/*------------------------------------------------------------------------- * * 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. * * Portions Copyright (c) 1996-2025, 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 "access/htup_details.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/planner.h" #include "optimizer/prep.h" #include "optimizer/tlist.h" #include "parser/parse_coerce.h" #include "utils/selfuncs.h" static RelOptInfo *recurse_set_operations(Node *setOp, PlannerInfo *root, SetOperationStmt *parentOp, List *colTypes, List *colCollations, List *refnames_tlist, List **pTargetList, bool *istrivial_tlist); static RelOptInfo *generate_recursion_path(SetOperationStmt *setOp, PlannerInfo *root, List *refnames_tlist, List **pTargetList); static void build_setop_child_paths(PlannerInfo *root, RelOptInfo *rel, bool trivial_tlist, List *child_tlist, List *interesting_pathkeys, double *pNumGroups); 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, List **istrivial_tlist); static void postprocess_setop_rel(PlannerInfo *root, RelOptInfo *rel); static List *generate_setop_tlist(List *colTypes, List *colCollations, Index varno, bool hack_constants, List *input_tlist, List *refnames_tlist, bool *trivial_tlist); static List *generate_append_tlist(List *colTypes, List *colCollations, List *input_tlists, List *refnames_tlist); static List *generate_setop_grouplist(SetOperationStmt *op, List *targetlist); /* * 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); /* * In the outer query level, equivalence classes are limited to classes * which define that the top-level target entry is equivalent to the * corresponding child target entry. There won't be any equivalence class * merging. Mark that merging is complete to allow us to make pathkeys. */ Assert(root->eq_classes == NIL); root->ec_merging_done = true; /* * 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 those, and for AppendRelInfos in case they're needed. */ 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 { bool trivial_tlist; /* * 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. */ setop_rel = recurse_set_operations((Node *) topop, root, NULL, /* no parent */ topop->colTypes, topop->colCollations, leftmostQuery->targetList, &top_tlist, &trivial_tlist); } /* 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 * * setOp: current step (could be a SetOperationStmt or a leaf RangeTblRef) * parentOp: parent step, or NULL if none (but see below) * colTypes: OID list of set-op's result column datatypes * colCollations: OID list of set-op's result column collations * refnames_tlist: targetlist to take column names from * * parentOp should be passed as NULL unless that step is interested in * getting sorted output from this step. ("Sorted" means "sorted according * to the default btree opclasses of the result column datatypes".) * * Returns a RelOptInfo for the subtree, as well as these output parameters: * *pTargetList: receives the fully-fledged tlist for the subtree's top plan * *istrivial_tlist: true if, and only if, datatypes between parent and child * match. * * If setOp is a leaf node, this function plans the sub-query but does * not populate the pathlist of the returned RelOptInfo. The caller will * generate SubqueryScan paths using useful path(s) of the subquery (see * build_setop_child_paths). But this function does build the paths for * set-operation nodes. * * 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. * XXX Now that there are no flag columns and hence no resjunk columns, we * could probably refactor this file to deal only in pathtargets. * * 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, SetOperationStmt *parentOp, List *colTypes, List *colCollations, List *refnames_tlist, List **pTargetList, bool *istrivial_tlist) { RelOptInfo *rel; *istrivial_tlist = true; /* for now */ /* 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; List *tlist; bool trivial_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. If we have a * parentOp, pass that down to encourage subquery_planner to consider * suitably-sorted Paths. */ subroot = rel->subroot = subquery_planner(root->glob, subquery, root, false, root->tuple_fraction, parentOp); /* * 