOp->larg, root,
                                  setOp->colTypes, setOp->colCollations,
                                  false, -1,
                                  refnames_tlist,
                                  &lpath_tlist,
                                  NULL);
    lpath = lrel->cheapest_total_path;
    /* The right path will want to look at the left one ... */
    root->non_recursive_path = lpath;
    rrel = recurse_set_operations(setOp->rarg, root,
                                  setOp->colTypes, setOp->colCollations,
                                  false, -1,
                                  refnames_tlist,
                                  &rpath_tlist,
                                  NULL);
    rpath = rrel->cheapest_total_path;
    root->non_recursive_path = NULL;

    /*
     * Generate tlist for RecursiveUnion path node --- same as in Append cases
     */
    tlist = generate_append_tlist(setOp->colTypes, setOp->colCollations, false,
                                  list_make2(lpath_tlist, rpath_tlist),
                                  refnames_tlist);

    *pTargetList = tlist;

    /* Build result relation. */
    result_rel = fetch_upper_rel(root, UPPERREL_SETOP,
                                 bms_union(lrel->relids, rrel->relids));
    result_rel->reltarget = create_pathtarget(root, tlist);

    /*
     * If UNION, identify the grouping operators
     */
    if (setOp->all)
    {
        groupList = NIL;
        dNumGroups = 0;
    }
    else
    {
        /* Identify the grouping semantics */
        groupList = generate_setop_grouplist(setOp, tlist);

        /* We only support hashing here */
        if (!grouping_is_hashable(groupList))
            ereport(ERROR,
                    (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                     errmsg("could not implement recursive UNION"),
                     errdetail("All column datatypes must be hashable.")));

        /*
         * For the moment, take the number of distinct groups as equal to the
         * total input size, ie, the worst case.
         */
        dNumGroups = lpath->rows + rpath->rows * 10;
    }

    /*
     * And make the path node.
     */
    path = (Path *) create_recursiveunion_path(root,
                                               result_rel,
                                               lpath,
                                               rpath,
                                               result_rel->reltarget,
                                               groupList,
                                               root->wt_param_id,
                                               dNumGroups);

    add_path(result_rel, path);
    postprocess_setop_rel(root, result_rel);
    return result_rel;
}

/*
 * Generate paths for a UNION or UNION ALL node
 */
static RelOptInfo *
generate_union_paths(SetOperationStmt *op, PlannerInfo *root,
                     List *refnames_tlist,
                     List **pTargetList)
{
    Relids      relids = NULL;
    RelOptInfo *result_rel;
    double      save_fraction = root->tuple_fraction;
    ListCell   *lc;
    List       *pathlist = NIL;
    List       *partial_pathlist = NIL;
    bool        partial_paths_valid = true;
    bool        consider_parallel = true;
    List       *rellist;
    List       *tlist_list;
    List       *tlist;
    Path       *path;

    /*
     * If plain UNION, tell children to fetch all tuples.
     *
     * Note: in UNION ALL, we pass the top-level tuple_fraction unmodified to
     * each arm of the UNION ALL.  One could make a case for reducing the
     * tuple fraction for later arms (discounting by the expected size of the
     * earlier arms' results) but it seems not worth the trouble. The normal
     * case where tuple_fraction isn't already zero is a LIMIT at top level,
     * and passing it down as-is is usually enough to get the desired result
     * of preferring fast-start plans.
     */
    if (!op->all)
        root->tuple_fraction = 0.0;

    /*
     * If any of my children are identical UNION nodes (same op, all-flag, and
     * colTypes) then they can be merged into this node so that we generate
     * only one Append and unique-ification for the lot.  Recurse to find such
     * nodes and compute their children's paths.
     */
    rellist = plan_union_children(root, op, refnames_tlist, &tlist_list);

    /*
     * Generate tlist for Append plan node.
     *
     * The tlist for an Append plan isn't important as far as the Append is
     * concerned, but we must make it look real anyway for the benefit of the
     * next plan level up.
     */
    tlist = generate_append_tlist(op->colTypes, op->colCollations, false,
                                  tlist_list, refnames_tlist);

    *pTargetList = tlist;

    /* Build path lists and relid set. */
    foreach(lc, rellist)
    {
        RelOptInfo *rel = lfirst(lc);

        pathlist = lappend(pathlist, rel->cheapest_total_path);

        if (consider_parallel)
        {
            if (!rel->consider_parallel)
            {
                consider_parallel = false;
                partial_paths_valid = false;
            }
            else if (rel->partial_pathlist == NIL)
                partial_paths_valid = false;
            else
                partial_pathlist = lappend(partial_pathlist,
                                           linitial(rel->partial_pathlist));
        }

        relids = bms_union(relids, rel->relids);
    }

    /* Build result relation. */
    result_rel = fetch_upper_rel(root, UPPERREL_SETOP, relids);
    result_rel->reltarget = create_pathtarget(root, tlist);
    result_rel->consider_parallel = consider_parallel;

    /*
     * Append the child results together.
     */
    path = (Path *) create_append_path(root, result_rel, pathlist, NIL,
                                       NULL, 0, false, NIL, -1);

    /*
     * For UNION ALL, we just need the Append path.  For UNION, need to add
     * node(s) to remove duplicates.
     */
    if (!op->all)
        path = make_union_unique(op, path, tlist, root);

    add_path(result_rel, path);

    /*
     * Estimate number of groups.  For now we just assume the output is unique
     * --- this is certainly true for the UNION case, and we want worst-case
     * estimates anyway.
     */
    result_rel->rows = path->rows;

    /*
     * Now consider doing the same thing using the partial paths plus Append
     * plus Gather.
     */
    if (partial_paths_valid)
    {
        Path       *ppath;
        ListCell   *lc;
        int         parallel_workers = 0;

        /* Find the highest number of workers requested for any subpath. */
        foreach(lc, partial_pathlist)
        {
            Path       *path = lfirst(lc);

            parallel_workers = Max(parallel_workers, path->parallel_workers);
        }
        Assert(parallel_workers > 0);

        /*
         * If the use of parallel append is permitted, always request at least
         * log2(# of children) paths.  We assume it can be useful to have
         * extra workers in this case because they will be spread out across
         * the children.  The precise formula is just a guess; see
         * add_paths_to_append_rel.
         */
        if (enable_parallel_append)
        {
            parallel_workers = Max(parallel_workers,
                                   fls(list_length(partial_pathlist)));
            parallel_workers = Min(parallel_workers,
                                   max_parallel_workers_per_gather);
        }
        Assert(parallel_workers > 0);

        ppath = (Path *)
            create_append_path(root, result_rel, NIL, partial_pathlist,
                               NULL, parallel_workers, enable_parallel_append,
                               NIL, -1);
        ppath = (Path *)
            create_gather_path(root, result_rel, ppath,
                               result_rel->reltarget, NULL, NULL);
        if (!op->all)
            ppath = make_union_unique(op, ppath, tlist, root);
        add_path(result_rel, ppath);
    }

    /* Undo effects of possibly forcing tuple_fraction to 0 */
    root->tuple_fraction = save_fraction;

    return result_rel;
}

/*
 * Generate paths for an INTERSECT, INTERSECT ALL, EXCEPT, or EXCEPT ALL node
 */
static RelOptInfo *
generate_nonunion_paths(SetOperationStmt *op, PlannerInfo *root,
                        List *refnames_tlist,
                        List **pTargetList)
{
    RelOptInfo *result_rel;
    RelOptInfo *lrel,
               *rrel;
    double      save_fraction = root->tuple_fraction;
    Path       *lpath,
               *rpath,
               *path;
    List       *lpath_tlist,
               *rpath_tlist,
               *tlist_list,
               *tlist,
               *groupList,
               *pathlist;
    double      dLeftGroups,
                dRightGroups,
                dNumGroups,
                dNumOutputRows;
    bool        use_hash;
    SetOpCmd    cmd;
    int         firstFlag;

    /*
     * Tell children to fetch all tuples.
     */
    root->tuple_fraction = 0.0;

    /* Recurse on children, ensuring their outputs are marked */
    lrel = recurse_set_operations(op->larg, root,
                                  op->colTypes, op->colCollations,
                                  false, 0,
                                  refnames_tlist,
                                  &lpath_tlist,
                                  &dLeftGroups);
    lpath = lrel->cheapest_total_path;
    rrel = recurse_set_operations(op->rarg, root,
                                  op->colTypes, op->colCollations,
                                  false, 1,
                                  refnames_tlist,
                                  &rpath_tlist,
                                  &dRightGroups);
    rpath = rrel->cheapest_total_path;

    /* Undo effects of forcing tuple_fraction to 0 */
    root->tuple_fraction = save_fraction;

