/*------------------------------------------------------------------------- * * pathnode.c * Routines to manipulate pathlists and create path nodes * * Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/optimizer/util/pathnode.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include "foreign/fdwapi.h" #include "miscadmin.h" #include "nodes/extensible.h" #include "nodes/nodeFuncs.h" #include "optimizer/appendinfo.h" #include "optimizer/clauses.h" #include "optimizer/cost.h" #include "optimizer/optimizer.h" #include "optimizer/pathnode.h" #include "optimizer/paths.h" #include "optimizer/planmain.h" #include "optimizer/prep.h" #include "optimizer/restrictinfo.h" #include "optimizer/tlist.h" #include "parser/parsetree.h" #include "utils/lsyscache.h" #include "utils/memutils.h" #include "utils/selfuncs.h" typedef enum { COSTS_EQUAL, /* path costs are fuzzily equal */ COSTS_BETTER1, /* first path is cheaper than second */ COSTS_BETTER2, /* second path is cheaper than first */ COSTS_DIFFERENT /* neither path dominates the other on cost */ } PathCostComparison; /* * STD_FUZZ_FACTOR is the normal fuzz factor for compare_path_costs_fuzzily. * XXX is it worth making this user-controllable? It provides a tradeoff * between planner runtime and the accuracy of path cost comparisons. */ #define STD_FUZZ_FACTOR 1.01 static List *translate_sub_tlist(List *tlist, int relid); static int append_total_cost_compare(const ListCell *a, const ListCell *b); static int append_startup_cost_compare(const ListCell *a, const ListCell *b); static List *reparameterize_pathlist_by_child(PlannerInfo *root, List *pathlist, RelOptInfo *child_rel); /***************************************************************************** * MISC. PATH UTILITIES *****************************************************************************/ /* * compare_path_costs * Return -1, 0, or +1 according as path1 is cheaper, the same cost, * or more expensive than path2 for the specified criterion. */ int compare_path_costs(Path *path1, Path *path2, CostSelector criterion) { if (criterion == STARTUP_COST) { if (path1->startup_cost < path2->startup_cost) return -1; if (path1->startup_cost > path2->startup_cost) return +1; /* * If paths have the same startup cost (not at all unlikely), order * them by total cost. */ if (path1->total_cost < path2->total_cost) return -1; if (path1->total_cost > path2->total_cost) return +1; } else { if (path1->total_cost < path2->total_cost) return -1; if (path1->total_cost > path2->total_cost) return +1; /* * If paths have the same total cost, order them by startup cost. */ if (path1->startup_cost < path2->startup_cost) return -1; if (path1->startup_cost > path2->startup_cost) return +1; } return 0; } /* * compare_fractional_path_costs * Return -1, 0, or +1 according as path1 is cheaper, the same cost, * or more expensive than path2 for fetching the specified fraction * of the total tuples. * * If fraction is <= 0 or > 1, we interpret it as 1, ie, we select the * path with the cheaper total_cost. */ int compare_fractional_path_costs(Path *path1, Path *path2, double fraction) { Cost cost1, cost2; if (fraction <= 0.0 || fraction >= 1.0) return compare_path_costs(path1, path2, TOTAL_COST); cost1 = path1->startup_cost + fraction * (path1->total_cost - path1->startup_cost); cost2 = path2->startup_cost + fraction * (path2->total_cost - path2->startup_cost); if (cost1 < cost2) return -1; if (cost1 > cost2) return +1; return 0; } /* * compare_path_costs_fuzzily * Compare the costs of two paths to see if either can be said to * dominate the other. * * We use fuzzy comparisons so that add_path() can avoid keeping both of * a pair of paths that really have insignificantly different cost. * * The fuzz_factor argument must be 1.0 plus delta, where delta is the * fraction of the smaller cost that is considered to be a significant * difference. For example, fuzz_factor = 1.01 makes the fuzziness limit * be 1% of the smaller cost. * * The two paths are said to have "equal" costs if both startup and total * costs are fuzzily the same. Path1 is said to be better than path2 if * it has fuzzily better startup cost and fuzzily no worse total cost, * or if it has fuzzily better total cost and fuzzily no worse startup cost. * Path2 is better than path1 if the reverse holds. Finally, if one path * is fuzzily better than the other on startup cost and fuzzily worse on * total cost, we just say that their costs are "different", since neither * dominates the other across the whole performance spectrum. * * This function also enforces a policy rule that paths for which the relevant * one of parent->consider_startup and parent->consider_param_startup is false * cannot survive comparisons solely on the grounds of good startup cost, so * we never return COSTS_DIFFERENT when that is true for the total-cost loser. * (But if total costs are fuzzily equal, we compare startup costs anyway, * in hopes of eliminating one path or the other.) */ static PathCostComparison compare_path_costs_fuzzily(Path *path1, Path *path2, double fuzz_factor) { #define CONSIDER_PATH_STARTUP_COST(p) \ ((p)->param_info == NULL ? (p)->parent->consider_startup : (p)->parent->consider_param_startup) /* * Check total cost first since it's more likely to be different; many * paths have zero startup cost. */ if (path1->total_cost > path2->total_cost * fuzz_factor) { /* path1 fuzzily worse on total cost */ if (CONSIDER_PATH_STARTUP_COST(path1) && path2->startup_cost > path1->startup_cost * fuzz_factor) { /* ... but path2 fuzzily worse on startup, so DIFFERENT */ return COSTS_DIFFERENT; } /* else path2 dominates */ return COSTS_BETTER2; } if (path2->total_cost > path1->total_cost * fuzz_factor) { /* path2 fuzzily worse on total cost */ if (CONSIDER_PATH_STARTUP_COST(path2) && path1->startup_cost > path2->startup_cost * fuzz_factor) { /* ... but path1 fuzzily worse on startup, so DIFFERENT */ return COSTS_DIFFERENT; } /* else path1 dominates */ return COSTS_BETTER1; } /* fuzzily the same on total cost ... */ if (path1->startup_cost > path2->startup_cost * fuzz_factor) { /* ... but path1 fuzzily worse on startup, so path2 wins */ return COSTS_BETTER2; } if (path2->startup_cost > path1->startup_cost * fuzz_factor) { /* ... but path2 fuzzily worse on startup, so path1 wins */ return COSTS_BETTER1; } /* fuzzily the same on both costs */ return COSTS_EQUAL; #undef CONSIDER_PATH_STARTUP_COST } /* * set_cheapest * Find the minimum-cost paths from among a relation's paths, * and save them in the rel's cheapest-path fields. * * cheapest_total_path is normally the cheapest-total-cost unparameterized * path; but if there are no unparameterized paths, we assign it to be the * best (cheapest least-parameterized) parameterized path. However, only * unparameterized paths are considered candidates for cheapest_startup_path, * so that will be NULL if there are no unparameterized paths. * * The cheapest_parameterized_paths list collects all parameterized paths * that have survived the add_path() tournament for this relation. (Since * add_path ignores pathkeys for a parameterized path, these will be paths * that have best cost or best row count for their parameterization. We * may also have both a parallel-safe and a non-parallel-safe path in some * cases for the same parameterization in some cases, but this should be * relatively rare since, most typically, all paths for the same relation * will be parallel-safe or none of them will.) * * cheapest_parameterized_paths always includes the cheapest-total * unparameterized path, too, if there is one; the users of that list find * it more convenient if that's included. * * This is normally called only after we've finished constructing the path * list for the rel node. */ void set_cheapest(RelOptInfo *parent_rel) { Path *cheapest_startup_path; Path *cheapest_total_path; Path *best_param_path; List *parameterized_paths; ListCell *p; Assert(IsA(parent_rel, RelOptInfo)); if (parent_rel->pathlist == NIL) elog(ERROR, "could not devise a query plan for the given query"); cheapest_startup_path = cheapest_total_path = best_param_path = NULL; parameterized_paths = NIL; foreach(p, parent_rel->pathlist) { Path *path = (Path *) lfirst(p); int cmp; if (path->param_info) { /* Parameterized path, so add it to parameterized_paths */ parameterized_paths = lappend(parameterized_paths, path); /* * If we have an unparameterized cheapest-total, we no longer care * about finding the best parameterized path, so move on. */ if (cheapest_total_path) continue; /* * Otherwise, track the best parameterized path, which is the one * with least total cost among those of the minimum * parameterization. */ if (best_param_path == NULL) best_param_path = path; else { switch (bms_subset_compare(PATH_REQ_OUTER(path), PATH_REQ_OUTER(best_param_path))) { case BMS_EQUAL: /* keep the cheaper one */ if (compare_path_costs(path, best_param_path, TOTAL_COST) < 0) best_param_path = path; break; case BMS_SUBSET1: /* new path is less-parameterized */ best_param_path = path; break; case BMS_SUBSET2: /* old path is less-parameterized, keep it */ break; case BMS_DIFFERENT: /* * This means that neither path has the least possible * parameterization for the rel. We'll sit on the old * path until something better comes along. */ break; } } } else { /* Unparameterized path, so consider it for cheapest slots */ if (cheapest_total_path == NULL) { cheapest_startup_path = cheapest_total_path = path; continue; } /* * If we find two paths of identical costs, try to keep the * better-sorted one. The paths might have unrelated sort * orderings, in which case we can only guess which might be * better to keep, but if one is superior then we definitely * should keep that one. */ cmp = compare_path_costs(cheapest_startup_path, path, STARTUP_COST); if (cmp > 0 || (cmp == 0 && compare_pathkeys(cheapest_startup_path->pathkeys, path->pathkeys) == PATHKEYS_BETTER2)) cheapest_startup_path = path; cmp = compare_path_costs(cheapest_total_path, path, TOTAL_COST); if (cmp > 0 || (cmp == 0 && compare_pathkeys(cheapest_total_path->pathkeys, path->pathkeys) == PATHKEYS_BETTER2)) cheapest_total_path = path; } } /* Add cheapest unparameterized path, if any, to parameterized_paths */ if (cheapest_total_path) parameterized_paths = lcons(cheapest_total_path, parameterized_paths); /* * If there is no unparameterized path, use the best parameterized path as * cheapest_total_path (but not as cheapest_startup_path). */ if (cheapest_total_path == NULL) cheapest_total_path = best_param_path; Assert(cheapest_total_path != NULL); parent_rel->cheapest_startup_path = cheapest_startup_path; parent_rel->cheapest_total_path = cheapest_total_path; parent_rel->cheapest_unique_path = NULL; /* computed only if needed */ parent_rel->cheapest_parameterized_paths = parameterized_paths; } /* * add_path * Consider a potential implementation path for the specified parent rel, * and add it to the rel's pathlist if it is worthy of consideration. * A path is worthy if it has a better sort order (better pathkeys) or * cheaper cost (on either dimension), or generates fewer rows, than any * existing path that has the same or superset parameterization rels. * We also consider parallel-safe paths more worthy than others. * * We also remove from the rel's pathlist any old paths that are dominated * by new_path --- that is, new_path is cheaper, at least as well ordered, * generates no more rows, requires no outer rels not required by the old * path, and is no less parallel-safe. * * In most cases, a path with a superset parameterization will generate * fewer rows (since it has more join clauses to apply), so that those two * figures of merit move in opposite directions; this means that a path of * one parameterization can seldom dominate a path of another. But such * cases do arise, so we make the full set of checks anyway. * * There are two policy decisions embedded in this function, along with * its sibling add_path_precheck. First, we treat all parameterized paths * as having NIL pathkeys, so that they cannot win comparisons on the * basis of sort order. This is to reduce the number of parameterized * paths that are kept; see discussion in src/backend/optimizer/README. * * Second, we only consider cheap startup cost to be interesting if * parent_rel->consider_startup is true for an unparameterized path, or * parent_rel->consider_param_startup is true for a parameterized one. * Again, this allows discarding useless paths sooner. * * The pathlist is kept sorted by total_cost, with cheaper paths * at the front. Within this routine, that's simply a speed hack: * doing it that way makes it more likely that we will reject an inferior * path after a few comparisons, rather than many comparisons. * However, add_path_precheck relies on this ordering to exit early * when possible. * * NOTE: discarded Path objects are immediately pfree'd to reduce planner * memory consumption. We dare not try to free the substructure of a Path, * since much of it may be shared with other Paths or the query tree itself; * but just recycling discarded Path nodes is a very useful savings in * a large join tree. We can recycle the List nodes of pathlist, too. * * As noted in optimizer/README, deleting a previously-accepted Path is * safe because we know that Paths of this rel cannot yet be referenced * from any other rel, such as a higher-level join. However, in some cases * it is possible that a Path is referenced by another Path for its own * rel; we must not delete such a Path, even if it is dominated by the new * Path. Currently this occurs only for IndexPath objects, which may be * referenced as children of BitmapHeapPaths as well as being paths in * their own right. Hence, we don't pfree IndexPaths when rejecting them. * * 'parent_rel' is the relation entry to which the path corresponds. * 'new_path' is a potential path for parent_rel. * * Returns nothing, but modifies parent_rel->pathlist. */ void add_path(RelOptInfo *parent_rel, Path *new_path) { bool accept_new = true; /* unless we find a superior old path */ int insert_at = 0; /* where to insert new item */ List *new_path_pathkeys; ListCell *p1; /* * This is a convenient place to check for query cancel --- no part of the * planner goes very long without calling add_path(). */ CHECK_FOR_INTERRUPTS(); /* Pretend parameterized paths have no pathkeys, per comment above */ new_path_pathkeys = new_path->param_info ? NIL : new_path->pathkeys; /* * Loop to check proposed new path against old paths. Note it is possible * for more than one old path to be tossed out because new_path dominates * it. */ foreach(p1, parent_rel->pathlist) { Path *old_path = (Path *) lfirst(p1); bool remove_old = false; /* unless new proves superior */ PathCostComparison costcmp; PathKeysComparison keyscmp; BMS_Comparison outercmp; /* * Do a fuzzy cost comparison with standard fuzziness limit. */ costcmp = compare_path_costs_fuzzily(new_path, old_path, STD_FUZZ_FACTOR); /* * If the two paths compare differently for startup and total cost, * then we want to keep both, and we can skip comparing pathkeys and * required_outer rels. If they compare the same, proceed with the * other comparisons. Row count is checked last. (We make the tests * in this order because the cost comparison is most likely to turn * out "different", and the pathkeys comparison next most likely. As * explained above, row count very seldom makes a difference, so even * though it's cheap to compare there's not much point in checking it * earlier.) */ if (costcmp != COSTS_DIFFERENT) { /* Similarly check to see if either dominates on pathkeys */ List *old_path_pathkeys; old_path_pathkeys = old_path->param_info ? NIL : old_path->pathkeys; keyscmp = compare_pathkeys(new_path_pathkeys, old_path_pathkeys); if (keyscmp != PATHKEYS_DIFFERENT) { switch (costcmp) { case COSTS_EQUAL: outercmp = bms_subset_compare(PATH_REQ_OUTER(new_path), PATH_REQ_OUTER(old_path)); if (keyscmp == PATHKEYS_BETTER1) { if ((outercmp == BMS_EQUAL || outercmp == BMS_SUBSET1) && new_path->rows <= old_path->rows && new_path->parallel_safe >= old_path->parallel_safe) remove_old = true; /* new dominates old */ } else if (keyscmp == PATHKEYS_BETTER2) { if ((outercmp == BMS_EQUAL || outercmp == BMS_SUBSET2) && new_path->rows >= old_path->rows && new_path->parallel_safe <= old_path->parallel_safe) accept_new = false; /* old dominates new */ } else /* keyscmp == PATHKEYS_EQUAL */ { if (outercmp == BMS_EQUAL) { /* * Same pathkeys and outer rels, and fuzzily * the same cost, so keep just one; to decide * which, first check parallel-safety, then * rows, then do a fuzzy cost comparison with * very small fuzz limit. (We used to do an * exact cost comparison, but that results in * annoying platform-specific plan variations * due to roundoff in the cost estimates.) If * things are still tied, arbitrarily keep * only the old path. Notice that we will * keep only the old path even if the * less-fuzzy comparison decides the startup * and total costs compare differently. */ if (new_path->parallel_safe > old_path->parallel_safe) remove_old = true; /* new dominates old */ else if (new_path->parallel_safe < old_path->parallel_safe) accept_new = false; /* old dominates new */ else if (new_path->rows < old_path->rows) remove_old = true; /* new dominates old */ else if (new_path->rows > old_path->rows) accept_new = false; /* old dominates new */ else if (compare_path_costs_fuzzily(new_path, old_path, 1.0000000001) == COSTS_BETTER1) remove_old = true; /* new dominates old */ else accept_new = false; /* old equals or * dominates new */ } else if (outercmp == BMS_SUBSET1 && new_path->rows <= old_path->rows && new_path->parallel_safe >= old_path->parallel_safe) remove_old = true; /* new dominates old */ else if (outercmp == BMS_SUBSET2 && new_path->rows >= old_path->rows && new_path->parallel_safe <= old_path->parallel_safe) accept_new = false; /* old dominates new */ /* else different parameterizations, keep both */ } break; case COSTS_BETTER1: if (keyscmp != PATHKEYS_BETTER2) { outercmp = bms_subset_compare(PATH_REQ_OUTER(new_path), PATH_REQ_OUTER(old_path)); if ((outercmp == BMS_EQUAL || outercmp == BMS_SUBSET1) && new_path->rows <= old_path->rows && new_path->parallel_safe >= old_path->parallel_safe) remove_old = true; /* new dominates old */ } break; case COSTS_BETTER2: if (keyscmp != PATHKEYS_BETTER1) { outercmp = bms_subset_compare(PATH_REQ_OUTER(new_path), PATH_REQ_OUTER(old_path)); if ((outercmp == BMS_EQUAL || outercmp == BMS_SUBSET2) && new_path->rows >= old_path->rows && new_path->parallel_safe <= old_path->parallel_safe) accept_new = false; /* old dominates new */ } break; case COSTS_DIFFERENT: /* * can't get here, but keep this case to keep compiler * quiet */ break; } } } /* * Remove current element from pathlist if dominated by new. */ if (remove_old) { parent_rel->pathlist = foreach_delete_current(parent_rel->pathlist, p1); /* * Delete the data pointed-to by the deleted cell, if possible */ if (!IsA(old_path, IndexPath)) pfree(old_path); } else { /* new belongs after this old path if it has cost >= old's */ if (new_path->total_cost >= old_path->total_cost) insert_at = foreach_current_index(p1) + 1; } /* * If we found an old path that dominates new_path, we can quit * scanning the pathlist; we will not add new_path, and we assume * new_path cannot dominate any other elements of the pathlist. */ if (!accept_new) break; } if (accept_new) { /* Accept the new path: insert it at proper place in pathlist */ parent_rel->pathlist = list_insert_nth(parent_rel->pathlist, insert_at, new_path); } else { /* Reject and recycle the new path */ if (!IsA(new_path, IndexPath)) pfree(new_path); } } /* * add_path_precheck * Check whether a proposed new path could possibly get accepted. * We assume we know the path's pathkeys and parameterization accurately, * and have lower bounds for its costs. * * Note that we do not know the path's rowcount, since getting an estimate for * that is too expensive to do before prechecking. We assume here that paths * of a superset parameterization will generate fewer rows; if that holds, * then paths with different parameterizations cannot dominate each other * and so we can simply ignore existing paths of another parameterization. * (In the infrequent cases where that rule of thumb fails, add_path will * get rid of the inferior path.) * * At the time this is called, we haven't actually built a Path structure, * so the required information has to be passed piecemeal. */ bool add_path_precheck(RelOptInfo *parent_rel, Cost startup_cost, Cost total_cost, List *pathkeys, Relids required_outer) { List *new_path_pathkeys; bool consider_startup; ListCell *p1; /* Pretend parameterized paths have no pathkeys, per add_path policy */ new_path_pathkeys = required_outer ? NIL : pathkeys; /* Decide whether new path's startup cost is interesting */ consider_startup = required_outer ? parent_rel->consider_param_startup : parent_rel->consider_startup; foreach(p1, parent_rel->pathlist) { Path *old_path = (Path *) lfirst(p1); PathKeysComparison keyscmp; /* * We are looking for an old_path with the same parameterization (and * by assumption the same rowcount) that dominates the new path on * pathkeys as well as both cost metrics. If we find one, we can * reject the new path. * * Cost comparisons here should match compare_path_costs_fuzzily. */ if (total_cost > old_path->total_cost * STD_FUZZ_FACTOR) { /* new path can win on startup cost only if consider_startup */ if (startup_cost > old_path->startup_cost * STD_FUZZ_FACTOR || !consider_startup) { /* new path loses on cost, so check pathkeys... */ List *old_path_pathkeys; old_path_pathkeys = old_path->param_info ? NIL : old_path->pathkeys; keyscmp = compare_pathkeys(new_path_pathkeys, old_path_pathkeys); if (keyscmp == PATHKEYS_EQUAL || keyscmp == PATHKEYS_BETTER2) { /* new path does not win on pathkeys... */ if (bms_equal(required_outer, PATH_REQ_OUTER(old_path))) { /* Found an old path that dominates the new one */ return false; } } } } else { /* * Since the pathlist is sorted by total_cost, we can stop looking * once we reach a path with a total_cost larger than the new * path's. */ break; } } return true; } /* * add_partial_path * Like add_path, our goal here is to consider whether a path is worthy * of being kept around, but the considerations here are a bit different. * A partial path is one which can be executed in any number of workers in * parallel such that each worker will generate a subset of the path's * overall result. * * As in add_path, the partial_pathlist is kept sorted with the cheapest * total path in front. This is depended on by multiple places, which * just take the front entry as the cheapest path without searching. * * We don't generate parameterized partial paths for several reasons. Most * importantly, they're not safe to execute, because there's nothing to * make sure that a parallel scan within the parameterized portion of the * plan is running with the same value in every worker at the same time. * Fortunately, it seems unlikely to be worthwhile anyway, because having * each worker scan the entire outer relation and a subset of the inner * relation will generally be a terrible plan. The inner (parameterized) * side of the plan will be small anyway. There could be rare cases where * this wins big - e.g. if join order constraints put a 1-row relation on * the outer side of the topmost join with a parameterized plan on the inner * side - but we'll have to be content not to handle such cases until * somebody builds an executor infrastructure that can cope with them. * * Because we don't consider parameterized paths here, we also don't * need to consider the row counts as a measure of quality: every path will * produce the same number of rows. Neither do we need to consider startup * costs: parallelism is only used for plans that will be run to completion. * Therefore, this routine is much simpler than add_path: it needs to * consider only pathkeys and total