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, rtr->rtindex, true, subroot->processed_tlist, refnames_tlist, &trivial_tlist); rel->reltarget = create_pathtarget(root, tlist); /* Return the fully-fledged tlist to caller, too */ *pTargetList = tlist; *istrivial_tlist = trivial_tlist; } 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 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_paths() or * generate_nonunion_paths(), and hence its tlist was generated by * generate_append_tlist() or generate_setop_tlist(), this will work. * We just tell generate_setop_tlist() to use varno 0. */ if (!tlist_same_datatypes(*pTargetList, colTypes, false) || !tlist_same_collations(*pTargetList, colCollations, false)) { PathTarget *target; bool trivial_tlist; ListCell *lc; *pTargetList = generate_setop_tlist(colTypes, colCollations, 0, false, *pTargetList, refnames_tlist, &trivial_tlist); *istrivial_tlist = trivial_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; } } postprocess_setop_rel(root, rel); } else { elog(ERROR, "unrecognized node type: %d", (int) nodeTag(setOp)); *pTargetList = NIL; rel = NULL; /* keep compiler quiet */ } 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; bool lpath_trivial_tlist; List *rpath_tlist; bool rpath_trivial_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, NULL, /* no value in sorted results */ setOp->colTypes, setOp->colCollations, refnames_tlist, &lpath_tlist, &lpath_trivial_tlist); if (lrel->rtekind == RTE_SUBQUERY) build_setop_child_paths(root, lrel, lpath_trivial_tlist, lpath_tlist, NIL, 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, NULL, /* no value in sorted results */ setOp->colTypes, setOp->colCollations, refnames_tlist, &rpath_tlist, &rpath_trivial_tlist); if (rrel->rtekind == RTE_SUBQUERY) build_setop_child_paths(root, rrel, rpath_trivial_tlist, rpath_tlist, NIL, 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, 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; } /* * build_setop_child_paths * Build paths for the set op child relation denoted by 'rel'. * * 'rel' is an RTE_SUBQUERY relation. We have already generated paths within * the subquery's subroot; the task here is to create SubqueryScan paths for * 'rel', representing scans of the useful subquery paths. * * interesting_pathkeys: if not NIL, also include paths that suit these * pathkeys, sorting any unsorted paths as required. * *pNumGroups: if not NULL, we estimate the number of distinct groups * in the result, and store it there. */ static void build_setop_child_paths(PlannerInfo *root, RelOptInfo *rel, bool trivial_tlist, List *child_tlist, List *interesting_pathkeys, double *pNumGroups) { RelOptInfo *final_rel; List *setop_pathkeys = rel->subroot->setop_pathkeys; ListCell *lc; /* it can't be a set op child rel if it's not a subquery */ Assert(rel->rtekind == RTE_SUBQUERY); /* when sorting is needed, add child rel equivalences */ if (interesting_pathkeys != NIL) add_setop_child_rel_equivalences(root, rel, child_tlist, interesting_pathkeys); /* * 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(rel->subroot, UPPERREL_FINAL, NULL); rel->consider_parallel = final_rel->consider_parallel; /* Generate subquery scan paths for any interesting path in final_rel */ foreach(lc, final_rel->pathlist) { Path *subpath = (Path *) lfirst(lc); List *pathkeys; Path *cheapest_input_path = final_rel->cheapest_total_path; bool is_sorted; int presorted_keys; /* * Include the cheapest path as-is so that the set operation can be * cheaply implemented using a method which does not require the input * to be sorted. */ if (subpath == cheapest_input_path) { /* Convert subpath's pathkeys to outer representation */ pathkeys = convert_subquery_pathkeys(root, rel, subpath->pathkeys, make_tlist_from_pathtarget(subpath->pathtarget)); /* Generate outer path using this subpath */ add_path(rel, (Path *) create_subqueryscan_path(root, rel, subpath, trivial_tlist, pathkeys, NULL)); } /* skip dealing with sorted paths if the setop doesn't need them */ if (interesting_pathkeys == NIL) continue; /* * Create paths to suit final sort order required for setop_pathkeys. * Here we'll sort the cheapest input