    /*
     * For EXCEPT, we must put the left input first.  For INTERSECT, either
     * order should give the same results, and we prefer to put the smaller
     * input first in order to minimize the size of the hash table in the
     * hashing case.  "Smaller" means the one with the fewer groups.
     */
    if (op->op == SETOP_EXCEPT || dLeftGroups <= dRightGroups)
    {
        pathlist = list_make2(lpath, rpath);
        tlist_list = list_make2(lpath_tlist, rpath_tlist);
        firstFlag = 0;
    }
    else
    {
        pathlist = list_make2(rpath, lpath);
        tlist_list = list_make2(rpath_tlist, lpath_tlist);
        firstFlag = 1;
    }

    /*
     * Generate tlist for Append plan node.
     *
     * The tlist for an Append plan isn't important as far as the Append is
     * concerned, but we must make it look real anyway for the benefit of the
     * next plan level up.  In fact, it has to be real enough that the flag
     * column is shown as a variable not a constant, else setrefs.c will get
     * confused.
     */
    tlist = generate_append_tlist(op->colTypes, op->colCollations, true,
                                  tlist_list, refnames_tlist);

    *pTargetList = tlist;

    /* Build result relation. */
    result_rel = fetch_upper_rel(root, UPPERREL_SETOP,
                                 bms_union(lrel->relids, rrel->relids));
    result_rel->reltarget = create_pathtarget(root, tlist);;

    /*
     * Append the child results together.
     */
    path = (Path *) create_append_path(root, result_rel, pathlist, NIL,
                                       NULL, 0, false, NIL, -1);

    /* Identify the grouping semantics */
    groupList = generate_setop_grouplist(op, tlist);

    /*
     * Estimate number of distinct groups that we'll need hashtable entries
     * for; this is the size of the left-hand input for EXCEPT, or the smaller
     * input for INTERSECT.  Also estimate the number of eventual output rows.
     * In non-ALL cases, we estimate each group produces one output row; in
     * ALL cases use the relevant relation size.  These are worst-case
     * estimates, of course, but we need to be conservative.
     */
    if (op->op == SETOP_EXCEPT)
    {
        dNumGroups = dLeftGroups;
        dNumOutputRows = op->all ? lpath->rows : dNumGroups;
    }
    else
    {
        dNumGroups = Min(dLeftGroups, dRightGroups);
        dNumOutputRows = op->all ? Min(lpath->rows, rpath->rows) : dNumGroups;
    }

    /*
     * Decide whether to hash or sort, and add a sort node if needed.
     */
    use_hash = choose_hashed_setop(root, groupList, path,
                                   dNumGroups, dNumOutputRows,
                                   (op->op == SETOP_INTERSECT) ? "INTERSECT" : "EXCEPT");

    if (groupList && !use_hash)
        path = (Path *) create_sort_path(root,
                                         result_rel,
                                         path,
                                         make_pathkeys_for_sortclauses(root,
                                                                       groupList,
                                                                       tlist),
                                         -1.0);

    /*
     * Finally, add a SetOp path node to generate the correct output.
     */
    switch (op->op)
    {
        case SETOP_INTERSECT:
            cmd = op->all ? SETOPCMD_INTERSECT_ALL : SETOPCMD_INTERSECT;
            break;
        case SETOP_EXCEPT:
            cmd = op->all ? SETOPCMD_EXCEPT_ALL : SETOPCMD_EXCEPT;
            break;
        default:
            elog(ERROR, "unrecognized set op: %d", (int) op->op);
            cmd = SETOPCMD_INTERSECT;   /* keep compiler quiet */
            break;
    }
    path = (Path *) create_setop_path(root,
                                      result_rel,
                                      path,
                                      cmd,
                                      use_hash ? SETOP_HASHED : SETOP_SORTED,
                                      groupList,
                                      list_length(op->colTypes) + 1,
                                      use_hash ? firstFlag : -1,
                                      dNumGroups,
                                      dNumOutputRows);

    result_rel->rows = path->rows;
    add_path(result_rel, path);
    return result_rel;
}

/*
 * Pull up children of a UNION node that are identically-propertied UNIONs.
 *
 * NOTE: we can also pull a UNION ALL up into a UNION, since the distinct
 * output rows will be lost anyway.
 *
 * NOTE: currently, we ignore collations while determining if a child has
 * the same properties.  This is semantically sound only so long as all
 * collations have the same notion of equality.  It is valid from an
 * implementation standpoint because we don't care about the ordering of
 * a UNION child's result: UNION ALL results are always unordered, and
 * generate_union_paths will force a fresh sort if the top level is a UNION.
 */
static List *
plan_union_children(PlannerInfo *root,
                    SetOperationStmt *top_union,
                    List *refnames_tlist,
                    List **tlist_list)
{
    List       *pending_rels = list_make1(top_union);
    List       *result = NIL;
    List       *child_tlist;

    *tlist_list = NIL;

    while (pending_rels != NIL)
    {
        Node       *setOp = linitial(pending_rels);

        pending_rels = list_delete_first(pending_rels);

        if (IsA(setOp, SetOperationStmt))
        {
            SetOperationStmt *op = (SetOperationStmt *) setOp;

            if (op->op == top_union->op &&
                (op->all == top_union->all || op->all) &&
                equal(op->colTypes, top_union->colTypes))
            {
                /* Same UNION, so fold children into parent */
                pending_rels = lcons(op->rarg, pending_rels);
                pending_rels = lcons(op->larg, pending_rels);
                continue;
            }
        }

        /*
         * Not same, so plan this child separately.
         *
         * Note we disallow any resjunk columns in child results.  This is
         * necessary since the Append node that implements the union won't do
         * any projection, and upper levels will get confused if some of our
         * output tuples have junk and some don't.  This case only arises when
         * we have an EXCEPT or INTERSECT as child, else there won't be
         * resjunk anyway.
         */
        result = lappend(result, recurse_set_operations(setOp, root,
                                                        top_union->colTypes,
                                                        top_union->colCollations,
                                                        false, -1,
                                                        refnames_tlist,
                                                        &child_tlist,
                                                        NULL));
        *tlist_list = lappend(*tlist_list, child_tlist);
    }

    return result;
}

/*
 * Add nodes to the given path tree to unique-ify the result of a UNION.
 */
static Path *
make_union_unique(SetOperationStmt *op, Path *path, List *tlist,
                  PlannerInfo *root)
{
    RelOptInfo *result_rel = fetch_upper_rel(root, UPPERREL_SETOP, NULL);
    List       *groupList;
    double      dNumGroups;

    /* Identify the grouping semantics */
    groupList = generate_setop_grouplist(op, tlist);

    /*
     * XXX for the moment, take the number of distinct groups as equal to the
     * total input size, ie, the worst case.  This is too conservative, but we
     * don't want to risk having the hashtable overrun memory; also, it's not
     * clear how to get a decent estimate of the true size.  One should note
     * as well the propensity of novices to write UNION rather than UNION ALL
     * even when they don't expect any duplicates...
     */
    dNumGroups = path->rows;

    /* Decide whether to hash or sort */
    if (choose_hashed_setop(root, groupList, path,
                            dNumGroups, dNumGroups,
                            "UNION"))
    {
        /* Hashed aggregate plan --- no sort needed */
        path = (Path *) create_agg_path(root,
                                        result_rel,
                                        path,
                                        create_pathtarget(root, tlist),
                                        AGG_HASHED,
                                        AGGSPLIT_SIMPLE,
                                        groupList,
                                        NIL,
                                        NULL,
                                        dNumGroups);
    }
    else
    {
        /* Sort and Unique */
        if (groupList)
            path = (Path *)
                create_sort_path(root,
                                 result_rel,
                                 path,
                                 make_pathkeys_for_sortclauses(root,
                                                               groupList,
                                                               tlist),
                                 -1.0);
        path = (Path *) create_upper_unique_path(root,
                                                 result_rel,
                                                 path,
                                                 list_length(path->pathkeys),
                                                 dNumGroups);
    }

    return path;
}

/*
 * postprocess_setop_rel - perform steps required after adding paths
 */
static void
postprocess_setop_rel(PlannerInfo *root, RelOptInfo *rel)
{
    /*
     * We don't currently worry about allowing FDWs to contribute paths to
     * this relation, but give extensions a chance.
     */
    if (create_upper_paths_hook)
        (*create_upper_paths_hook) (root, UPPERREL_SETOP,
                                    NULL, rel, NULL);

    /* Select cheapest path */
    set_cheapest(rel);
}

/*
 * choose_hashed_setop - should we use hashing for a set operation?
 */
static bool
choose_hashed_setop(PlannerInfo *root, List *groupClauses,
                    Path *input_path,
                    double dNumGroups, double dNumOutputRows,
                    const char *construct)
{
    int         numGroupCols = list_length(groupClauses);
    bool        can_sort;
    bool        can_hash;
    Size        hashentrysize;
    Path        hashed_p;
    Path        sorted_p;
    double      tuple_fraction;