cost. * * As with add_path, we pfree paths that are found to be dominated by * another partial path; this requires that there be no other references to * such paths yet. Hence, GatherPaths must not be created for a rel until * we're done creating all partial paths for it. Unlike add_path, we don't * take an exception for IndexPaths as partial index paths won't be * referenced by partial BitmapHeapPaths. */ void add_partial_path(RelOptInfo *parent_rel, Path *new_path) { bool accept_new = true; /* unless we find a superior old path */ int insert_at = 0; /* where to insert new item */ ListCell *p1; /* Check for query cancel. */ CHECK_FOR_INTERRUPTS(); /* Path to be added must be parallel safe. */ Assert(new_path->parallel_safe); /* Relation should be OK for parallelism, too. */ Assert(parent_rel->consider_parallel); /* * As in add_path, throw out any paths which are dominated by the new * path, but throw out the new path if some existing path dominates it. */ foreach(p1, parent_rel->partial_pathlist) { Path *old_path = (Path *) lfirst(p1); bool remove_old = false; /* unless new proves superior */ PathKeysComparison keyscmp; /* Compare pathkeys. */ keyscmp = compare_pathkeys(new_path->pathkeys, old_path->pathkeys); /* Unless pathkeys are incompatible, keep just one of the two paths. */ if (keyscmp != PATHKEYS_DIFFERENT) { if (new_path->total_cost > old_path->total_cost * STD_FUZZ_FACTOR) { /* New path costs more; keep it only if pathkeys are better. */ if (keyscmp != PATHKEYS_BETTER1) accept_new = false; } else if (old_path->total_cost > new_path->total_cost * STD_FUZZ_FACTOR) { /* Old path costs more; keep it only if pathkeys are better. */ if (keyscmp != PATHKEYS_BETTER2) remove_old = true; } else if (keyscmp == PATHKEYS_BETTER1) { /* Costs are about the same, new path has better pathkeys. */ remove_old = true; } else if (keyscmp == PATHKEYS_BETTER2) { /* Costs are about the same, old path has better pathkeys. */ accept_new = false; } else if (old_path->total_cost > new_path->total_cost * 1.0000000001) { /* Pathkeys are the same, and the old path costs more. */ remove_old = true; } else { /* * Pathkeys are the same, and new path isn't materially * cheaper. */ accept_new = false; } } /* * Remove current element from partial_pathlist if dominated by new. */ if (remove_old) { parent_rel->partial_pathlist = foreach_delete_current(parent_rel->partial_pathlist, p1); pfree(old_path); } else { /* new belongs after this old path if it has cost >= old's */ if (new_path->total_cost >= old_path->total_cost) insert_at = foreach_current_index(p1) + 1; } /* * If we found an old path that dominates new_path, we can quit * scanning the partial_pathlist; we will not add new_path, and we * assume new_path cannot dominate any later path. */ if (!accept_new) break; } if (accept_new) { /* Accept the new path: insert it at proper place */ parent_rel->partial_pathlist = list_insert_nth(parent_rel->partial_pathlist, insert_at, new_path); } else { /* Reject and recycle the new path */ pfree(new_path); } } /* * add_partial_path_precheck * Check whether a proposed new partial path could possibly get accepted. * * Unlike add_path_precheck, we can ignore startup cost and parameterization, * since they don't matter for partial paths (see add_partial_path). But * we do want to make sure we don't add a partial path if there's already * a complete path that dominates it, since in that case the proposed path * is surely a loser. */ bool add_partial_path_precheck(RelOptInfo *parent_rel, Cost total_cost, List *pathkeys) { ListCell *p1; /* * Our goal here is twofold. First, we want to find out whether this path * is clearly inferior to some existing partial path. If so, we want to * reject it immediately. Second, we want to find out whether this path * is clearly superior to some existing partial path -- at least, modulo * final cost computations. If so, we definitely want to consider it. * * Unlike add_path(), we always compare pathkeys here. This is because we * expect partial_pathlist to be very short, and getting a definitive * answer at this stage avoids the need to call add_path_precheck. */ foreach(p1, parent_rel->partial_pathlist) { Path *old_path = (Path *) lfirst(p1); PathKeysComparison keyscmp; keyscmp = compare_pathkeys(pathkeys, old_path->pathkeys); if (keyscmp != PATHKEYS_DIFFERENT) { if (total_cost > old_path->total_cost * STD_FUZZ_FACTOR && keyscmp != PATHKEYS_BETTER1) return false; if (old_path->total_cost > total_cost * STD_FUZZ_FACTOR && keyscmp != PATHKEYS_BETTER2) return true; } } /* * This path is neither clearly inferior to an existing partial path nor * clearly good enough that it might replace one. Compare it to * non-parallel plans. If it loses even before accounting for the cost of * the Gather node, we should definitely reject it. * * Note that we pass the total_cost to add_path_precheck twice. This is * because it's never advantageous to consider the startup cost of a * partial path; the resulting plans, if run in parallel, will be run to * completion. */ if (!add_path_precheck(parent_rel, total_cost, total_cost, pathkeys, NULL)) return false; return true; } /***************************************************************************** * PATH NODE CREATION ROUTINES *****************************************************************************/ /* * create_seqscan_path * Creates a path corresponding to a sequential scan, returning the * pathnode. */ Path * create_seqscan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer, int parallel_workers) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_SeqScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = (parallel_workers > 0); pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = parallel_workers; pathnode->pathkeys = NIL; /* seqscan has unordered result */ cost_seqscan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_samplescan_path * Creates a path node for a sampled table scan. */ Path * create_samplescan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_SampleScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* samplescan has unordered result */ cost_samplescan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_index_path * Creates a path node for an index scan. * * 'index' is a usable index. * 'indexclauses' is a list of IndexClause nodes representing clauses * to be enforced as qual conditions in the scan. * 'indexorderbys' is a list of bare expressions (no RestrictInfos) * to be used as index ordering operators in the scan. * 'indexorderbycols' is an integer list of index column numbers (zero based) * the ordering operators can be used with. * 'pathkeys' describes the ordering of the path. * 'indexscandir' is either ForwardScanDirection or BackwardScanDirection. * 'indexonly' is true if an index-only scan is wanted. * 'required_outer' is the set of outer relids for a parameterized path. * 'loop_count' is the number of repetitions of the indexscan to factor into * estimates of caching behavior. * 'partial_path' is true if constructing a parallel index scan path. * * Returns the new path node. */ IndexPath * create_index_path(PlannerInfo *root, IndexOptInfo *index, List *indexclauses, List *indexorderbys, List *indexorderbycols, List *pathkeys, ScanDirection indexscandir, bool indexonly, Relids required_outer, double loop_count, bool partial_path) { IndexPath *pathnode = makeNode(IndexPath); RelOptInfo *rel = index->rel; pathnode->path.pathtype = indexonly ? T_IndexOnlyScan : T_IndexScan; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = pathkeys; pathnode->indexinfo = index; pathnode->indexclauses = indexclauses; pathnode->indexorderbys = indexorderbys; pathnode->indexorderbycols = indexorderbycols; pathnode->indexscandir = indexscandir; cost_index(pathnode, root, loop_count, partial_path); return pathnode; } /* * create_bitmap_heap_path * Creates a path node for a bitmap scan. * * 'bitmapqual' is a tree of IndexPath, BitmapAndPath, and BitmapOrPath nodes. * 'required_outer' is the set of outer relids for a parameterized path. * 'loop_count' is the number of repetitions of the indexscan to factor into * estimates of caching behavior. * * loop_count should match the value used when creating the component * IndexPaths. */ BitmapHeapPath * create_bitmap_heap_path(PlannerInfo *root, RelOptInfo *rel, Path *bitmapqual, Relids required_outer, double loop_count, int parallel_degree) { BitmapHeapPath *pathnode = makeNode(BitmapHeapPath); pathnode->path.pathtype = T_BitmapHeapScan; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = (parallel_degree > 0); pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = parallel_degree; pathnode->path.pathkeys = NIL; /* always unordered */ pathnode->bitmapqual = bitmapqual; cost_bitmap_heap_scan(&pathnode->path, root, rel, pathnode->path.param_info, bitmapqual, loop_count); return pathnode; } /* * create_bitmap_and_path * Creates a path node representing a BitmapAnd. */ BitmapAndPath * create_bitmap_and_path(PlannerInfo *root, RelOptInfo *rel, List *bitmapquals) { BitmapAndPath *pathnode = makeNode(BitmapAndPath); Relids required_outer = NULL; ListCell *lc; pathnode->path.pathtype = T_BitmapAnd; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; /* * Identify the required outer rels as the union of what the child paths * depend on. (Alternatively, we could insist that the caller pass this * in, but it's more convenient and reliable to compute it here.) */ foreach(lc, bitmapquals) { Path *bitmapqual = (Path *) lfirst(lc); required_outer = bms_add_members(required_outer, PATH_REQ_OUTER(bitmapqual)); } pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); /* * Currently, a BitmapHeapPath, BitmapAndPath, or BitmapOrPath will be * parallel-safe if and only if rel->consider_parallel is set. So, we can * set the flag for this path based only on the relation-level flag, * without actually iterating over the list of children. */ pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; /* always unordered */ pathnode->bitmapquals = bitmapquals; /* this sets bitmapselectivity as well as the regular cost fields: */ cost_bitmap_and_node(pathnode, root); return pathnode; } /* * create_bitmap_or_path * Creates a path node representing a BitmapOr. */ BitmapOrPath * create_bitmap_or_path(PlannerInfo *root, RelOptInfo *rel, List *bitmapquals) { BitmapOrPath *pathnode = makeNode(BitmapOrPath); Relids required_outer = NULL; ListCell *lc; pathnode->path.pathtype = T_BitmapOr; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; /* * Identify the required outer rels as the union of what the child paths * depend on. (Alternatively, we could insist that the caller pass this * in, but it's more convenient and reliable to compute it here.) */ foreach(lc, bitmapquals) { Path *bitmapqual = (Path *) lfirst(lc); required_outer = bms_add_members(required_outer, PATH_REQ_OUTER(bitmapqual)); } pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); /* * Currently, a BitmapHeapPath, BitmapAndPath, or BitmapOrPath will be * parallel-safe if and only if rel->consider_parallel is set. So, we can * set the flag for this path based only on the relation-level flag, * without actually iterating over the list of children. */ pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; /* always unordered */ pathnode->bitmapquals = bitmapquals; /* this sets bitmapselectivity as well as the regular cost fields: */ cost_bitmap_or_node(pathnode, root); return pathnode; } /* * create_tidscan_path * Creates a path corresponding to a scan by TID, returning the pathnode. */ TidPath * create_tidscan_path(PlannerInfo *root, RelOptInfo *rel, List *tidquals, Relids required_outer) { TidPath *pathnode = makeNode(TidPath); pathnode->path.pathtype = T_TidScan; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; /* always unordered */ pathnode->tidquals = tidquals; cost_tidscan(&pathnode->path, root, rel, tidquals, pathnode->path.param_info); return pathnode; } /* * create_tidrangescan_path * Creates a path corresponding to a scan by a range of