path (if not sorted already) and * incremental sort any paths which are partially sorted. */ is_sorted = pathkeys_count_contained_in(setop_pathkeys, subpath->pathkeys, &presorted_keys); if (!is_sorted) { double limittuples = rel->subroot->limit_tuples; /* * Try at least sorting the cheapest path and also try * incrementally sorting any path which is partially sorted * already (no need to deal with paths which have presorted keys * when incremental sort is disabled unless it's the cheapest * input path). */ if (subpath != cheapest_input_path && (presorted_keys == 0 || !enable_incremental_sort)) continue; /* * We've no need to consider both a sort and incremental sort. * We'll just do a sort if there are no presorted keys and an * incremental sort when there are presorted keys. */ if (presorted_keys == 0 || !enable_incremental_sort) subpath = (Path *) create_sort_path(rel->subroot, final_rel, subpath, setop_pathkeys, limittuples); else subpath = (Path *) create_incremental_sort_path(rel->subroot, final_rel, subpath, setop_pathkeys, presorted_keys, limittuples); } /* * subpath is now sorted, so add it to the pathlist. We already added * the cheapest_input_path above, so don't add it again unless we just * sorted it. */ if (subpath != cheapest_input_path) { /* Convert subpath's pathkeys to outer representation */ pathkeys = convert_subquery_pathkeys(root, rel, subpath->pathkeys, make_tlist_from_pathtarget(subpath->pathtarget)); /* Generate outer path using this subpath */ add_path(rel, (Path *) create_subqueryscan_path(root, rel, subpath, trivial_tlist, pathkeys, NULL)); } } /* if consider_parallel is false, there should be no partial paths */ Assert(final_rel->consider_parallel || final_rel->partial_pathlist == NIL); /* * 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, trivial_tlist, NIL, NULL); add_partial_path(rel, partial_path); } postprocess_setop_rel(root, rel); /* * 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 subroot->parse'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. Note, we use this not * subquery's targetlist but subroot->parse's targetlist, because it was * revised by self-join removal. subquery's targetlist might contain the * references to the removed relids. */ if (pNumGroups) { PlannerInfo *subroot = rel->subroot; Query *subquery = subroot->parse; if (subquery->groupClause || subquery->groupingSets || subquery->distinctClause || subroot->hasHavingQual || subquery->hasAggs) *pNumGroups = rel->cheapest_total_path->rows; else *pNumGroups = estimate_num_groups(subroot, get_tlist_exprs(subroot->parse->targetList, false), rel->cheapest_total_path->rows, NULL, NULL); } } /* * 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; ListCell *lc; ListCell *lc2; ListCell *lc3; List *cheapest_pathlist = NIL; List *ordered_pathlist = NIL; List *partial_pathlist = NIL; bool partial_paths_valid = true; bool consider_parallel = true; List *rellist; List *tlist_list; List *trivial_tlist_list; List *tlist; List *groupList = NIL; Path *apath; Path *gpath = NULL; bool try_sorted = false; List *union_pathkeys = NIL; /* * If any of my children are identical UNION nodes (same op, all-flag, and * colTypes/colCollations) then they can be merged into this node so that * we generate only one Append/MergeAppend and unique-ification for the * lot. Recurse to find such nodes. */ rellist = plan_union_children(root, op, refnames_tlist, &tlist_list, &trivial_tlist_list); /* * Generate tlist for Append/MergeAppend 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, tlist_list, refnames_tlist); *pTargetList = tlist; /* For UNIONs (not UNION ALL), try sorting, if sorting is possible */ if (!op->all) { /* Identify the grouping semantics */ groupList = generate_setop_grouplist(op, tlist); if (grouping_is_sortable(op->groupClauses)) { try_sorted = true; /* Determine the pathkeys for sorting by the whole target list */ union_pathkeys = make_pathkeys_for_sortclauses(root, groupList, tlist); root->query_pathkeys = union_pathkeys; } } /* * Now that we've got the append target list, we can build the union child * paths. */ forthree(lc, rellist, lc2, trivial_tlist_list, lc3, tlist_list) { RelOptInfo *rel = lfirst(lc); bool