    /* Check whether the operators support sorting or hashing */
    can_sort = grouping_is_sortable(groupClauses);
    can_hash = grouping_is_hashable(groupClauses);
    if (can_hash && can_sort)
    {
        /* we have a meaningful choice to make, continue ... */
    }
    else if (can_hash)
        return true;
    else if (can_sort)
        return false;
    else
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
        /* translator: %s is UNION, INTERSECT, or EXCEPT */
                 errmsg("could not implement %s", construct),
                 errdetail("Some of the datatypes only support hashing, while others only support sorting.")));

    /* Prefer sorting when enable_hashagg is off */
    if (!enable_hashagg)
        return false;

    /*
     * Don't do it if it doesn't look like the hashtable will fit into
     * work_mem.
     */
    hashentrysize = MAXALIGN(input_path->pathtarget->width) + MAXALIGN(SizeofMinimalTupleHeader);

    if (hashentrysize * dNumGroups > work_mem * 1024L)
        return false;

    /*
     * See if the estimated cost is no more than doing it the other way.
     *
     * We need to consider input_plan + hashagg versus input_plan + sort +
     * group.  Note that the actual result plan might involve a SetOp or
     * Unique node, not Agg or Group, but the cost estimates for Agg and Group
     * should be close enough for our purposes here.
     *
     * These path variables are dummies that just hold cost fields; we don't
     * make actual Paths for these steps.
     */
    cost_agg(&hashed_p, root, AGG_HASHED, NULL,
             numGroupCols, dNumGroups,
             NIL,
             input_path->startup_cost, input_path->total_cost,
             input_path->rows);

    /*
     * Now for the sorted case.  Note that the input is *always* unsorted,
     * since it was made by appending unrelated sub-relations together.
     */
    sorted_p.startup_cost = input_path->startup_cost;
    sorted_p.total_cost = input_path->total_cost;
    /* XXX cost_sort doesn't actually look at pathkeys, so just pass NIL */
    cost_sort(&sorted_p, root, NIL, sorted_p.total_cost,
              input_path->rows, input_path->pathtarget->width,
              0.0, work_mem, -1.0);
    cost_group(&sorted_p, root, numGroupCols, dNumGroups,
               NIL,
               sorted_p.startup_cost, sorted_p.total_cost,
               input_path->rows);

    /*
     * Now make the decision using the top-level tuple fraction.  First we
     * have to convert an absolute count (LIMIT) into fractional form.
     */
    tuple_fraction = root->tuple_fraction;
    if (tuple_fraction >= 1.0)
        tuple_fraction /= dNumOutputRows;

    if (compare_fractional_path_costs(&hashed_p, &sorted_p,
                                      tuple_fraction) < 0)
    {
        /* Hashed is cheaper, so use it */
        return true;
    }
    return false;
}

/*
 * Generate targetlist for a set-operation plan node
 *
 * colTypes: OID list of set-op's result column datatypes
 * colCollations: OID list of set-op's result column collations
 * flag: -1 if no flag column needed, 0 or 1 to create a const flag column
 * varno: varno to use in generated Vars
 * hack_constants: true to copy up constants (see comments in code)
 * input_tlist: targetlist of this node's input node
 * refnames_tlist: targetlist to take column names from
 */
static List *
generate_setop_tlist(List *colTypes, List *colCollations,
                     int flag,
                     Index varno,
                     bool hack_constants,
                     List *input_tlist,
                     List *refnames_tlist)
{
    List       *tlist = NIL;
    int         resno = 1;
    ListCell   *ctlc,
               *cclc,
               *itlc,
               *rtlc;
    TargetEntry *tle;
    Node       *expr;

    /* there's no forfour() so we must chase one list manually */
    rtlc = list_head(refnames_tlist);
    forthree(ctlc, colTypes, cclc, colCollations, itlc, input_tlist)
    {
        Oid         colType = lfirst_oid(ctlc);
        Oid         colColl = lfirst_oid(cclc);
        TargetEntry *inputtle = (TargetEntry *) lfirst(itlc);
        TargetEntry *reftle = (TargetEntry *) lfirst(rtlc);

        rtlc = lnext(rtlc);

        Assert(inputtle->resno == resno);
        Assert(reftle->resno == resno);
        Assert(!inputtle->resjunk);
        Assert(!reftle->resjunk);

        /*
         * Generate columns referencing input columns and having appropriate
         * data types and column names.  Insert datatype coercions where
         * necessary.
         *
         * HACK: constants in the input's targetlist are copied up as-is
         * rather than being referenced as subquery outputs.  This is mainly
         * to ensure that when we try to coerce them to the output column's
         * datatype, the right things happen for UNKNOWN constants.  But do
         * this only at the first level of subquery-scan plans; we don't want
         * phony constants appearing in the output tlists of upper-level
         * nodes!
         */
        if (hack_constants && inputtle->expr && IsA(inputtle->expr, Const))
            expr = (Node *) inputtle->expr;
        else
            expr = (Node *) makeVar(varno,
                                    inputtle->resno,
                                    exprType((Node *) inputtle->expr),
                                    exprTypmod((Node *) inputtle->expr),
                                    exprCollation((Node *) inputtle->expr),
                                    0);

        if (exprType(expr) != colType)
        {
            /*
             * Note: it's not really cool to be applying coerce_to_common_type
             * here; one notable point is that assign_expr_collations never
             * gets run on any generated nodes.  For the moment that's not a
             * problem because we force the correct exposed collation below.
             * It would likely be best to make the parser generate the correct
             * output tlist for every set-op to begin with, though.
             */
            expr = coerce_to_common_type(NULL,  /* no UNKNOWNs here */
                                         expr,
                                         colType,
                                         "UNION/INTERSECT/EXCEPT");
        }

        /*
         * Ensure the tlist entry's exposed collation matches the set-op. This
         * is necessary because plan_set_operations() reports the result
         * ordering as a list of SortGroupClauses, which don't carry collation
         * themselves but just refer to tlist entries.  If we don't show the
         * right collation then planner.c might do the wrong thing in
         * higher-level queries.
         *
         * Note we use RelabelType, not CollateExpr, since this expression
         * will reach the executor without any further processing.
         */
        if (exprCollation(expr) != colColl)
        {
            expr = (Node *) makeRelabelType((Expr *) expr,
                                            exprType(expr),
                                            exprTypmod(expr),
                                            colColl,
                                            COERCE_IMPLICIT_CAST);
        }

        tle = makeTargetEntry((Expr *) expr,
                              (AttrNumber) resno++,
                              pstrdup(reftle->resname),
                              false);

        /*
         * By convention, all non-resjunk columns in a setop tree have
         * ressortgroupref equal to their resno.  In some cases the ref isn't
         * needed, but this is a cleaner way than modifying the tlist later.
         */
        tle->ressortgroupref = tle->resno;

        tlist = lappend(tlist, tle);
    }

    if (flag >= 0)
    {
        /* Add a resjunk flag column */
        /* flag value is the given constant */
        expr = (Node *) makeConst(INT4OID,
                                  -1,
                                  InvalidOid,
                                  sizeof(int32),
                                  Int32GetDatum(flag),
                                  false,
                                  true);
        tle = makeTargetEntry((Expr *) expr,
                              (AttrNumber) resno++,
                              pstrdup("flag"),
                              true);
        tlist = lappend(tlist, tle);
    }

    return tlist;
}

/*
 * Generate targetlist for a set-operation Append node
 *
 * colTypes: OID list of set-op's result column datatypes
 * colCollations: OID list of set-op's result column collations
 * flag: true to create a flag column copied up from subplans
 * input_tlists: list of tlists for sub-plans of the Append
 * refnames_tlist: targetlist to take column names from
 *
 * The entries in the Append's targetlist should always be simple Vars;
 * we just have to make sure they have the right datatypes/typmods/collations.
 * The Vars are always generated with varno 0.
 *
 * XXX a problem with the varno-zero approach is that set_pathtarget_cost_width
 * cannot figure out a realistic width for the tlist we make here.  But we
 * ought to refactor this code to produce a PathTarget directly, anyway.
 */
static List *
generate_append_tlist(List *colTypes, List *colCollations,
                      bool flag,
                      List *input_tlists,
                      List *refnames_tlist)
{
    List       *tlist = NIL;
    int         resno = 1;
    ListCell   *curColType;
    ListCell   *curColCollation;
    ListCell   *ref_tl_item;
    int         colindex;
    TargetEntry *tle;
    Node       *expr;
    ListCell   *tlistl;
    int32      *colTypmods;