TIDs, returning * the pathnode. */ TidRangePath * create_tidrangescan_path(PlannerInfo *root, RelOptInfo *rel, List *tidrangequals, Relids required_outer) { TidRangePath *pathnode = makeNode(TidRangePath); pathnode->path.pathtype = T_TidRangeScan; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; /* always unordered */ pathnode->tidrangequals = tidrangequals; cost_tidrangescan(&pathnode->path, root, rel, tidrangequals, pathnode->path.param_info); return pathnode; } /* * create_append_path * Creates a path corresponding to an Append plan, returning the * pathnode. * * Note that we must handle subpaths = NIL, representing a dummy access path. * Also, there are callers that pass root = NULL. */ AppendPath * create_append_path(PlannerInfo *root, RelOptInfo *rel, List *subpaths, List *partial_subpaths, List *pathkeys, Relids required_outer, int parallel_workers, bool parallel_aware, double rows) { AppendPath *pathnode = makeNode(AppendPath); ListCell *l; Assert(!parallel_aware || parallel_workers > 0); pathnode->path.pathtype = T_Append; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; /* * If this is for a baserel (not a join or non-leaf partition), we prefer * to apply get_baserel_parampathinfo to construct a full ParamPathInfo * for the path. This supports building a Memoize path atop this path, * and if this is a partitioned table the info may be useful for run-time * pruning (cf make_partition_pruneinfo()). * * However, if we don't have "root" then that won't work and we fall back * on the simpler get_appendrel_parampathinfo. There's no point in doing * the more expensive thing for a dummy path, either. */ if (rel->reloptkind == RELOPT_BASEREL && root && subpaths != NIL) pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); else pathnode->path.param_info = get_appendrel_parampathinfo(rel, required_outer); pathnode->path.parallel_aware = parallel_aware; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = parallel_workers; pathnode->path.pathkeys = pathkeys; /* * For parallel append, non-partial paths are sorted by descending total * costs. That way, the total time to finish all non-partial paths is * minimized. Also, the partial paths are sorted by descending startup * costs. There may be some paths that require to do startup work by a * single worker. In such case, it's better for workers to choose the * expensive ones first, whereas the leader should choose the cheapest * startup plan. */ if (pathnode->path.parallel_aware) { /* * We mustn't fiddle with the order of subpaths when the Append has * pathkeys. The order they're listed in is critical to keeping the * pathkeys valid. */ Assert(pathkeys == NIL); list_sort(subpaths, append_total_cost_compare); list_sort(partial_subpaths, append_startup_cost_compare); } pathnode->first_partial_path = list_length(subpaths); pathnode->subpaths = list_concat(subpaths, partial_subpaths); /* * Apply query-wide LIMIT if known and path is for sole base relation. * (Handling this at this low level is a bit klugy.) */ if (root != NULL && bms_equal(rel->relids, root->all_query_rels)) pathnode->limit_tuples = root->limit_tuples; else pathnode->limit_tuples = -1.0; foreach(l, pathnode->subpaths) { Path *subpath = (Path *) lfirst(l); pathnode->path.parallel_safe = pathnode->path.parallel_safe && subpath->parallel_safe; /* All child paths must have same parameterization */ Assert(bms_equal(PATH_REQ_OUTER(subpath), required_outer)); } Assert(!parallel_aware || pathnode->path.parallel_safe); /* * If there's exactly one child path then the output of the Append is * necessarily ordered the same as the child's, so we can inherit the * child's pathkeys if any, overriding whatever the caller might've said. * Furthermore, if the child's parallel awareness matches the Append's, * then the Append is a no-op and will be discarded later (in setrefs.c). * Then we can inherit the child's size and cost too, effectively charging * zero for the Append. Otherwise, we must do the normal costsize * calculation. */ if (list_length(pathnode->subpaths) == 1) { Path *child = (Path *) linitial(pathnode->subpaths); if (child->parallel_aware == parallel_aware) { pathnode->path.rows = child->rows; pathnode->path.startup_cost = child->startup_cost; pathnode->path.total_cost = child->total_cost; } else cost_append(pathnode); /* Must do this last, else cost_append complains */ pathnode->path.pathkeys = child->pathkeys; } else cost_append(pathnode); /* If the caller provided a row estimate, override the computed value. */ if (rows >= 0) pathnode->path.rows = rows; return pathnode; } /* * append_total_cost_compare * list_sort comparator for sorting append child paths * by total_cost descending * * For equal total costs, we fall back to comparing startup costs; if those * are equal too, break ties using bms_compare on the paths' relids. * (This is to avoid getting unpredictable results from list_sort.) */ static int append_total_cost_compare(const ListCell *a, const ListCell *b) { Path *path1 = (Path *) lfirst(a); Path *path2 = (Path *) lfirst(b); int cmp; cmp = compare_path_costs(path1, path2, TOTAL_COST); if (cmp != 0) return -cmp; return bms_compare(path1->parent->relids, path2->parent->relids); } /* * append_startup_cost_compare * list_sort comparator for sorting append child paths * by startup_cost descending * * For equal startup costs, we fall back to comparing total costs; if those * are equal too, break ties using bms_compare on the paths' relids. * (This is to avoid getting unpredictable results from list_sort.) */ static int append_startup_cost_compare(const ListCell *a, const ListCell *b) { Path *path1 = (Path *) lfirst(a); Path *path2 = (Path *) lfirst(b); int cmp; cmp = compare_path_costs(path1, path2, STARTUP_COST); if (cmp != 0) return -cmp; return bms_compare(path1->parent->relids, path2->parent->relids); } /* * create_merge_append_path * Creates a path corresponding to a MergeAppend plan, returning the * pathnode. */ MergeAppendPath * create_merge_append_path(PlannerInfo *root, RelOptInfo *rel, List *subpaths, List *pathkeys, Relids required_outer) { MergeAppendPath *pathnode = makeNode(MergeAppendPath); Cost input_startup_cost; Cost input_total_cost; ListCell *l; pathnode->path.pathtype = T_MergeAppend; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = get_appendrel_parampathinfo(rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = pathkeys; pathnode->subpaths = subpaths; /* * Apply query-wide LIMIT if known and path is for sole base relation. * (Handling this at this low level is a bit klugy.) */ if (bms_equal(rel->relids, root->all_query_rels)) pathnode->limit_tuples = root->limit_tuples; else pathnode->limit_tuples = -1.0; /* * Add up the sizes and costs of the input paths. */ pathnode->path.rows = 0; input_startup_cost = 0; input_total_cost = 0; foreach(l, subpaths) { Path *subpath = (Path *) lfirst(l); pathnode->path.rows += subpath->rows; pathnode->path.parallel_safe = pathnode->path.parallel_safe && subpath->parallel_safe; if (pathkeys_contained_in(pathkeys, subpath->pathkeys)) { /* Subpath is adequately ordered, we won't need to sort it */ input_startup_cost += subpath->startup_cost; input_total_cost += subpath->total_cost; } else { /* We'll need to insert a Sort node, so include cost for that */ Path sort_path; /* dummy for result of cost_sort */ cost_sort(&sort_path, root, pathkeys, subpath->total_cost, subpath->parent->tuples, subpath->pathtarget->width, 0.0, work_mem, pathnode->limit_tuples); input_startup_cost += sort_path.startup_cost; input_total_cost += sort_path.total_cost; } /* All child paths must have same parameterization */ Assert(bms_equal(PATH_REQ_OUTER(subpath), required_outer)); } /* * Now we can compute total costs of the MergeAppend. If there's exactly * one child path and its parallel awareness matches that of the * MergeAppend, then the MergeAppend is a no-op and will be discarded * later (in setrefs.c); otherwise we do the normal cost calculation. */ if (list_length(subpaths) == 1 && ((Path *) linitial(subpaths))->parallel_aware == pathnode->path.parallel_aware) { pathnode->path.startup_cost = input_startup_cost; pathnode->path.total_cost = input_total_cost; } else cost_merge_append(&pathnode->path, root, pathkeys, list_length(subpaths), input_startup_cost, input_total_cost, pathnode->path.rows); return pathnode; } /* * create_group_result_path * Creates a path representing a Result-and-nothing-else plan. * * This is only used for degenerate grouping cases, in which we know we * need to produce one result row, possibly filtered by a HAVING qual. */ GroupResultPath * create_group_result_path(PlannerInfo *root, RelOptInfo *rel, PathTarget *target, List *havingqual) { GroupResultPath *pathnode = makeNode(GroupResultPath); pathnode->path.pathtype = T_Result; pathnode->path.parent = rel; pathnode->path.pathtarget = target; pathnode->path.param_info = NULL; /* there are no other rels... */ pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; pathnode->quals = havingqual; /* * We can't quite use cost_resultscan() because the quals we want to * account for are not baserestrict quals of the rel. Might as well just * hack it here. */ pathnode->path.rows = 1; pathnode->path.startup_cost = target->cost.startup; pathnode->path.total_cost = target->cost.startup + cpu_tuple_cost + target->cost.per_tuple; /* * Add cost of qual, if any --- but we ignore its selectivity, since our * rowcount estimate should be 1 no matter what the qual is. */ if (havingqual) { QualCost qual_cost; cost_qual_eval(&qual_cost, havingqual, root); /* havingqual is evaluated once at startup */ pathnode->path.startup_cost += qual_cost.startup + qual_cost.per_tuple; pathnode->path.total_cost += qual_cost.startup + qual_cost.per_tuple; } return pathnode; } /* * create_material_path * Creates a path corresponding to a Material plan, returning the * pathnode. */ MaterialPath * create_material_path(RelOptInfo *rel, Path *subpath) { MaterialPath *pathnode = makeNode(MaterialPath); Assert(subpath->parent == rel); pathnode->path.pathtype = T_Material; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = subpath->param_info; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; cost_material(&pathnode->path, subpath->startup_cost, subpath->total_cost, subpath->rows, subpath->pathtarget->width); return pathnode; } /* * create_memoize_path * Creates a path corresponding to a Memoize plan, returning the pathnode. */ MemoizePath * create_memoize_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, List *param_exprs, List *hash_operators, bool singlerow, bool binary_mode, double calls) { MemoizePath *pathnode = makeNode(MemoizePath); Assert(subpath->parent == rel); pathnode->path.pathtype = T_Memoize; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = subpath->param_info; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; pathnode->hash_operators = hash_operators; pathnode->param_exprs = param_exprs; pathnode->singlerow = singlerow; pathnode->binary_mode = binary_mode; pathnode->calls = calls; /* * For now we set est_entries to 0. cost_memoize_rescan() does all the * hard work to determine how many cache entries there are likely to be, * so it seems best to leave it up to that function to fill this field in. * If left at 0, the executor will make a guess at a good value. */ pathnode->est_entries = 0; /* * Add a small additional charge for caching the first entry. All the * harder calculations for rescans are performed in cost_memoize_rescan(). */ pathnode->path.startup_cost = subpath->startup_cost + cpu_tuple_cost; pathnode->path.total_cost = subpath->total_cost + cpu_tuple_cost; pathnode->path.rows = subpath->rows; return pathnode; } /* * create_unique_path * Creates a path representing elimination of distinct rows from the * input data. Distinct-ness is defined according to the needs of the * semijoin represented by sjinfo. If it is not possible to identify * how to make the data unique, NULL is returned. * * If used at all, this is likely to be called repeatedly on the same rel; * and the input subpath should always be the same (the cheapest_total path * for the rel). So we cache the result. */ UniquePath * create_unique_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, SpecialJoinInfo *sjinfo) { UniquePath *pathnode; Path sort_path; /* dummy for result of cost_sort */ Path agg_path; /* dummy for result of cost_agg */ MemoryContext oldcontext; int numCols; /* Caller made a mistake if subpath isn't cheapest_total ... */ Assert(subpath == rel->cheapest_total_path); Assert(subpath->parent == rel); /* ... or if SpecialJoinInfo is the wrong one */ Assert(sjinfo->jointype == JOIN_SEMI); Assert(bms_equal(rel->relids, sjinfo->syn_righthand)); /* If result already cached, return it */ if (rel->cheapest_unique_path) return (UniquePath *) rel->cheapest_unique_path; /* If it's not possible to unique-ify, return NULL */ if (!