trivial_tlist = lfirst_int(lc2); List *child_tlist = lfirst_node(List, lc3); /* only build paths for the union children */ if (rel->rtekind == RTE_SUBQUERY) build_setop_child_paths(root, rel, trivial_tlist, child_tlist, union_pathkeys, NULL); } /* Build path lists and relid set. */ foreach(lc, rellist) { RelOptInfo *rel = lfirst(lc); Path *ordered_path; cheapest_pathlist = lappend(cheapest_pathlist, rel->cheapest_total_path); if (try_sorted) { ordered_path = get_cheapest_path_for_pathkeys(rel->pathlist, union_pathkeys, NULL, TOTAL_COST, false); if (ordered_path != NULL) ordered_pathlist = lappend(ordered_pathlist, ordered_path); else { /* * If we can't find a sorted path, just give up trying to * generate a list of correctly sorted child paths. This can * happen when type coercion was added to the targetlist due * to mismatching types from the union children. */ try_sorted = false; } } 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; result_rel->consider_startup = (root->tuple_fraction > 0); /* * Append the child results together using the cheapest paths from each * union child. */ apath = (Path *) create_append_path(root, result_rel, cheapest_pathlist, NIL, NIL, NULL, 0, false, -1); /* * 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 = apath->rows; /* * Now consider doing the same thing using the partial paths plus Append * plus Gather. */ if (partial_paths_valid) { Path *papath; int parallel_workers = 0; /* Find the highest number of workers requested for any subpath. */ foreach(lc, partial_pathlist) { Path *subpath = lfirst(lc); parallel_workers = Max(parallel_workers, subpath->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, pg_leftmost_one_pos32(list_length(partial_pathlist)) + 1); parallel_workers = Min(parallel_workers, max_parallel_workers_per_gather); } Assert(parallel_workers > 0); papath = (Path *) create_append_path(root, result_rel, NIL, partial_pathlist, NIL, NULL, parallel_workers, enable_parallel_append, -1); gpath = (Path *) create_gather_path(root, result_rel, papath, result_rel->reltarget, NULL, NULL); } if (!op->all) { double dNumGroups; bool can_sort = grouping_is_sortable(groupList); bool can_hash = grouping_is_hashable(groupList); /* * XXX for the moment, take the number of distinct groups as equal to * the total input size, i.e., the worst case. This is too * conservative, but 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 = apath->rows; if (can_hash) { Path *path; /* * Try a hash aggregate plan on 'apath'. This is the cheapest * available path containing each append child. */ path = (Path *) create_agg_path(root, result_rel, apath, create_pathtarget(root, tlist), AGG_HASHED, AGGSPLIT_SIMPLE, groupList, NIL, NULL, dNumGroups); add_path(result_rel, path); /* Try hash aggregate on the Gather path, if valid */ if (gpath != NULL) { /* Hashed aggregate plan --- no sort needed */ path = (Path *) create_agg_path(root, result_rel, gpath, create_pathtarget(root, tlist), AGG_HASHED, AGGSPLIT_SIMPLE, groupList, NIL, NULL, dNumGroups); add_path(result_rel, path); } } if (can_sort) { Path *path = apath; /* Try Sort -> Unique on the Append path */ if (groupList != NIL) 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); add_path(result_rel, path); /* Try Sort -> Unique on the Gather path, if set */ if (gpath != NULL) { path = gpath; 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); add_path(result_rel, path); } } /* * Try making a MergeAppend path if we managed to find a path with the * correct pathkeys in each union child query. */ if (try_sorted && groupList != NIL) { Path *path; path = (Path *) create_merge_append_path(root, result_rel, ordered_pathlist, union_pathkeys, NULL); /* and make the MergeAppend unique */ path = (Path *) create_upper_unique_path(root, result_rel, path, list_length(tlist), dNumGroups); add_path(result_rel, path); } } else { /* UNION ALL */ add_path(result_rel, apath); if (gpath != NULL) add_path(result_rel, gpath); } 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, *groupList; bool lpath_trivial_tlist, rpath_trivial_tlist, result_trivial_tlist; List *nonunion_pathkeys = NIL; double dLeftGroups, dRightGroups, dNumGroups, dNumOutputRows; bool