    /*
     * First extract typmods to use.
     *
     * If the inputs all agree on type and typmod of a particular column, use
     * that typmod; else use -1.
     */
    colTypmods = (int32 *) palloc(list_length(colTypes) * sizeof(int32));

    foreach(tlistl, input_tlists)
    {
        List       *subtlist = (List *) lfirst(tlistl);
        ListCell   *subtlistl;

        curColType = list_head(colTypes);
        colindex = 0;
        foreach(subtlistl, subtlist)
        {
            TargetEntry *subtle = (TargetEntry *) lfirst(subtlistl);

            if (subtle->resjunk)
                continue;
            Assert(curColType != NULL);
            if (exprType((Node *) subtle->expr) == lfirst_oid(curColType))
            {
                /* If first subplan, copy the typmod; else compare */
                int32       subtypmod = exprTypmod((Node *) subtle->expr);

                if (tlistl == list_head(input_tlists))
                    colTypmods[colindex] = subtypmod;
                else if (subtypmod != colTypmods[colindex])
                    colTypmods[colindex] = -1;
            }
            else
            {
                /* types disagree, so force typmod to -1 */
                colTypmods[colindex] = -1;
            }
            curColType = lnext(curColType);
            colindex++;
        }
        Assert(curColType == NULL);
    }

    /*
     * Now we can build the tlist for the Append.
     */
    colindex = 0;
    forthree(curColType, colTypes, curColCollation, colCollations,
             ref_tl_item, refnames_tlist)
    {
        Oid         colType = lfirst_oid(curColType);
        int32       colTypmod = colTypmods[colindex++];
        Oid         colColl = lfirst_oid(curColCollation);
        TargetEntry *reftle = (TargetEntry *) lfirst(ref_tl_item);

        Assert(reftle->resno == resno);
        Assert(!reftle->resjunk);
        expr = (Node *) makeVar(0,
                                resno,
                                colType,
                                colTypmod,
                                colColl,
                                0);
        tle = makeTargetEntry((Expr *) expr,
                              (AttrNumber) resno++,
                              pstrdup(reftle->resname),
                              false);

        /*
         * By convention, all non-resjunk columns in a setop tree have
         * ressortgroupref equal to their resno.  In some cases the ref isn't
         * needed, but this is a cleaner way than modifying the tlist later.
         */
        tle->ressortgroupref = tle->resno;

        tlist = lappend(tlist, tle);
    }

    if (flag)
    {
        /* Add a resjunk flag column */
        /* flag value is shown as copied up from subplan */
        expr = (Node *) makeVar(0,
                                resno,
                                INT4OID,
                                -1,
                                InvalidOid,
                                0);
        tle = makeTargetEntry((Expr *) expr,
                              (AttrNumber) resno++,
                              pstrdup("flag"),
                              true);
        tlist = lappend(tlist, tle);
    }

    pfree(colTypmods);

    return tlist;
}

/*
 * generate_setop_grouplist
 *      Build a SortGroupClause list defining the sort/grouping properties
 *      of the setop's output columns.
 *
 * Parse analysis already determined the properties and built a suitable
 * list, except that the entries do not have sortgrouprefs set because
 * the parser output representation doesn't include a tlist for each
 * setop.  So what we need to do here is copy that list and install
 * proper sortgrouprefs into it (copying those from the targetlist).
 */
static List *
generate_setop_grouplist(SetOperationStmt *op, List *targetlist)
{
    List       *grouplist = copyObject(op->groupClauses);
    ListCell   *lg;
    ListCell   *lt;

    lg = list_head(grouplist);
    foreach(lt, targetlist)
    {
        TargetEntry *tle = (TargetEntry *) lfirst(lt);
        SortGroupClause *sgc;

        if (tle->resjunk)
        {
            /* resjunk columns should not have sortgrouprefs */
            Assert(tle->ressortgroupref == 0);
            continue;           /* ignore resjunk columns */
        }

        /* non-resjunk columns should have sortgroupref = resno */
        Assert(tle->ressortgroupref == tle->resno);

        /* non-resjunk columns should have grouping clauses */
        Assert(lg != NULL);
        sgc = (SortGroupClause *) lfirst(lg);
        lg = lnext(lg);
        Assert(sgc->tleSortGroupRef == 0);

        sgc->tleSortGroupRef = tle->ressortgroupref;
    }
    Assert(lg == NULL);
    return grouplist;
}


/*
 * expand_inherited_tables
 *      Expand each rangetable entry that represents an inheritance set
 *      into an "append relation".  At the conclusion of this process,
 *      the "inh" flag is set in all and only those RTEs that are append
 *      relation parents.
 */
void
expand_inherited_tables(PlannerInfo *root)
{
    Index       nrtes;
    Index       rti;
    ListCell   *rl;

    /*
     * expand_inherited_rtentry may add RTEs to parse->rtable. The function is
     * expected to recursively handle any RTEs that it creates with inh=true.
     * So just scan as far as the original end of the rtable list.
     */
    nrtes = list_length(root->parse->rtable);
    rl = list_head(root->parse->rtable);
    for (rti = 1; rti <= nrtes; rti++)
    {
        RangeTblEntry *rte = (RangeTblEntry *) lfirst(rl);

        expand_inherited_rtentry(root, rte, rti);
        rl = lnext(rl);
    }
}

/*
 * expand_inherited_rtentry
 *      Check whether a rangetable entry represents an inheritance set.
 *      If so, add entries for all the child tables to the query's
 *      rangetable, and build AppendRelInfo nodes for all the child tables
 *      and add them to root->append_rel_list.  If not, clear the entry's
 *      "inh" flag to prevent later code from looking for AppendRelInfos.
 *
 * Note that the original RTE is considered to represent the whole
 * inheritance set.  The first of the generated RTEs is an RTE for the same
 * table, but with inh = false, to represent the parent table in its role
 * as a simple member of the inheritance set.
 *
 * A childless table is never considered to be an inheritance set. For
 * regular inheritance, a parent RTE must always have at least two associated
 * AppendRelInfos: one corresponding to the parent table as a simple member of
 * inheritance set and one or more corresponding to the actual children.
 * Since a partitioned table is not scanned, it might have only one associated
 * AppendRelInfo.
 */
static void
expand_inherited_rtentry(PlannerInfo *root, RangeTblEntry *rte, Index rti)
{
    Query      *parse = root->parse;
    Oid         parentOID;
    PlanRowMark *oldrc;
    Relation    oldrelation;
    LOCKMODE    lockmode;
    List       *inhOIDs;
    ListCell   *l;

    /* Does RT entry allow inheritance? */
    if (!rte->inh)
        return;
    /* Ignore any already-expanded UNION ALL nodes */
    if (rte->rtekind != RTE_RELATION)
    {
        Assert(rte->rtekind == RTE_SUBQUERY);
        return;
    }
    /* Fast path for common case of childless table */
    parentOID = rte->relid;
    if (!has_subclass(parentOID))
    {
        /* Clear flag before returning */
        rte->inh = false;
        return;
    }

    /*
     * The rewriter should already have obtained an appropriate lock on each
     * relation named in the query.  However, for each child relation we add
     * to the query, we must obtain an appropriate lock, because this will be
     * the first use of those relations in the parse/rewrite/plan pipeline.
     *
     * If the parent relation is the query's result relation, then we need
     * RowExclusiveLock.  Otherwise, if it's accessed FOR UPDATE/SHARE, we
     * need RowShareLock; otherwise AccessShareLock.  We can't just grab
     * AccessShareLock because then the executor would be trying to upgrade
     * the lock, leading to possible deadlocks.  (This code should match the
     * parser and rewriter.)
     */
    oldrc = get_plan_rowmark(root->rowMarks, rti);
    if (rti == parse->resultRelation)
        lockmode = RowExclusiveLock;
    else if (oldrc && RowMarkRequiresRowShareLock(oldrc->markType))
        lockmode = RowShareLock;
    else
        lockmode = AccessShareLock;

    /* Scan for all members of inheritance set, acquire needed locks */
    inhOIDs = find_all_inheritors(parentOID, lockmode, NULL);

    /*
     * Check that there's at least one descendant, else treat as no-child
     * case.  This could happen despite above has_subclass() check, if table
     * once had a child but no longer does.
     */
    if (list_length(inhOIDs) < 2)
    {
        /* Clear flag before returning */
        rte->inh = false;
        return;
    }

    /*
     * If parent relation is selected FOR UPDATE/SHARE, we need to mark its
     * PlanRowMark as isParent = true, and generate a new PlanRowMark for each
     * child.
     */
    if (oldrc)
        oldrc->isParent = true;

    /*
     * Must open the parent relation to examine its tupdesc.  We need not lock
     * it; we assume the rewriter already did.
     */
    oldrelation = heap_open(parentOID, NoLock);

    /* Scan the inheritance set and expand it */
    if (RelationGetPartitionDesc(oldrelation) != NULL)
    {
        Assert(rte->relkind == RELKIND_PARTITIONED_TABLE);

        /*
         * If this table has partitions, recursively expand them in the order
         * in which they appear in the PartitionDesc.  While at it, also
         * extract the partition key columns of all the partitioned tables.
         */
        expand_partitioned_rtentry(root, rte, rti, oldrelation, oldrc,
                                   lockmode, &root->append_rel_list);
    }
    else
    {
        List       *appinfos = NIL;
        RangeTblEntry *childrte;
        Index       childRTindex;