(sjinfo->semi_can_btree || sjinfo->semi_can_hash)) return NULL; /* * When called during GEQO join planning, we are in a short-lived memory * context. We must make sure that the path and any subsidiary data * structures created for a baserel survive the GEQO cycle, else the * baserel is trashed for future GEQO cycles. On the other hand, when we * are creating those for a joinrel during GEQO, we don't want them to * clutter the main planning context. Upshot is that the best solution is * to explicitly allocate memory in the same context the given RelOptInfo * is in. */ oldcontext = MemoryContextSwitchTo(GetMemoryChunkContext(rel)); pathnode = makeNode(UniquePath); pathnode->path.pathtype = T_Unique; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = subpath->param_info; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; /* * Assume the output is unsorted, since we don't necessarily have pathkeys * to represent it. (This might get overridden below.) */ pathnode->path.pathkeys = NIL; pathnode->subpath = subpath; pathnode->in_operators = sjinfo->semi_operators; pathnode->uniq_exprs = sjinfo->semi_rhs_exprs; /* * If the input is a relation and it has a unique index that proves the * semi_rhs_exprs are unique, then we don't need to do anything. Note * that relation_has_unique_index_for automatically considers restriction * clauses for the rel, as well. */ if (rel->rtekind == RTE_RELATION && sjinfo->semi_can_btree && relation_has_unique_index_for(root, rel, NIL, sjinfo->semi_rhs_exprs, sjinfo->semi_operators)) { pathnode->umethod = UNIQUE_PATH_NOOP; pathnode->path.rows = rel->rows; pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost; pathnode->path.pathkeys = subpath->pathkeys; rel->cheapest_unique_path = (Path *) pathnode; MemoryContextSwitchTo(oldcontext); return pathnode; } /* * If the input is a subquery whose output must be unique already, then we * don't need to do anything. The test for uniqueness has to consider * exactly which columns we are extracting; for example "SELECT DISTINCT * x,y" doesn't guarantee that x alone is distinct. So we cannot check for * this optimization unless semi_rhs_exprs consists only of simple Vars * referencing subquery outputs. (Possibly we could do something with * expressions in the subquery outputs, too, but for now keep it simple.) */ if (rel->rtekind == RTE_SUBQUERY) { RangeTblEntry *rte = planner_rt_fetch(rel->relid, root); if (query_supports_distinctness(rte->subquery)) { List *sub_tlist_colnos; sub_tlist_colnos = translate_sub_tlist(sjinfo->semi_rhs_exprs, rel->relid); if (sub_tlist_colnos && query_is_distinct_for(rte->subquery, sub_tlist_colnos, sjinfo->semi_operators)) { pathnode->umethod = UNIQUE_PATH_NOOP; pathnode->path.rows = rel->rows; pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost; pathnode->path.pathkeys = subpath->pathkeys; rel->cheapest_unique_path = (Path *) pathnode; MemoryContextSwitchTo(oldcontext); return pathnode; } } } /* Estimate number of output rows */ pathnode->path.rows = estimate_num_groups(root, sjinfo->semi_rhs_exprs, rel->rows, NULL, NULL); numCols = list_length(sjinfo->semi_rhs_exprs); if (sjinfo->semi_can_btree) { /* * Estimate cost for sort+unique implementation */ cost_sort(&sort_path, root, NIL, subpath->total_cost, rel->rows, subpath->pathtarget->width, 0.0, work_mem, -1.0); /* * Charge one cpu_operator_cost per comparison per input tuple. We * assume all columns get compared at most of the tuples. (XXX * probably this is an overestimate.) This should agree with * create_upper_unique_path. */ sort_path.total_cost += cpu_operator_cost * rel->rows * numCols; } if (sjinfo->semi_can_hash) { /* * Estimate the overhead per hashtable entry at 64 bytes (same as in * planner.c). */ int hashentrysize = subpath->pathtarget->width + 64; if (hashentrysize * pathnode->path.rows > get_hash_memory_limit()) { /* * We should not try to hash. Hack the SpecialJoinInfo to * remember this, in case we come through here again. */ sjinfo->semi_can_hash = false; } else cost_agg(&agg_path, root, AGG_HASHED, NULL, numCols, pathnode->path.rows, NIL, subpath->startup_cost, subpath->total_cost, rel->rows, subpath->pathtarget->width); } if (sjinfo->semi_can_btree && sjinfo->semi_can_hash) { if (agg_path.total_cost < sort_path.total_cost) pathnode->umethod = UNIQUE_PATH_HASH; else pathnode->umethod = UNIQUE_PATH_SORT; } else if (sjinfo->semi_can_btree) pathnode->umethod = UNIQUE_PATH_SORT; else if (sjinfo->semi_can_hash) pathnode->umethod = UNIQUE_PATH_HASH; else { /* we can get here only if we abandoned hashing above */ MemoryContextSwitchTo(oldcontext); return NULL; } if (pathnode->umethod == UNIQUE_PATH_HASH) { pathnode->path.startup_cost = agg_path.startup_cost; pathnode->path.total_cost = agg_path.total_cost; } else { pathnode->path.startup_cost = sort_path.startup_cost; pathnode->path.total_cost = sort_path.total_cost; } rel->cheapest_unique_path = (Path *) pathnode; MemoryContextSwitchTo(oldcontext); return pathnode; } /* * create_gather_merge_path * * Creates a path corresponding to a gather merge scan, returning * the pathnode. */ GatherMergePath * create_gather_merge_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, PathTarget *target, List *pathkeys, Relids required_outer, double *rows) { GatherMergePath *pathnode = makeNode(GatherMergePath); Cost input_startup_cost = 0; Cost input_total_cost = 0; Assert(subpath->parallel_safe); Assert(pathkeys); pathnode->path.pathtype = T_GatherMerge; pathnode->path.parent = rel; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->subpath = subpath; pathnode->num_workers = subpath->parallel_workers; pathnode->path.pathkeys = pathkeys; pathnode->path.pathtarget = target ? target : rel->reltarget; pathnode->path.rows += subpath->rows; if (pathkeys_contained_in(pathkeys, subpath->pathkeys)) { /* Subpath is adequately ordered, we won't need to sort it */ input_startup_cost += subpath->startup_cost; input_total_cost += subpath->total_cost; } else { /* We'll need to insert a Sort node, so include cost for that */ Path sort_path; /* dummy for result of cost_sort */ cost_sort(&sort_path, root, pathkeys, subpath->total_cost, subpath->rows, subpath->pathtarget->width, 0.0, work_mem, -1); input_startup_cost += sort_path.startup_cost; input_total_cost += sort_path.total_cost; } cost_gather_merge(pathnode, root, rel, pathnode->path.param_info, input_startup_cost, input_total_cost, rows); return pathnode; } /* * translate_sub_tlist - get subquery column numbers represented by tlist * * The given targetlist usually contains only Vars referencing the given relid. * Extract their varattnos (ie, the column numbers of the subquery) and return * as an integer List. * * If any of the tlist items is not a simple Var, we cannot determine whether * the subquery's uniqueness condition (if any) matches ours, so punt and * return NIL. */ static List * translate_sub_tlist(List *tlist, int relid) { List *result = NIL; ListCell *l; foreach(l, tlist) { Var *var = (Var *) lfirst(l); if (!var || !IsA(var, Var) || var->varno != relid) return NIL; /* punt */ result = lappend_int(result, var->varattno); } return result; } /* * create_gather_path * Creates a path corresponding to a gather scan, returning the * pathnode. * * 'rows' may optionally be set to override row estimates from other sources. */ GatherPath * create_gather_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, PathTarget *target, Relids required_outer, double *rows) { GatherPath *pathnode = makeNode(GatherPath); Assert(subpath->parallel_safe); pathnode->path.pathtype = T_Gather; pathnode->path.parent = rel; pathnode->path.pathtarget = target; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = false; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; /* Gather has unordered result */ pathnode->subpath = subpath; pathnode->num_workers = subpath->parallel_workers; pathnode->single_copy = false; if (pathnode->num_workers == 0) { pathnode->path.pathkeys = subpath->pathkeys; pathnode->num_workers = 1; pathnode->single_copy = true; } cost_gather(pathnode, root, rel, pathnode->path.param_info, rows); return pathnode; } /* * create_subqueryscan_path * Creates a path corresponding to a scan of a subquery, * returning the pathnode. * * Caller must pass trivial_pathtarget = true if it believes rel->reltarget to * be trivial, ie just a fetch of all the subquery output columns in order. * While we could determine that here, the caller can usually do it more * efficiently (or at least amortize it over multiple calls). */ SubqueryScanPath * create_subqueryscan_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, bool trivial_pathtarget, List *pathkeys, Relids required_outer) { SubqueryScanPath *pathnode = makeNode(SubqueryScanPath); pathnode->path.pathtype = T_SubqueryScan; pathnode->path.parent = rel; pathnode->path.pathtarget = rel->reltarget; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->path.pathkeys = pathkeys; pathnode->subpath = subpath; cost_subqueryscan(pathnode, root, rel, pathnode->path.param_info, trivial_pathtarget); return pathnode; } /* * create_functionscan_path * Creates a path corresponding to a sequential scan of a function, * returning the pathnode. */ Path * create_functionscan_path(PlannerInfo *root, RelOptInfo *rel, List *pathkeys, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_FunctionScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = pathkeys; cost_functionscan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_tablefuncscan_path * Creates a path corresponding to a sequential scan of a table function, * returning the pathnode. */ Path * create_tablefuncscan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_TableFuncScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* result is always unordered */ cost_tablefuncscan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_valuesscan_path * Creates a path corresponding to a scan of a VALUES list, * returning the pathnode. */ Path * create_valuesscan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_ValuesScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* result is always unordered */ cost_valuesscan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_ctescan_path * Creates a path corresponding to a scan of a non-self-reference CTE, * returning the pathnode. */ Path * create_ctescan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_CteScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* XXX for now, result is always unordered */ cost_ctescan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_namedtuplestorescan_path * Creates a path corresponding to a scan of a named tuplestore, returning * the pathnode. */ Path * create_namedtuplestorescan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_NamedTuplestoreScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* result is always unordered */ cost_namedtuplestorescan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_resultscan_path * Creates a path corresponding to a scan of an RTE_RESULT relation, * returning the pathnode. */ Path * create_resultscan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_Result; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* result