can_sort; bool can_hash; SetOpCmd cmd; /* * Tell children to fetch all tuples. */ root->tuple_fraction = 0.0; /* Recurse on children */ lrel = recurse_set_operations(op->larg, root, op, op->colTypes, op->colCollations, refnames_tlist, &lpath_tlist, &lpath_trivial_tlist); rrel = recurse_set_operations(op->rarg, root, op, op->colTypes, op->colCollations, refnames_tlist, &rpath_tlist, &rpath_trivial_tlist); /* * Generate tlist for SetOp plan node. * * The tlist for a SetOp plan isn't important so far as the SetOp is * concerned, but we must make it look real anyway for the benefit of the * next plan level up. */ tlist = generate_setop_tlist(op->colTypes, op->colCollations, 0, false, lpath_tlist, refnames_tlist, &result_trivial_tlist); /* We should not have needed any type coercions in the tlist */ Assert(result_trivial_tlist); *pTargetList = tlist; /* Identify the grouping semantics */ groupList = generate_setop_grouplist(op, tlist); /* Check whether the operators support sorting or hashing */ can_sort = grouping_is_sortable(groupList); can_hash = grouping_is_hashable(groupList); if (!can_sort && !can_hash) ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), /* translator: %s is INTERSECT or EXCEPT */ errmsg("could not implement %s", (op->op == SETOP_INTERSECT) ? "INTERSECT" : "EXCEPT"), errdetail("Some of the datatypes only support hashing, while others only support sorting."))); if (can_sort) { /* Determine the pathkeys for sorting by the whole target list */ nonunion_pathkeys = make_pathkeys_for_sortclauses(root, groupList, tlist); root->query_pathkeys = nonunion_pathkeys; } /* * Now that we've got all that info, we can build the child paths. */ if (lrel->rtekind == RTE_SUBQUERY) build_setop_child_paths(root, lrel, lpath_trivial_tlist, lpath_tlist, nonunion_pathkeys, &dLeftGroups); else dLeftGroups = lrel->rows; if (rrel->rtekind == RTE_SUBQUERY) build_setop_child_paths(root, rrel, rpath_trivial_tlist, rpath_tlist, nonunion_pathkeys, &dRightGroups); else dRightGroups = rrel->rows; /* 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 (a) minimize the size of the hash table in the * hashing case, and (b) improve our chances of exploiting the executor's * fast path for empty left-hand input. "Smaller" means the one with the * fewer groups. */ if (op->op != SETOP_EXCEPT && dLeftGroups > dRightGroups) { /* need to swap the two inputs */ RelOptInfo *tmprel; List *tmplist; double tmpd; tmprel = lrel; lrel = rrel; rrel = tmprel; tmplist = lpath_tlist; lpath_tlist = rpath_tlist; rpath_tlist = tmplist; tmpd = dLeftGroups; dLeftGroups = dRightGroups; dRightGroups = tmpd; } lpath = lrel->cheapest_total_path; rpath = rrel->cheapest_total_path; /* Build result relation. */ result_rel = fetch_upper_rel(root, UPPERREL_SETOP, bms_union(lrel->relids, rrel->relids)); result_rel->reltarget = create_pathtarget(root, 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 = dLeftGroups; dNumOutputRows = op->all ? Min(lpath->rows, rpath->rows) : dNumGroups; } result_rel->rows = dNumOutputRows; /* Select the SetOpCmd type */ 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; } /* * If we can hash, that just requires a SetOp atop the cheapest inputs. */ if (can_hash) { path = (Path *) create_setop_path(root, result_rel, lpath, rpath, cmd, SETOP_HASHED, groupList, dNumGroups, dNumOutputRows); add_path(result_rel, path); } /* * If we can sort, generate the cheapest sorted input paths, and add a * SetOp atop those. */ if (can_sort) { List *pathkeys; Path *slpath, *srpath; /* First the left input ... */ pathkeys = make_pathkeys_for_sortclauses(root, groupList, lpath_tlist); if (pathkeys_contained_in(pathkeys, lpath->pathkeys)) slpath = lpath; /* cheapest path is already sorted */ else { slpath = get_cheapest_path_for_pathkeys(lrel->pathlist, nonunion_pathkeys, NULL, TOTAL_COST, false); /* Subquery failed to produce any presorted paths? */ if (slpath == NULL) slpath = (Path *) create_sort_path(root, lpath->parent, lpath, pathkeys, -1.0); } /* and now the same for the right. */ pathkeys = make_pathkeys_for_sortclauses(root, groupList, rpath_tlist); if (pathkeys_contained_in(pathkeys, rpath->pathkeys)) srpath = rpath; /* cheapest path is already