        /*
         * This table has no partitions.  Expand any plain inheritance
         * children in the order the OIDs were returned by
         * find_all_inheritors.
         */
        foreach(l, inhOIDs)
        {
            Oid         childOID = lfirst_oid(l);
            Relation    newrelation;

            /* Open rel if needed; we already have required locks */
            if (childOID != parentOID)
                newrelation = heap_open(childOID, NoLock);
            else
                newrelation = oldrelation;

            /*
             * It is possible that the parent table has children that are temp
             * tables of other backends.  We cannot safely access such tables
             * (because of buffering issues), and the best thing to do seems
             * to be to silently ignore them.
             */
            if (childOID != parentOID && RELATION_IS_OTHER_TEMP(newrelation))
            {
                heap_close(newrelation, lockmode);
                continue;
            }

            expand_single_inheritance_child(root, rte, rti, oldrelation, oldrc,
                                            newrelation,
                                            &appinfos, &childrte,
                                            &childRTindex);

            /* Close child relations, but keep locks */
            if (childOID != parentOID)
                heap_close(newrelation, NoLock);
        }

        /*
         * If all the children were temp tables, pretend it's a
         * non-inheritance situation; we don't need Append node in that case.
         * The duplicate RTE we added for the parent table is harmless, so we
         * don't bother to get rid of it; ditto for the useless PlanRowMark
         * node.
         */
        if (list_length(appinfos) < 2)
            rte->inh = false;
        else
            root->append_rel_list = list_concat(root->append_rel_list,
                                                appinfos);

    }

    heap_close(oldrelation, NoLock);
}

/*
 * expand_partitioned_rtentry
 *      Recursively expand an RTE for a partitioned table.
 *
 * Note that RelationGetPartitionDispatchInfo will expand partitions in the
 * same order as this code.
 */
static void
expand_partitioned_rtentry(PlannerInfo *root, RangeTblEntry *parentrte,
                           Index parentRTindex, Relation parentrel,
                           PlanRowMark *top_parentrc, LOCKMODE lockmode,
                           List **appinfos)
{
    int         i;
    RangeTblEntry *childrte;
    Index       childRTindex;
    bool        has_child = false;
    PartitionDesc partdesc = RelationGetPartitionDesc(parentrel);

    check_stack_depth();

    /* A partitioned table should always have a partition descriptor. */
    Assert(partdesc);

    Assert(parentrte->inh);

    /*
     * Note down whether any partition key cols are being updated. Though it's
     * the root partitioned table's updatedCols we are interested in, we
     * instead use parentrte to get the updatedCols. This is convenient
     * because parentrte already has the root partrel's updatedCols translated
     * to match the attribute ordering of parentrel.
     */
    if (!root->partColsUpdated)
        root->partColsUpdated =
            has_partition_attrs(parentrel, parentrte->updatedCols, NULL);

    /* First expand the partitioned table itself. */
    expand_single_inheritance_child(root, parentrte, parentRTindex, parentrel,
                                    top_parentrc, parentrel,
                                    appinfos, &childrte, &childRTindex);

    for (i = 0; i < partdesc->nparts; i++)
    {
        Oid         childOID = partdesc->oids[i];
        Relation    childrel;

        /* Open rel; we already have required locks */
        childrel = heap_open(childOID, NoLock);

        /* As in expand_inherited_rtentry, skip non-local temp tables */
        if (RELATION_IS_OTHER_TEMP(childrel))
        {
            heap_close(childrel, lockmode);
            continue;
        }

        /* We have a real partition. */
        has_child = true;

        expand_single_inheritance_child(root, parentrte, parentRTindex,
                                        parentrel, top_parentrc, childrel,
                                        appinfos, &childrte, &childRTindex);

        /* If this child is itself partitioned, recurse */
        if (childrel->rd_rel->relkind == RELKIND_PARTITIONED_TABLE)
            expand_partitioned_rtentry(root, childrte, childRTindex,
                                       childrel, top_parentrc, lockmode,
                                       appinfos);

        /* Close child relation, but keep locks */
        heap_close(childrel, NoLock);
    }

    /*
     * If the partitioned table has no partitions or all the partitions are
     * temporary tables from other backends, treat this as non-inheritance
     * case.
     */
    if (!has_child)
        parentrte->inh = false;
}

/*
 * expand_single_inheritance_child
 *      Build a RangeTblEntry and an AppendRelInfo, if appropriate, plus
 *      maybe a PlanRowMark.
 *
 * We now expand the partition hierarchy level by level, creating a
 * corresponding hierarchy of AppendRelInfos and RelOptInfos, where each
 * partitioned descendant acts as a parent of its immediate partitions.
 * (This is a difference from what older versions of PostgreSQL did and what
 * is still done in the case of table inheritance for unpartitioned tables,
 * where the hierarchy is flattened during RTE expansion.)
 *
 * PlanRowMarks still carry the top-parent's RTI, and the top-parent's
 * allMarkTypes field still accumulates values from all descendents.
 *
 * "parentrte" and "parentRTindex" are immediate parent's RTE and
 * RTI. "top_parentrc" is top parent's PlanRowMark.
 *
 * The child RangeTblEntry and its RTI are returned in "childrte_p" and
 * "childRTindex_p" resp.
 */
static void
expand_single_inheritance_child(PlannerInfo *root, RangeTblEntry *parentrte,
                                Index parentRTindex, Relation parentrel,
                                PlanRowMark *top_parentrc, Relation childrel,
                                List **appinfos, RangeTblEntry **childrte_p,
                                Index *childRTindex_p)
{
    Query      *parse = root->parse;
    Oid         parentOID = RelationGetRelid(parentrel);
    Oid         childOID = RelationGetRelid(childrel);
    RangeTblEntry *childrte;
    Index       childRTindex;
    AppendRelInfo *appinfo;

    /*
     * Build an RTE for the child, and attach to query's rangetable list. We
     * copy most fields of the parent's RTE, but replace relation OID and
     * relkind, and set inh = false.  Also, set requiredPerms to zero since
     * all required permissions checks are done on the original RTE. Likewise,
     * set the child's securityQuals to empty, because we only want to apply
     * the parent's RLS conditions regardless of what RLS properties
     * individual children may have.  (This is an intentional choice to make
     * inherited RLS work like regular permissions checks.) The parent
     * securityQuals will be propagated to children along with other base
     * restriction clauses, so we don't need to do it here.
     */
    childrte = copyObject(parentrte);
    *childrte_p = childrte;
    childrte->relid = childOID;
    childrte->relkind = childrel->rd_rel->relkind;
    /* A partitioned child will need to be expanded further. */
    if (childOID != parentOID &&
        childrte->relkind == RELKIND_PARTITIONED_TABLE)
        childrte->inh = true;
    else
        childrte->inh = false;
    childrte->requiredPerms = 0;
    childrte->securityQuals = NIL;
    parse->rtable = lappend(parse->rtable, childrte);
    childRTindex = list_length(parse->rtable);
    *childRTindex_p = childRTindex;

    /*
     * We need an AppendRelInfo if paths will be built for the child RTE. If
     * childrte->inh is true, then we'll always need to generate append paths
     * for it.  If childrte->inh is false, we must scan it if it's not a
     * partitioned table; but if it is a partitioned table, then it never has
     * any data of its own and need not be scanned.
     */
    if (childrte->relkind != RELKIND_PARTITIONED_TABLE || childrte->inh)
    {
        appinfo = makeNode(AppendRelInfo);
        appinfo->parent_relid = parentRTindex;
        appinfo->child_relid = childRTindex;
        appinfo->parent_reltype = parentrel->rd_rel->reltype;
        appinfo->child_reltype = childrel->rd_rel->reltype;
        make_inh_translation_list(parentrel, childrel, childRTindex,
                                  &appinfo->translated_vars);
        appinfo->parent_reloid = parentOID;
        *appinfos = lappend(*appinfos, appinfo);

        /*
         * Translate the column permissions bitmaps to the child's attnums (we
         * have to build the translated_vars list before we can do this). But
         * if this is the parent table, leave copyObject's result alone.
         *
         * Note: we need to do this even though the executor won't run any
         * permissions checks on the child RTE.  The insertedCols/updatedCols
         * bitmaps may be examined for trigger-firing purposes.
         */
        if (childOID != parentOID)
        {
            childrte->selectedCols = translate_col_privs(parentrte->selectedCols,
                                                         appinfo->translated_vars);
            childrte->insertedCols = translate_col_privs(parentrte->insertedCols,
                                                         appinfo->translated_vars);
            childrte->updatedCols = translate_col_privs(parentrte->updatedCols,
                                                        appinfo->translated_vars);
        }
    }