is always unordered */ cost_resultscan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_worktablescan_path * Creates a path corresponding to a scan of a self-reference CTE, * returning the pathnode. */ Path * create_worktablescan_path(PlannerInfo *root, RelOptInfo *rel, Relids required_outer) { Path *pathnode = makeNode(Path); pathnode->pathtype = T_WorkTableScan; pathnode->parent = rel; pathnode->pathtarget = rel->reltarget; pathnode->param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->parallel_aware = false; pathnode->parallel_safe = rel->consider_parallel; pathnode->parallel_workers = 0; pathnode->pathkeys = NIL; /* result is always unordered */ /* Cost is the same as for a regular CTE scan */ cost_ctescan(pathnode, root, rel, pathnode->param_info); return pathnode; } /* * create_foreignscan_path * Creates a path corresponding to a scan of a foreign base table, * returning the pathnode. * * This function is never called from core Postgres; rather, it's expected * to be called by the GetForeignPaths function of a foreign data wrapper. * We make the FDW supply all fields of the path, since we do not have any way * to calculate them in core. However, there is a usually-sane default for * the pathtarget (rel->reltarget), so we let a NULL for "target" select that. */ ForeignPath * create_foreignscan_path(PlannerInfo *root, RelOptInfo *rel, PathTarget *target, double rows, Cost startup_cost, Cost total_cost, List *pathkeys, Relids required_outer, Path *fdw_outerpath, List *fdw_restrictinfo, List *fdw_private) { ForeignPath *pathnode = makeNode(ForeignPath); /* Historically some FDWs were confused about when to use this */ Assert(IS_SIMPLE_REL(rel)); pathnode->path.pathtype = T_ForeignScan; pathnode->path.parent = rel; pathnode->path.pathtarget = target ? target : rel->reltarget; pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.rows = rows; pathnode->path.startup_cost = startup_cost; pathnode->path.total_cost = total_cost; pathnode->path.pathkeys = pathkeys; pathnode->fdw_outerpath = fdw_outerpath; pathnode->fdw_restrictinfo = fdw_restrictinfo; pathnode->fdw_private = fdw_private; return pathnode; } /* * create_foreign_join_path * Creates a path corresponding to a scan of a foreign join, * returning the pathnode. * * This function is never called from core Postgres; rather, it's expected * to be called by the GetForeignJoinPaths function of a foreign data wrapper. * We make the FDW supply all fields of the path, since we do not have any way * to calculate them in core. However, there is a usually-sane default for * the pathtarget (rel->reltarget), so we let a NULL for "target" select that. */ ForeignPath * create_foreign_join_path(PlannerInfo *root, RelOptInfo *rel, PathTarget *target, double rows, Cost startup_cost, Cost total_cost, List *pathkeys, Relids required_outer, Path *fdw_outerpath, List *fdw_restrictinfo, List *fdw_private) { ForeignPath *pathnode = makeNode(ForeignPath); /* * We should use get_joinrel_parampathinfo to handle parameterized paths, * but the API of this function doesn't support it, and existing * extensions aren't yet trying to build such paths anyway. For the * moment just throw an error if someone tries it; eventually we should * revisit this. */ if (!bms_is_empty(required_outer) || !bms_is_empty(rel->lateral_relids)) elog(ERROR, "parameterized foreign joins are not supported yet"); pathnode->path.pathtype = T_ForeignScan; pathnode->path.parent = rel; pathnode->path.pathtarget = target ? target : rel->reltarget; pathnode->path.param_info = NULL; /* XXX see above */ pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.rows = rows; pathnode->path.startup_cost = startup_cost; pathnode->path.total_cost = total_cost; pathnode->path.pathkeys = pathkeys; pathnode->fdw_outerpath = fdw_outerpath; pathnode->fdw_restrictinfo = fdw_restrictinfo; pathnode->fdw_private = fdw_private; return pathnode; } /* * create_foreign_upper_path * Creates a path corresponding to an upper relation that's computed * directly by an FDW, returning the pathnode. * * This function is never called from core Postgres; rather, it's expected to * be called by the GetForeignUpperPaths function of a foreign data wrapper. * We make the FDW supply all fields of the path, since we do not have any way * to calculate them in core. However, there is a usually-sane default for * the pathtarget (rel->reltarget), so we let a NULL for "target" select that. */ ForeignPath * create_foreign_upper_path(PlannerInfo *root, RelOptInfo *rel, PathTarget *target, double rows, Cost startup_cost, Cost total_cost, List *pathkeys, Path *fdw_outerpath, List *fdw_restrictinfo, List *fdw_private) { ForeignPath *pathnode = makeNode(ForeignPath); /* * Upper relations should never have any lateral references, since joining * is complete. */ Assert(bms_is_empty(rel->lateral_relids)); pathnode->path.pathtype = T_ForeignScan; pathnode->path.parent = rel; pathnode->path.pathtarget = target ? target : rel->reltarget; pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel; pathnode->path.parallel_workers = 0; pathnode->path.rows = rows; pathnode->path.startup_cost = startup_cost; pathnode->path.total_cost = total_cost; pathnode->path.pathkeys = pathkeys; pathnode->fdw_outerpath = fdw_outerpath; pathnode->fdw_restrictinfo = fdw_restrictinfo; pathnode->fdw_private = fdw_private; return pathnode; } /* * calc_nestloop_required_outer * Compute the required_outer set for a nestloop join path * * Note: result must not share storage with either input */ Relids calc_nestloop_required_outer(Relids outerrelids, Relids outer_paramrels, Relids innerrelids, Relids inner_paramrels) { Relids required_outer; /* inner_path can require rels from outer path, but not vice versa */ Assert(!bms_overlap(outer_paramrels, innerrelids)); /* easy case if inner path is not parameterized */ if (!inner_paramrels) return bms_copy(outer_paramrels); /* else, form the union ... */ required_outer = bms_union(outer_paramrels, inner_paramrels); /* ... and remove any mention of now-satisfied outer rels */ required_outer = bms_del_members(required_outer, outerrelids); return required_outer; } /* * calc_non_nestloop_required_outer * Compute the required_outer set for a merge or hash join path * * Note: result must not share storage with either input */ Relids calc_non_nestloop_required_outer(Path *outer_path, Path *inner_path) { Relids outer_paramrels = PATH_REQ_OUTER(outer_path); Relids inner_paramrels = PATH_REQ_OUTER(inner_path); Relids required_outer; /* neither path can require rels from the other */ Assert(!bms_overlap(outer_paramrels, inner_path->parent->relids)); Assert(!bms_overlap(inner_paramrels, outer_path->parent->relids)); /* form the union ... */ required_outer = bms_union(outer_paramrels, inner_paramrels); /* we do not need an explicit test for empty; bms_union gets it right */ return required_outer; } /* * create_nestloop_path * Creates a pathnode corresponding to a nestloop join between two * relations. * * 'joinrel' is the join relation. * 'jointype' is the type of join required * 'workspace' is the result from initial_cost_nestloop * 'extra' contains various information about the join * 'outer_path' is the outer path * 'inner_path' is the inner path * 'restrict_clauses' are the RestrictInfo nodes to apply at the join * 'pathkeys' are the path keys of the new join path * 'required_outer' is the set of required outer rels * * Returns the resulting path node. */ NestPath * create_nestloop_path(PlannerInfo *root, RelOptInfo *joinrel, JoinType jointype, JoinCostWorkspace *workspace, JoinPathExtraData *extra, Path *outer_path, Path *inner_path, List *restrict_clauses, List *pathkeys, Relids required_outer) { NestPath *pathnode = makeNode(NestPath); Relids inner_req_outer = PATH_REQ_OUTER(inner_path); /* * If the inner path is parameterized by the outer, we must drop any * restrict_clauses that are due to be moved into the inner path. We have * to do this now, rather than postpone the work till createplan time, * because the restrict_clauses list can affect the size and cost * estimates for this path. We detect such clauses by checking for serial * number match to clauses already enforced in the inner path. */ if (bms_overlap(inner_req_outer, outer_path->parent->relids)) { Bitmapset *enforced_serials = get_param_path_clause_serials(inner_path); List *jclauses = NIL; ListCell *lc; foreach(lc, restrict_clauses) { RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc); if (!bms_is_member(rinfo->rinfo_serial, enforced_serials)) jclauses = lappend(jclauses, rinfo); } restrict_clauses = jclauses; } pathnode->jpath.path.pathtype = T_NestLoop; pathnode->jpath.path.parent = joinrel; pathnode->jpath.path.pathtarget = joinrel->reltarget; pathnode->jpath.path.param_info = get_joinrel_parampathinfo(root, joinrel, outer_path, inner_path, extra->sjinfo, required_outer, &restrict_clauses); pathnode->jpath.path.parallel_aware = false; pathnode->jpath.path.parallel_safe = joinrel->consider_parallel && outer_path->parallel_safe && inner_path->parallel_safe; /* This is a foolish way to estimate parallel_workers, but for now... */ pathnode->jpath.path.parallel_workers = outer_path->parallel_workers; pathnode->jpath.path.pathkeys = pathkeys; pathnode->jpath.jointype = jointype; pathnode->jpath.inner_unique = extra->inner_unique; pathnode->jpath.outerjoinpath = outer_path; pathnode->jpath.innerjoinpath = inner_path; pathnode->jpath.joinrestrictinfo = restrict_clauses; final_cost_nestloop(root, pathnode, workspace, extra); return pathnode; } /* * create_mergejoin_path * Creates a pathnode corresponding to a mergejoin join between * two relations * * 'joinrel' is the join relation * 'jointype' is the type of join required * 'workspace' is the result from initial_cost_mergejoin * 'extra' contains various information about the join * 'outer_path' is the outer path * 'inner_path' is the inner path * 'restrict_clauses' are the RestrictInfo nodes to apply at the join * 'pathkeys' are the path keys of the new join path * 'required_outer' is the set of required outer rels * 'mergeclauses' are the RestrictInfo nodes to use as merge clauses * (this should be a subset of the restrict_clauses list) * 'outersortkeys' are the sort varkeys for the outer relation * 'innersortkeys' are the sort varkeys for the inner relation */ MergePath * create_mergejoin_path(PlannerInfo *root, RelOptInfo *joinrel, JoinType jointype, JoinCostWorkspace *workspace, JoinPathExtraData *extra, Path *outer_path, Path *inner_path, List *restrict_clauses, List *pathkeys, Relids required_outer, List *mergeclauses, List *outersortkeys, List *innersortkeys) { MergePath *pathnode = makeNode(MergePath); pathnode->jpath.path.pathtype = T_MergeJoin; pathnode->jpath.path.parent = joinrel; pathnode->jpath.path.pathtarget = joinrel->reltarget; pathnode->jpath.path.param_info = get_joinrel_parampathinfo(root, joinrel, outer_path, inner_path, extra->sjinfo, required_outer, &restrict_clauses); pathnode->jpath.path.parallel_aware = false; pathnode->jpath.path.parallel_safe = joinrel->consider_parallel && outer_path->parallel_safe && inner_path->parallel_safe; /* This is a foolish way to estimate parallel_workers, but for now... */ pathnode->jpath.path.parallel_workers = outer_path->parallel_workers; pathnode->jpath.path.pathkeys = pathkeys; pathnode->jpath.jointype = jointype; pathnode->jpath.inner_unique = extra->inner_unique; pathnode->jpath.outerjoinpath = outer_path; pathnode->jpath.innerjoinpath = inner_path; pathnode->jpath.joinrestrictinfo = restrict_clauses; pathnode->path_mergeclauses = mergeclauses; pathnode->outersortkeys = outersortkeys; pathnode->innersortkeys = innersortkeys; /* pathnode->skip_mark_restore will be set by final_cost_mergejoin */ /* pathnode->materialize_inner will be set by final_cost_mergejoin */ final_cost_mergejoin(root, pathnode, workspace, extra); return pathnode; } /* * create_hashjoin_path * Creates a pathnode corresponding to a hash join between