sorted */ else { srpath = get_cheapest_path_for_pathkeys(rrel->pathlist, nonunion_pathkeys, NULL, TOTAL_COST, false); /* Subquery failed to produce any presorted paths? */ if (srpath == NULL) srpath = (Path *) create_sort_path(root, rpath->parent, rpath, pathkeys, -1.0); } path = (Path *) create_setop_path(root, result_rel, slpath, srpath, cmd, SETOP_SORTED, groupList, dNumGroups, dNumOutputRows); add_path(result_rel, path); } return result_rel; } /* * Pull up children of a UNION node that are identically-propertied UNIONs, * and perform planning of the queries underneath the N-way UNION. * * The result is a list of RelOptInfos containing Paths for sub-nodes, with * one entry for each descendant that is a leaf query or non-identical setop. * We also return parallel lists of the childrens' targetlists and * is-trivial-tlist flags. * * NOTE: we can also pull a UNION ALL up into a UNION, since the distinct * output rows will be lost anyway. */ static List * plan_union_children(PlannerInfo *root, SetOperationStmt *top_union, List *refnames_tlist, List **tlist_list, List **istrivial_tlist) { List *pending_rels = list_make1(top_union); List *result = NIL; List *child_tlist; bool trivial_tlist; *tlist_list = NIL; *istrivial_tlist = 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) && equal(op->colCollations, top_union->colCollations)) { /* 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. * * If top_union isn't a UNION ALL, then we are interested in sorted * output from the child, so pass top_union as parentOp. Note that * this isn't necessarily the child node's immediate SetOperationStmt * parent, but that's fine: it's the effective parent. */ result = lappend(result, recurse_set_operations(setOp, root, top_union->all ? NULL : top_union, top_union->colTypes, top_union->colCollations, refnames_tlist, &child_tlist, &trivial_tlist)); *tlist_list = lappend(*tlist_list, child_tlist); *istrivial_tlist = lappend_int(*istrivial_tlist, trivial_tlist); } return result; } /* * 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); } /* * 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 * 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 * trivial_tlist: output parameter, set to true if targetlist is trivial */ static List * generate_setop_tlist(List *colTypes, List *colCollations, Index varno, bool hack_constants, List *input_tlist, List *refnames_tlist, bool *trivial_tlist) { List *tlist = NIL; int resno = 1; ListCell *ctlc, *cclc, *itlc, *rtlc; TargetEntry *tle; Node *expr; *trivial_tlist = true; /* until proven differently */ forfour(ctlc, colTypes, cclc, colCollations, itlc, input_tlist, rtlc, refnames_tlist) { Oid colType = lfirst_oid(ctlc); Oid colColl = lfirst_oid(cclc); TargetEntry *inputtle = (TargetEntry *) lfirst(itlc); TargetEntry *reftle = (TargetEntry *) lfirst(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! * * Note that copying a constant doesn't in itself require us to mark * the tlist nontrivial; see trivial_subqueryscan() in setrefs.c. */ 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"); *trivial_tlist = false; /* the coercion makes it not trivial */ } /* * 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 = applyRelabelType(expr, exprType(expr), exprTypmod(expr), colColl, COERCE_IMPLICIT_CAST, -1, false); *trivial_tlist = false; /* the relabel makes it not trivial */ } tle = makeTargetEntry((Expr *) expr, (AttrNumber) resno++, pstrdup(reftle->resname), false); /* * By convention, all output 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); } 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 * 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, 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); Assert(!subtle->resjunk); 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(colTypes, 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 output 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); } 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; Assert(!tle->resjunk); /* 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(grouplist, lg); Assert(sgc->tleSortGroupRef == 0); sgc->tleSortGroupRef = tle->ressortgroupref; } Assert(lg == NULL); return grouplist; }