    /*
     * Build a PlanRowMark if parent is marked FOR UPDATE/SHARE.
     */
    if (top_parentrc)
    {
        PlanRowMark *childrc = makeNode(PlanRowMark);

        childrc->rti = childRTindex;
        childrc->prti = top_parentrc->rti;
        childrc->rowmarkId = top_parentrc->rowmarkId;
        /* Reselect rowmark type, because relkind might not match parent */
        childrc->markType = select_rowmark_type(childrte,
                                                top_parentrc->strength);
        childrc->allMarkTypes = (1 << childrc->markType);
        childrc->strength = top_parentrc->strength;
        childrc->waitPolicy = top_parentrc->waitPolicy;

        /*
         * We mark RowMarks for partitioned child tables as parent RowMarks so
         * that the executor ignores them (except their existence means that
         * the child tables be locked using appropriate mode).
         */
        childrc->isParent = (childrte->relkind == RELKIND_PARTITIONED_TABLE);

        /* Include child's rowmark type in top parent's allMarkTypes */
        top_parentrc->allMarkTypes |= childrc->allMarkTypes;

        root->rowMarks = lappend(root->rowMarks, childrc);
    }
}

/*
 * make_inh_translation_list
 *    Build the list of translations from parent Vars to child Vars for
 *    an inheritance child.
 *
 * For paranoia's sake, we match type/collation as well as attribute name.
 */
static void
make_inh_translation_list(Relation oldrelation, Relation newrelation,
                          Index newvarno,
                          List **translated_vars)
{
    List       *vars = NIL;
    TupleDesc   old_tupdesc = RelationGetDescr(oldrelation);
    TupleDesc   new_tupdesc = RelationGetDescr(newrelation);
    int         oldnatts = old_tupdesc->natts;
    int         newnatts = new_tupdesc->natts;
    int         old_attno;

    for (old_attno = 0; old_attno < oldnatts; old_attno++)
    {
        Form_pg_attribute att;
        char       *attname;
        Oid         atttypid;
        int32       atttypmod;
        Oid         attcollation;
        int         new_attno;

        att = TupleDescAttr(old_tupdesc, old_attno);
        if (att->attisdropped)
        {
            /* Just put NULL into this list entry */
            vars = lappend(vars, NULL);
            continue;
        }
        attname = NameStr(att->attname);
        atttypid = att->atttypid;
        atttypmod = att->atttypmod;
        attcollation = att->attcollation;

        /*
         * When we are generating the "translation list" for the parent table
         * of an inheritance set, no need to search for matches.
         */
        if (oldrelation == newrelation)
        {
            vars = lappend(vars, makeVar(newvarno,
                                         (AttrNumber) (old_attno + 1),
                                         atttypid,
                                         atttypmod,
                                         attcollation,
                                         0));
            continue;
        }

        /*
         * Otherwise we have to search for the matching column by name.
         * There's no guarantee it'll have the same column position, because
         * of cases like ALTER TABLE ADD COLUMN and multiple inheritance.
         * However, in simple cases it will be the same column number, so try
         * that before we go groveling through all the columns.
         *
         * Note: the test for (att = ...) != NULL cannot fail, it's just a
         * notational device to include the assignment into the if-clause.
         */
        if (old_attno < newnatts &&
            (att = TupleDescAttr(new_tupdesc, old_attno)) != NULL &&
            !att->attisdropped &&
            strcmp(attname, NameStr(att->attname)) == 0)
            new_attno = old_attno;
        else
        {
            for (new_attno = 0; new_attno < newnatts; new_attno++)
            {
                att = TupleDescAttr(new_tupdesc, new_attno);
                if (!att->attisdropped &&
                    strcmp(attname, NameStr(att->attname)) == 0)
                    break;
            }
            if (new_attno >= newnatts)
                elog(ERROR, "could not find inherited attribute \"%s\" of relation \"%s\"",
                     attname, RelationGetRelationName(newrelation));
        }

        /* Found it, check type and collation match */
        if (atttypid != att->atttypid || atttypmod != att->atttypmod)
            elog(ERROR, "attribute \"%s\" of relation \"%s\" does not match parent's type",
                 attname, RelationGetRelationName(newrelation));
        if (attcollation != att->attcollation)
            elog(ERROR, "attribute \"%s\" of relation \"%s\" does not match parent's collation",
                 attname, RelationGetRelationName(newrelation));

        vars = lappend(vars, makeVar(newvarno,
                                     (AttrNumber) (new_attno + 1),
                                     atttypid,
                                     atttypmod,
                                     attcollation,
                                     0));
    }

    *translated_vars = vars;
}

/*
 * translate_col_privs
 *    Translate a bitmapset representing per-column privileges from the
 *    parent rel's attribute numbering to the child's.
 *
 * The only surprise here is that we don't translate a parent whole-row
 * reference into a child whole-row reference.  That would mean requiring
 * permissions on all child columns, which is overly strict, since the
 * query is really only going to reference the inherited columns.  Instead
 * we set the per-column bits for all inherited columns.
 */
static Bitmapset *
translate_col_privs(const Bitmapset *parent_privs,
                    List *translated_vars)
{
    Bitmapset  *child_privs = NULL;
    bool        whole_row;
    int         attno;
    ListCell   *lc;

    /* System attributes have the same numbers in all tables */
    for (attno = FirstLowInvalidHeapAttributeNumber + 1; attno < 0; attno++)
    {
        if (bms_is_member(attno - FirstLowInvalidHeapAttributeNumber,
                          parent_privs))
            child_privs = bms_add_member(child_privs,
                                         attno - FirstLowInvalidHeapAttributeNumber);
    }

    /* Check if parent has whole-row reference */
    whole_row = bms_is_member(InvalidAttrNumber - FirstLowInvalidHeapAttributeNumber,
                              parent_privs);

    /* And now translate the regular user attributes, using the vars list */
    attno = InvalidAttrNumber;
    foreach(lc, translated_vars)
    {
        Var        *var = lfirst_node(Var, lc);

        attno++;
        if (var == NULL)        /* ignore dropped columns */
            continue;
        if (whole_row ||
            bms_is_member(attno - FirstLowInvalidHeapAttributeNumber,
                          parent_privs))
            child_privs = bms_add_member(child_privs,
                                         var->varattno - FirstLowInvalidHeapAttributeNumber);
    }

    return child_privs;
}

/*
 * adjust_appendrel_attrs
 *    Copy the specified query or expression and translate Vars referring to a
 *    parent rel to refer to the corresponding child rel instead.  We also
 *    update rtindexes appearing outside Vars, such as resultRelation and
 *    jointree relids.
 *
 * Note: this is only applied after conversion of sublinks to subplans,
 * so we don't need to cope with recursion into sub-queries.
 *
 * Note: this is not hugely different from what pullup_replace_vars() does;
 * maybe we should try to fold the two routines together.
 */
Node *
adjust_appendrel_attrs(PlannerInfo *root, Node *node, int nappinfos,
                       AppendRelInfo **appinfos)
{
    Node       *result;
    adjust_appendrel_attrs_context context;

    context.root = root;
    context.nappinfos = nappinfos;
    context.appinfos = appinfos;

    /* If there's nothing to adjust, don't call this function. */
    Assert(nappinfos >= 1 && appinfos != NULL);

    /*
     * Must be prepared to start with a Query or a bare expression tree.
     */
    if (node && IsA(node, Query))
    {
        Query      *newnode;
        int         cnt;

        newnode = query_tree_mutator((Query *) node,
                                     adjust_appendrel_attrs_mutator,
                                     (void *) &context,
                                     QTW_IGNORE_RC_SUBQUERIES);
        for (cnt = 0; cnt < nappinfos; cnt++)
        {
            AppendRelInfo *appinfo = appinfos[cnt];

            if (newnode->resultRelation == appinfo->parent_relid)
            {
                newnode->resultRelation = appinfo->child_relid;
                /* Fix tlist resnos too, if it's inherited UPDATE */
                if (newnode->commandType == CMD_UPDATE)
                    newnode->targetList =
                        adjust_inherited_tlist(newnode->targetList,
                                               appinfo);
                break;
            }
        }

        result = (Node *) newnode;
    }
    else
        result = adjust_appendrel_attrs_mutator(node, &context);

    return result;
}

static Node *
adjust_appendrel_attrs_mutator(Node *node,
                               adjust_appendrel_attrs_context *context)
{
    AppendRelInfo **appinfos = context->appinfos;
    int         nappinfos = context->nappinfos;
    int         cnt;

    if (node == NULL)
        return NULL;
    if (IsA(node, Var))
    {
        Var        *var = (Var *) copyObject(node);
        AppendRelInfo *appinfo = NULL;

        for (cnt = 0; cnt < nappinfos; cnt++)
        {
            if (var->varno == appinfos[cnt]->parent_relid)
            {
                appinfo = appinfos[cnt];
                break;
            }
        }

        if (var->varlevelsup == 0 && appinfo)
        {
            var->varno = appinfo->child_relid;
            var->varnoold = appinfo->child_relid;
            if (var->varattno > 0)
            {
                Node       *newnode;

                if (var->varattno > list_length(appinfo->translated_vars))
                    elog(ERROR, "attribute %d of relation \"%s\" does not exist",
                         var->varattno, get_rel_name(appinfo->parent_reloid));
                newnode = copyObject(list_nth(appinfo->translated_vars,
                                              var->varattno - 1));
                if (newnode == NULL)
                    elog(ERROR, "attribute %d of relation \"%s\" does not exist",
                         var->varattno, get_rel_name(appinfo->parent_reloid));
                return newnode;
            }
            else if (var->varattno == 0)
            {
                /*
                 * Whole-row Var: if we are dealing with named rowtypes, we
                 * can use a whole-row Var for the child table plus a coercion
                 * step to convert the tuple layout to the parent's rowtype.
                 * Otherwise we have to generate a RowExpr.
                 */
                if (OidIsValid(appinfo->child_reltype))
                {
                    Assert(var->vartype == appinfo->parent_reltype);
                    if (appinfo->parent_reltype != appinfo->child_reltype)
                    {
                        ConvertRowtypeExpr *r = makeNode(ConvertRowtypeExpr);

                        r->arg = (Expr *) var;
                        r->resulttype = appinfo->parent_reltype;
                        r->convertformat = COERCE_IMPLICIT_CAST;
                        r->location = -1;
                        /* Make sure the Var node has the right type ID, too */
                        var->vartype = appinfo->child_reltype;
                        return (Node *) r;
                    }
                }
                else
                {
                    /*
                     * Build a RowExpr containing the translated variables.
                     *
                     * In practice var->vartype will always be RECORDOID here,
                     * so we need to come up with some suitable column names.
                     * We use the parent RTE's column names.
                     *
                     * Note: we can't get here for inheritance cases, so there
                     * is no need to worry that translated_vars might contain
                     * some dummy NULLs.
                     */
                    RowExpr    *rowexpr;
                    List       *fields;
                    RangeTblEntry *rte;

                    rte = rt_fetch(appinfo->parent_relid,
                                   context->root->parse->rtable);
                    fields = copyObject(appinfo->translated_vars);
                    rowexpr = makeNode(RowExpr);
                    rowexpr->args = fields;
                    rowexpr->row_typeid = var->vartype;
                    rowexpr->row_format = COERCE_IMPLICIT_CAST;
                    rowexpr->colnames = copyObject(rte->eref->colnames);
                    rowexpr->location = -1;

                    return (Node *) rowexpr;
                }
            }
            /* system attributes don't need any other translation */
        }
        return (Node *) var;
    }
    if (IsA(node, CurrentOfExpr))
    {
        CurrentOfExpr *cexpr = (CurrentOfExpr *) copyObject(node);

        for (cnt = 0; cnt < nappinfos; cnt++)
        {
            AppendRelInfo *appinfo = appinfos[cnt];

            if (cexpr->cvarno == appinfo->parent_relid)
            {
                cexpr->cvarno = appinfo->child_relid;
                break;
            }
        }
        return (Node *) cexpr;
    }
    if (IsA(node, RangeTblRef))
    {
        RangeTblRef *rtr = (RangeTblRef *) copyObject(node);

        for (cnt = 0; cnt < nappinfos; cnt++)
        {
            AppendRelInfo *appinfo = appinfos[cnt];

            if (rtr->rtindex == appinfo->parent_relid)
            {
                rtr->rtindex = appinfo->child_relid;
                break;
            }
        }
        return (Node *) rtr;
    }
    if (IsA(node, JoinExpr))
    {
        /* Copy the JoinExpr node with correct mutation of subnodes */
        JoinExpr   *j;
        AppendRelInfo *appinfo;

        j = (JoinExpr *) expression_tree_mutator(node,
                                                 adjust_appendrel_attrs_mutator,
                                                 (void *) context);
        /* now fix JoinExpr's rtindex (probably never happens) */
        for (cnt = 0; cnt < nappinfos; cnt++)
        {
            appinfo = appinfos[cnt];

            if (j->rtindex == appinfo->parent_relid)
            {
                j->rtindex = appinfo->child_relid;
                break;
            }
        }
        return (Node *) j;
    }
    if (IsA(node, PlaceHolderVar))
    {
        /* Copy the PlaceHolderVar node with correct mutation of subnodes */
        PlaceHolderVar *phv;

        phv = (PlaceHolderVar *) expression_tree_mutator(node,
                                                         adjust_appendrel_attrs_mutator,
                                                         (void *) context);
        /* now fix PlaceHolderVar's relid sets */
        if (phv->phlevelsup == 0)
            phv->phrels = adjust_child_relids(phv->phrels, context->nappinfos,
                                              context->appinfos);
        return (Node *) phv;
    }
    /* Shouldn't need to handle planner auxiliary nodes here */
    Assert(!IsA(node, SpecialJoinInfo));
    Assert(!IsA(node, AppendRelInfo));
    Assert(!IsA(node, PlaceHolderInfo));
    Assert(!IsA(node, MinMaxAggInfo));

    /*
     * We have to process RestrictInfo nodes specially.  (Note: although
     * set_append_rel_pathlist will hide RestrictInfos in the parent's
     * baserestrictinfo list from us, it doesn't hide those in joininfo.)
     */
    if (IsA(node, RestrictInfo))
    {
        RestrictInfo *oldinfo = (RestrictInfo *) node;
        RestrictInfo *newinfo = makeNode(RestrictInfo);

        /* Copy all flat-copiable fields */
        memcpy(newinfo, oldinfo, sizeof(RestrictInfo));

        /* Recursively fix the clause itself */
        newinfo->clause = (Expr *)
            adjust_appendrel_attrs_mutator((Node *) oldinfo->clause, context);

        /* and the modified version, if an OR clause */
        newinfo->orclause = (Expr *)
            adjust_appendrel_attrs_mutator((Node *) oldinfo->orclause, context);

        /* adjust relid sets too */
        newinfo->clause_relids = adjust_child_relids(oldinfo->clause_relids,
                                                     context->nappinfos,
                                                     context->appinfos);
        newinfo->required_relids = adjust_child_relids(oldinfo->required_relids,
                                                       context->nappinfos,
                                                       context->appinfos);
        newinfo->outer_relids = adjust_child_relids(oldinfo->outer_relids,
                                                    context->nappinfos,
                                                    context->appinfos);
        newinfo->nullable_relids = adjust_child_relids(oldinfo->nullable_relids,
                                                       context->nappinfos,
                                                       context->appinfos);
        newinfo->left_relids = adjust_child_relids(oldinfo->left_relids,
                                                   context->nappinfos,
                                                   context->appinfos);
        newinfo->right_relids = adjust_child_relids(oldinfo->right_relids,
                                                    context->nappinfos,
                                                    context->appinfos);

        /*
         * Reset cached derivative fields, since these might need to have
         * different values when considering the child relation.  Note we
         * don't reset left_ec/right_ec: each child variable is implicitly
         * equivalent to its parent, so still a member of the same EC if any.
         */
        newinfo->eval_cost.startup = -1;
        newinfo->norm_selec = -1;
        newinfo->outer_selec = -1;
        newinfo->left_em = NULL;
        newinfo->right_em = NULL;
        newinfo->scansel_cache = NIL;
        newinfo->left_bucketsize = -1;
        newinfo->right_bucketsize = -1;
        newinfo->left_mcvfreq = -1;
        newinfo->right_mcvfreq = -1;

        return (Node *) newinfo;
    }

    /*
     * NOTE: we do not need to recurse into sublinks, because they should
     * already have been converted to subplans before we see them.
     */
    Assert(!IsA(node, SubLink));
    Assert(!IsA(node, Query));

    return expression_tree_mutator(node, adjust_appendrel_attrs_mutator,
                                   (void *) context);
}

/*
 * Substitute child relids for parent relids in a Relid set.  The array of
 * appinfos specifies the substitutions to be performed.
 */
static Relids
adjust_child_relids(Relids relids, int nappinfos, AppendRelInfo **appinfos)
{
    Bitmapset  *result = NULL;
    int         cnt;

    for (cnt = 0; cnt < nappinfos; cnt++)
    {
        AppendRelInfo *appinfo = appinfos[cnt];

        /* Remove parent, add child */
        if (bms_is_member(appinfo->parent_relid, relids))
        {
            /* Make a copy if we are changing the set. */
            if (!result)
                result = bms_copy(relids);

            result = bms_del_member(result, appinfo->parent_relid);
            result = bms_add_member(result, appinfo->child_relid);
        }
    }

    /* If we made any changes, return the modified copy. */
    if (result)
        return result;

    /* Otherwise, return the original set without modification. */
    return relids;
}

/*
 * Replace any relid present in top_parent_relids with its child in
 * child_relids. Members of child_relids can be multiple levels below top
 * parent in the partition hierarchy.
 */
Relids
adjust_child_relids_multilevel(PlannerInfo *root, Relids relids,
                               Relids child_relids, Relids top_parent_relids)
{
    AppendRelInfo **appinfos;
    int         nappinfos;
    Relids      parent_relids = NULL;
    Relids      result;
    Relids      tmp_result = NULL;
    int         cnt;

    /*
     * If the given relids set doesn't contain any of the top parent relids,
     * it will remain unchanged.
     */
    if (!bms_overlap(relids, top_parent_relids))
        return relids;

    appinfos = find_appinfos_by_relids(root, child_relids, &nappinfos);

    /* Construct relids set for the immediate parent of the given child. */
    for (cnt = 0; cnt < nappinfos; cnt++)
    {
        AppendRelInfo *appinfo = appinfos[cnt];

        parent_relids = bms_add_member(parent_relids, appinfo->parent_relid);
    }

    /* Recurse if immediate parent is not the top parent. */
    if (!bms_equal(parent_relids, top_parent_relids))
    {
        tmp_result = adjust_child_relids_multilevel(root, relids,
                                                    parent_relids,
                                                    top_parent_relids);
        relids = tmp_result;
    }

    result = adjust_child_relids(relids, nappinfos, appinfos);

    /* Free memory consumed by any intermediate result. */
    if (tmp_result)
        bms_free(tmp_result);
    bms_free(parent_relids);
    pfree(appinfos);

    return result;
}

/*
 * Adjust the targetlist entries of an inherited UPDATE operation
 *
 * The expressions have already been fixed, but we have to make sure that
 * the target resnos match the child table (they may not, in the case of
 * a column that was added after-the-fact by ALTER TABLE).  In some cases
 * this can force us to re-order the tlist to preserve resno ordering.
 * (We do all this work in special cases so that preptlist.c is fast for
 * the typical case.)
 *
 * The given tlist has already been through expression_tree_mutator;
 * therefore the TargetEntry nodes are fresh copies that it's okay to
 * scribble on.
 *
 * Note that this is not needed for INSERT because INSERT isn't inheritable.
 */
static List *
adjust_inherited_tlist(List *tlist, AppendRelInfo *context)
{
    bool        changed_it = false;
    ListCell   *tl;
    List       *new_tlist;
    bool        more;
    int         attrno;

    /* This should only happen for an inheritance case, not UNION ALL */
    Assert(OidIsValid(context->parent_reloid));

    /* Scan tlist and update resnos to match attnums of child rel */
    foreach(tl, tlist)
    {
        TargetEntry *tle = (TargetEntry *) lfirst(tl);
        Var        *childvar;

        if (tle->resjunk)
            continue;           /* ignore junk items */

        /* Look up the translation of this column: it must be a Var */
        if (tle->resno <= 0 ||
            tle->resno > list_length(context->translated_vars))
            elog(ERROR, "attribute %d of relation \"%s\" does not exist",
                 tle->resno, get_rel_name(context->parent_reloid));
        childvar = (Var *) list_nth(context->translated_vars, tle->resno - 1);
        if (childvar == NULL || !IsA(childvar, Var))
            elog(ERROR, "attribute %d of relation \"%s\" does not exist",
                 tle->resno, get_rel_name(context->parent_reloid));

        if (tle->resno != childvar->varattno)
        {
            tle->resno = childvar->varattno;
            changed_it = true;
        }
    }

    /*
     * If we changed anything, re-sort the tlist by resno, and make sure
     * resjunk entries have resnos above the last real resno.  The sort
     * algorithm is a bit stupid, but for such a seldom-taken path, small is
     * probably better than fast.
     */
    if (!changed_it)
        return tlist;

    new_tlist = NIL;
    more = true;
    for (attrno = 1; more; attrno++)
    {
        more = false;
        foreach(tl, tlist)
        {
            TargetEntry *tle = (TargetEntry *) lfirst(tl);

            if (tle->resjunk)
                continue;       /* ignore junk items */

            if (tle->resno == attrno)
                new_tlist = lappend(new_tlist, tle);
            else if (tle->resno > attrno)
                more = true;
        }
    }

    foreach(tl, tlist)
    {
        TargetEntry *tle = (TargetEntry *) lfirst(tl);

        if (!tle->resjunk)
            continue;           /* here, ignore non-junk items */

        tle->resno = attrno;
        new_tlist = lappend(new_tlist, tle);
        attrno++;
    }

    return new_tlist;
}

/*
 * adjust_appendrel_attrs_multilevel
 *    Apply Var translations from a toplevel appendrel parent down to a child.
 *
 * In some cases we need to translate expressions referencing a parent relation
 * to reference an appendrel child that's multiple levels removed from it.
 */
Node *
adjust_appendrel_attrs_multilevel(PlannerInfo *root, Node *node,
                                  Relids child_relids,
                                  Relids top_parent_relids)
{
    AppendRelInfo **appinfos;
    Bitmapset  *parent_relids = NULL;
    int         nappinfos;
    int         cnt;

    Assert(bms_num_members(child_relids) == bms_num_members(top_parent_relids));

    appinfos = find_appinfos_by_relids(root, child_relids, &nappinfos);

    /* Construct relids set for the immediate parent of given child. */
    for (cnt = 0; cnt < nappinfos; cnt++)
    {
        AppendRelInfo *appinfo = appinfos[cnt];

        parent_relids = bms_add_member(parent_relids, appinfo->parent_relid);
    }

    /* Recurse if immediate parent is not the top parent. */
    if (!bms_equal(parent_relids, top_parent_relids))
        node = adjust_appendrel_attrs_multilevel(root, node, parent_relids,
                                                 top_parent_relids);

    /* Now translate for this child */
    node = adjust_appendrel_attrs(root, node, nappinfos, appinfos);

    pfree(appinfos);

    return node;
}

/*
 * Construct the SpecialJoinInfo for a child-join by translating
 * SpecialJoinInfo for the join between parents. left_relids and right_relids
 * are the relids of left and right side of the join respectively.
 */
SpecialJoinInfo *
build_child_join_sjinfo(PlannerInfo *root, SpecialJoinInfo *parent_sjinfo,
                        Relids left_relids, Relids right_relids)
{
    SpecialJoinInfo *sjinfo = makeNode(SpecialJoinInfo);
    AppendRelInfo **left_appinfos;
    int         left_nappinfos;
    AppendRelInfo **right_appinfos;
    int         right_nappinfos;

    memcpy(sjinfo, parent_sjinfo, sizeof(SpecialJoinInfo));
    left_appinfos = find_appinfos_by_relids(root, left_relids,
                                            &left_nappinfos);
    right_appinfos = find_appinfos_by_relids(root, right_relids,
                                             &right_nappinfos);

    sjinfo->min_lefthand = adjust_child_relids(sjinfo->min_lefthand,
                                               left_nappinfos, left_appinfos);
    sjinfo->min_righthand = adjust_child_relids(sjinfo->min_righthand,
                                                right_nappinfos,
                                                right_appinfos);
    sjinfo->syn_lefthand = adjust_child_relids(sjinfo->syn_lefthand,
                                               left_nappinfos, left_appinfos);
    sjinfo->syn_righthand = adjust_child_relids(sjinfo->syn_righthand,
                                                right_nappinfos,
                                                right_appinfos);
    sjinfo->semi_rhs_exprs = (List *) adjust_appendrel_attrs(root,
                                                             (Node *) sjinfo->semi_rhs_exprs,
                                                             right_nappinfos,
                                                             right_appinfos);

    pfree(left_appinfos);
    pfree(right_appinfos);

    return sjinfo;
}

/*
 * find_appinfos_by_relids
 *      Find AppendRelInfo structures for all relations specified by relids.
 *
 * The AppendRelInfos are returned in an array, which can be pfree'd by the
 * caller. *nappinfos is set to the number of entries in the array.
 */
AppendRelInfo **
find_appinfos_by_relids(PlannerInfo *root, Relids relids, int *nappinfos)
{
    ListCell   *lc;
    AppendRelInfo **appinfos;
    int         cnt = 0;

    *nappinfos = bms_num_members(relids);
    appinfos = (AppendRelInfo **) palloc(sizeof(AppendRelInfo *) * *nappinfos);

    foreach(lc, root->append_rel_list)
    {
        AppendRelInfo *appinfo = lfirst(lc);

        if (bms_is_member(appinfo->child_relid, relids))
        {
            appinfos[cnt] = appinfo;
            cnt++;

            /* Stop when we have gathered all the AppendRelInfos. */
            if (cnt == *nappinfos)
                return appinfos;
        }
    }

    /* Should have found the entries ... */
    elog(ERROR, "did not find all requested child rels in append_rel_list");
    return NULL;                /* not reached */
}