two relations. * * 'joinrel' is the join relation * 'jointype' is the type of join required * 'workspace' is the result from initial_cost_hashjoin * 'extra' contains various information about the join * 'outer_path' is the cheapest outer path * 'inner_path' is the cheapest inner path * 'parallel_hash' to select Parallel Hash of inner path (shared hash table) * 'restrict_clauses' are the RestrictInfo nodes to apply at the join * 'required_outer' is the set of required outer rels * 'hashclauses' are the RestrictInfo nodes to use as hash clauses * (this should be a subset of the restrict_clauses list) */ HashPath * create_hashjoin_path(PlannerInfo *root, RelOptInfo *joinrel, JoinType jointype, JoinCostWorkspace *workspace, JoinPathExtraData *extra, Path *outer_path, Path *inner_path, bool parallel_hash, List *restrict_clauses, Relids required_outer, List *hashclauses) { HashPath *pathnode = makeNode(HashPath); pathnode->jpath.path.pathtype = T_HashJoin; pathnode->jpath.path.parent = joinrel; pathnode->jpath.path.pathtarget = joinrel->reltarget; pathnode->jpath.path.param_info = get_joinrel_parampathinfo(root, joinrel, outer_path, inner_path, extra->sjinfo, required_outer, &restrict_clauses); pathnode->jpath.path.parallel_aware = joinrel->consider_parallel && parallel_hash; pathnode->jpath.path.parallel_safe = joinrel->consider_parallel && outer_path->parallel_safe && inner_path->parallel_safe; /* This is a foolish way to estimate parallel_workers, but for now... */ pathnode->jpath.path.parallel_workers = outer_path->parallel_workers; /* * A hashjoin never has pathkeys, since its output ordering is * unpredictable due to possible batching. XXX If the inner relation is * small enough, we could instruct the executor that it must not batch, * and then we could assume that the output inherits the outer relation's * ordering, which might save a sort step. However there is considerable * downside if our estimate of the inner relation size is badly off. For * the moment we don't risk it. (Note also that if we wanted to take this * seriously, joinpath.c would have to consider many more paths for the * outer rel than it does now.) */ pathnode->jpath.path.pathkeys = NIL; pathnode->jpath.jointype = jointype; pathnode->jpath.inner_unique = extra->inner_unique; pathnode->jpath.outerjoinpath = outer_path; pathnode->jpath.innerjoinpath = inner_path; pathnode->jpath.joinrestrictinfo = restrict_clauses; pathnode->path_hashclauses = hashclauses; /* final_cost_hashjoin will fill in pathnode->num_batches */ final_cost_hashjoin(root, pathnode, workspace, extra); return pathnode; } /* * create_projection_path * Creates a pathnode that represents performing a projection. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'target' is the PathTarget to be computed */ ProjectionPath * create_projection_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, PathTarget *target) { ProjectionPath *pathnode = makeNode(ProjectionPath); PathTarget *oldtarget; /* * We mustn't put a ProjectionPath directly above another; it's useless * and will confuse create_projection_plan. Rather than making sure all * callers handle that, let's implement it here, by stripping off any * ProjectionPath in what we're given. Given this rule, there won't be * more than one. */ if (IsA(subpath, ProjectionPath)) { ProjectionPath *subpp = (ProjectionPath *) subpath; Assert(subpp->path.parent == rel); subpath = subpp->subpath; Assert(!IsA(subpath, ProjectionPath)); } pathnode->path.pathtype = T_Result; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe && is_parallel_safe(root, (Node *) target->exprs); pathnode->path.parallel_workers = subpath->parallel_workers; /* Projection does not change the sort order */ pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; /* * We might not need a separate Result node. If the input plan node type * can project, we can just tell it to project something else. Or, if it * can't project but the desired target has the same expression list as * what the input will produce anyway, we can still give it the desired * tlist (possibly changing its ressortgroupref labels, but nothing else). * Note: in the latter case, create_projection_plan has to recheck our * conclusion; see comments therein. */ oldtarget = subpath->pathtarget; if (is_projection_capable_path(subpath) || equal(oldtarget->exprs, target->exprs)) { /* No separate Result node needed */ pathnode->dummypp = true; /* * Set cost of plan as subpath's cost, adjusted for tlist replacement. */ pathnode->path.rows = subpath->rows; pathnode->path.startup_cost = subpath->startup_cost + (target->cost.startup - oldtarget->cost.startup); pathnode->path.total_cost = subpath->total_cost + (target->cost.startup - oldtarget->cost.startup) + (target->cost.per_tuple - oldtarget->cost.per_tuple) * subpath->rows; } else { /* We really do need the Result node */ pathnode->dummypp = false; /* * The Result node's cost is cpu_tuple_cost per row, plus the cost of * evaluating the tlist. There is no qual to worry about. */ pathnode->path.rows = subpath->rows; pathnode->path.startup_cost = subpath->startup_cost + target->cost.startup; pathnode->path.total_cost = subpath->total_cost + target->cost.startup + (cpu_tuple_cost + target->cost.per_tuple) * subpath->rows; } return pathnode; } /* * apply_projection_to_path * Add a projection step, or just apply the target directly to given path. * * This has the same net effect as create_projection_path(), except that if * a separate Result plan node isn't needed, we just replace the given path's * pathtarget with the desired one. This must be used only when the caller * knows that the given path isn't referenced elsewhere and so can be modified * in-place. * * If the input path is a GatherPath or GatherMergePath, we try to push the * new target down to its input as well; this is a yet more invasive * modification of the input path, which create_projection_path() can't do. * * Note that we mustn't change the source path's parent link; so when it is * add_path'd to "rel" things will be a bit inconsistent. So far that has * not caused any trouble. * * 'rel' is the parent relation associated with the result * 'path' is the path representing the source of data * 'target' is the PathTarget to be computed */ Path * apply_projection_to_path(PlannerInfo *root, RelOptInfo *rel, Path *path, PathTarget *target) { QualCost oldcost; /* * If given path can't project, we might need a Result node, so make a * separate ProjectionPath. */ if (!is_projection_capable_path(path)) return (Path *) create_projection_path(root, rel, path, target); /* * We can just jam the desired tlist into the existing path, being sure to * update its cost estimates appropriately. */ oldcost = path->pathtarget->cost; path->pathtarget = target; path->startup_cost += target->cost.startup - oldcost.startup; path->total_cost += target->cost.startup - oldcost.startup + (target->cost.per_tuple - oldcost.per_tuple) * path->rows; /* * If the path happens to be a Gather or GatherMerge path, we'd like to * arrange for the subpath to return the required target list so that * workers can help project. But if there is something that is not * parallel-safe in the target expressions, then we can't. */ if ((IsA(path, GatherPath) || IsA(path, GatherMergePath)) && is_parallel_safe(root, (Node *) target->exprs)) { /* * We always use create_projection_path here, even if the subpath is * projection-capable, so as to avoid modifying the subpath in place. * It seems unlikely at present that there could be any other * references to the subpath, but better safe than sorry. * * Note that we don't change the parallel path's cost estimates; it * might be appropriate to do so, to reflect the fact that the bulk of * the target evaluation will happen in workers. */ if (IsA(path, GatherPath)) { GatherPath *gpath = (GatherPath *) path; gpath->subpath = (Path *) create_projection_path(root, gpath->subpath->parent, gpath->subpath, target); } else { GatherMergePath *gmpath = (GatherMergePath *) path; gmpath->subpath = (Path *) create_projection_path(root, gmpath->subpath->parent, gmpath->subpath, target); } } else if (path->parallel_safe && !is_parallel_safe(root, (Node *) target->exprs)) { /* * We're inserting a parallel-restricted target list into a path * currently marked parallel-safe, so we have to mark it as no longer * safe. */ path->parallel_safe = false; } return path; } /* * create_set_projection_path * Creates a pathnode that represents performing a projection that * includes set-returning functions. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'target' is the PathTarget to be computed */ ProjectSetPath * create_set_projection_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, PathTarget *target) { ProjectSetPath *pathnode = makeNode(ProjectSetPath); double tlist_rows; ListCell *lc; pathnode->path.pathtype = T_ProjectSet; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe && is_parallel_safe(root, (Node *) target->exprs); pathnode->path.parallel_workers = subpath->parallel_workers; /* Projection does not change the sort order XXX? */ pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; /* * Estimate number of rows produced by SRFs for each row of input; if * there's more than one in this node, use the maximum. */ tlist_rows = 1; foreach(lc, target->exprs) { Node *node = (Node *) lfirst(lc); double itemrows; itemrows = expression_returns_set_rows(root, node); if (tlist_rows < itemrows) tlist_rows = itemrows; } /* * In addition to the cost of evaluating the tlist, charge cpu_tuple_cost * per input row, and half of cpu_tuple_cost for each added output row. * This is slightly bizarre maybe, but it's what 9.6 did; we may revisit * this estimate later. */ pathnode->path.rows = subpath->rows * tlist_rows; pathnode->path.startup_cost = subpath->startup_cost + target->cost.startup; pathnode->path.total_cost = subpath->total_cost + target->cost.startup + (cpu_tuple_cost + target->cost.per_tuple) * subpath->rows + (pathnode->path.rows - subpath->rows) * cpu_tuple_cost / 2; return pathnode; } /* * create_incremental_sort_path * Creates a pathnode that represents performing an incremental sort. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'pathkeys' represents the desired sort order * 'presorted_keys' is the number of keys by which the input path is * already sorted * 'limit_tuples' is the estimated bound on the number of output tuples, * or -1 if no LIMIT or couldn't estimate */ IncrementalSortPath * create_incremental_sort_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, List *pathkeys, int presorted_keys, double limit_tuples) { IncrementalSortPath *sort = makeNode(IncrementalSortPath); SortPath *pathnode = &sort->spath; pathnode->path.pathtype = T_IncrementalSort; pathnode->path.parent = rel; /* Sort doesn't project, so use source path's pathtarget */ pathnode->path.pathtarget = subpath->pathtarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->path.pathkeys = pathkeys; pathnode->subpath = subpath; cost_incremental_sort(&pathnode->path, root, pathkeys, presorted_keys, subpath->startup_cost, subpath->total_cost, subpath->rows, subpath->pathtarget->width, 0.0, /* XXX comparison_cost shouldn't be 0? */ work_mem, limit_tuples); sort->nPresortedCols = presorted_keys; return sort; } /* * create_sort_path * Creates a pathnode that represents performing an explicit sort. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'pathkeys' represents the desired sort order * 'limit_tuples' is the estimated bound on the number of output tuples, * or -1 if no LIMIT or couldn't estimate */ SortPath * create_sort_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, List *pathkeys, double limit_tuples) { SortPath *pathnode = makeNode(SortPath); pathnode->path.pathtype = T_Sort; pathnode->path.parent = rel; /* Sort doesn't project, so use source path's pathtarget */ pathnode->path.pathtarget = subpath->pathtarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->path.pathkeys = pathkeys; pathnode->subpath = subpath; cost_sort(&pathnode->path, root, pathkeys, subpath->total_cost, subpath->rows, subpath->pathtarget->width, 0.0, /* XXX comparison_cost shouldn't be 0? */ work_mem, limit_tuples); return pathnode; } /* * create_group_path * Creates a pathnode that represents performing grouping of presorted input * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'target' is the PathTarget to be computed * 'groupClause' is a list of SortGroupClause's representing the grouping * 'qual' is the HAVING quals if any * 'numGroups' is the estimated number of groups */ GroupPath * create_group_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, List *groupClause, List *qual, double numGroups) { GroupPath *pathnode = makeNode(GroupPath); PathTarget *target = rel->reltarget; pathnode->path.pathtype = T_Group; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; /* Group doesn't change sort ordering */ pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; pathnode->groupClause = groupClause; pathnode->qual = qual; cost_group(&pathnode->path, root, list_length(groupClause), numGroups, qual, subpath->startup_cost, subpath->total_cost, subpath->rows); /* add tlist eval cost for each output row */ pathnode->path.startup_cost += target->cost.startup; pathnode->path.total_cost += target->cost.startup + target->cost.per_tuple * pathnode->path.rows; return pathnode; } /* * create_upper_unique_path * Creates a pathnode that represents performing an explicit Unique step * on presorted input. * * This produces a Unique plan node, but the use-case is so different from * create_unique_path that it doesn't seem worth trying to merge the two. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'numCols' is the number of grouping columns * 'numGroups' is the estimated number of groups * * The input path must be sorted on the grouping columns, plus possibly * additional columns; so the first numCols pathkeys are the grouping columns */ UpperUniquePath * create_upper_unique_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, int numCols, double numGroups) { UpperUniquePath *pathnode = makeNode(UpperUniquePath); pathnode->path.pathtype = T_Unique; pathnode->path.parent = rel; /* Unique doesn't project, so use source path's pathtarget */ pathnode->path.pathtarget = subpath->pathtarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; /* Unique doesn't change the input ordering */ pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; pathnode->numkeys = numCols; /* * Charge one cpu_operator_cost per comparison per input tuple. We assume * all columns get compared at most of the tuples. (XXX probably this is * an overestimate.) */ pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost + cpu_operator_cost * subpath->rows * numCols; pathnode->path.rows = numGroups; return pathnode; } /* * create_agg_path * Creates a pathnode that represents performing aggregation/grouping * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'target' is the PathTarget to be computed * 'aggstrategy' is the Agg node's basic implementation strategy * 'aggsplit' is the Agg node's aggregate-splitting mode * 'groupClause' is a list of SortGroupClause's representing the grouping * 'qual' is the HAVING quals if any * 'aggcosts' contains cost info about the aggregate functions to be computed * 'numGroups' is the estimated number of groups (1 if not grouping) */ AggPath * create_agg_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, PathTarget *target, AggStrategy aggstrategy, AggSplit aggsplit, List *groupClause, List *qual, const AggClauseCosts *aggcosts, double numGroups) { AggPath *pathnode = makeNode(AggPath); pathnode->path.pathtype = T_Agg; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; if (aggstrategy == AGG_SORTED) { /* * Attempt to preserve the order of the subpath. Additional pathkeys * may have been added in adjust_group_pathkeys_for_groupagg() to * support ORDER BY / DISTINCT aggregates. Pathkeys added there * belong to columns within the aggregate function, so we must strip * these additional pathkeys off as those columns are unavailable * above the aggregate node. */ if (list_length(subpath->pathkeys) > root->num_groupby_pathkeys) pathnode->path.pathkeys = list_copy_head(subpath->pathkeys, root->num_groupby_pathkeys); else pathnode->path.pathkeys = subpath->pathkeys; /* preserves order */ } else pathnode->path.pathkeys = NIL; /* output is unordered */ pathnode->subpath = subpath; pathnode->aggstrategy = aggstrategy; pathnode->aggsplit = aggsplit; pathnode->numGroups = numGroups; pathnode->transitionSpace = aggcosts ? aggcosts->transitionSpace : 0; pathnode->groupClause = groupClause; pathnode->qual = qual; cost_agg(&pathnode->path, root, aggstrategy, aggcosts, list_length(groupClause), numGroups, qual, subpath->startup_cost, subpath->total_cost, subpath->rows, subpath->pathtarget->width); /* add tlist eval cost for each output row */ pathnode->path.startup_cost += target->cost.startup; pathnode->path.total_cost += target->cost.startup + target->cost.per_tuple * pathnode->path.rows; return pathnode; } /* * create_groupingsets_path * Creates a pathnode that represents performing GROUPING SETS aggregation * * GroupingSetsPath represents sorted grouping with one or more grouping sets. * The input path's result must be sorted to match the last entry in * rollup_groupclauses. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'target' is the PathTarget to be computed * 'having_qual' is the HAVING quals if any * 'rollups' is a list of RollupData nodes * 'agg_costs' contains cost info about the aggregate functions to be computed */ GroupingSetsPath * create_groupingsets_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, List *having_qual, AggStrategy aggstrategy, List *rollups, const AggClauseCosts *agg_costs) { GroupingSetsPath *pathnode = makeNode(GroupingSetsPath); PathTarget *target = rel->reltarget; ListCell *lc; bool is_first = true; bool is_first_sort = true; /* The topmost generated Plan node will be an Agg */ pathnode->path.pathtype = T_Agg; pathnode->path.parent = rel; pathnode->path.pathtarget = target; pathnode->path.param_info = subpath->param_info; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->subpath = subpath; /* * Simplify callers by downgrading AGG_SORTED to AGG_PLAIN, and AGG_MIXED * to AGG_HASHED, here if possible. */ if (aggstrategy == AGG_SORTED && list_length(rollups) == 1 && ((RollupData *) linitial(rollups))->groupClause == NIL) aggstrategy = AGG_PLAIN; if (aggstrategy == AGG_MIXED && list_length(rollups) == 1) aggstrategy = AGG_HASHED; /* * Output will be in sorted order by group_pathkeys if, and only if, there * is a single rollup operation on a non-empty list of grouping * expressions. */ if (aggstrategy == AGG_SORTED && list_length(rollups) == 1) pathnode->path.pathkeys = root->group_pathkeys; else pathnode->path.pathkeys = NIL; pathnode->aggstrategy = aggstrategy; pathnode->rollups = rollups; pathnode->qual = having_qual; pathnode->transitionSpace = agg_costs ? agg_costs->transitionSpace : 0; Assert(rollups != NIL); Assert(aggstrategy != AGG_PLAIN || list_length(rollups) == 1); Assert(aggstrategy != AGG_MIXED || list_length(rollups) > 1); foreach(lc, rollups) { RollupData *rollup = lfirst(lc); List *gsets = rollup->gsets; int numGroupCols = list_length(linitial(gsets)); /* * In AGG_SORTED or AGG_PLAIN mode, the first rollup takes the * (already-sorted) input, and following ones do their own sort. * * In AGG_HASHED mode, there is one rollup for each grouping set. * * In AGG_MIXED mode, the first rollups are hashed, the first * non-hashed one takes the (already-sorted) input, and following ones * do their own sort. */ if (is_first) { cost_agg(&pathnode->path, root, aggstrategy, agg_costs, numGroupCols, rollup->numGroups, having_qual, subpath->startup_cost, subpath->total_cost, subpath->rows, subpath->pathtarget->width); is_first = false; if (!rollup->is_hashed) is_first_sort = false; } else { Path sort_path; /* dummy for result of cost_sort */ Path agg_path; /* dummy for result of cost_agg */ if (rollup->is_hashed || is_first_sort) { /* * Account for cost of aggregation, but don't charge input * cost again */ cost_agg(&agg_path, root, rollup->is_hashed ? AGG_HASHED : AGG_SORTED, agg_costs, numGroupCols, rollup->numGroups, having_qual, 0.0, 0.0, subpath->rows, subpath->pathtarget->width); if (!rollup->is_hashed) is_first_sort = false; } else { /* Account for cost of sort, but don't charge input cost again */ cost_sort(&sort_path, root, NIL, 0.0, subpath->rows, subpath->pathtarget->width, 0.0, work_mem, -1.0); /* Account for cost of aggregation */ cost_agg(&agg_path, root, AGG_SORTED, agg_costs, numGroupCols, rollup->numGroups, having_qual, sort_path.startup_cost, sort_path.total_cost, sort_path.rows, subpath->pathtarget->width); } pathnode->path.total_cost += agg_path.total_cost; pathnode->path.rows += agg_path.rows; } } /* add tlist eval cost for each output row */ pathnode->path.startup_cost += target->cost.startup; pathnode->path.total_cost += target->cost.startup + target->cost.per_tuple * pathnode->path.rows; return pathnode; } /* * create_minmaxagg_path * Creates a pathnode that represents computation of MIN/MAX aggregates * * 'rel' is the parent relation associated with the result * 'target' is the PathTarget to be computed * 'mmaggregates' is a list of MinMaxAggInfo structs * 'quals' is the HAVING quals if any */ MinMaxAggPath * create_minmaxagg_path(PlannerInfo *root, RelOptInfo *rel, PathTarget *target, List *mmaggregates, List *quals) { MinMaxAggPath *pathnode = makeNode(MinMaxAggPath); Cost initplan_cost; ListCell *lc; /* The topmost generated Plan node will be a Result */ pathnode->path.pathtype = T_Result; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = true; /* might change below */ pathnode->path.parallel_workers = 0; /* Result is one unordered row */ pathnode->path.rows = 1; pathnode->path.pathkeys = NIL; pathnode->mmaggregates = mmaggregates; pathnode->quals = quals; /* Calculate cost of all the initplans, and check parallel safety */ initplan_cost = 0; foreach(lc, mmaggregates) { MinMaxAggInfo *mminfo = (MinMaxAggInfo *) lfirst(lc); initplan_cost += mminfo->pathcost; if (!mminfo->path->parallel_safe) pathnode->path.parallel_safe = false; } /* add tlist eval cost for each output row, plus cpu_tuple_cost */ pathnode->path.startup_cost = initplan_cost + target->cost.startup; pathnode->path.total_cost = initplan_cost + target->cost.startup + target->cost.per_tuple + cpu_tuple_cost; /* * Add cost of qual, if any --- but we ignore its selectivity, since our * rowcount estimate should be 1 no matter what the qual is. */ if (quals) { QualCost qual_cost; cost_qual_eval(&qual_cost, quals, root); pathnode->path.startup_cost += qual_cost.startup; pathnode->path.total_cost += qual_cost.startup + qual_cost.per_tuple; } /* * If the initplans were all parallel-safe, also check safety of the * target and quals. (The Result node itself isn't parallelizable, but if * we are in a subquery then it can be useful for the outer query to know * that this one is parallel-safe.) */ if (pathnode->path.parallel_safe) pathnode->path.parallel_safe = is_parallel_safe(root, (Node *) target->exprs) && is_parallel_safe(root, (Node *) quals); return pathnode; } /* * create_windowagg_path * Creates a pathnode that represents computation of window functions * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'target' is the PathTarget to be computed * 'windowFuncs' is a list of WindowFunc structs * 'winclause' is a WindowClause that is common to all the WindowFuncs * 'qual' WindowClause.runconditions from lower-level WindowAggPaths. * Must always be NIL when topwindow == false * 'topwindow' pass as true only for the top-level WindowAgg. False for all * intermediate WindowAggs. * * The input must be sorted according to the WindowClause's PARTITION keys * plus ORDER BY keys. */ WindowAggPath * create_windowagg_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, PathTarget *target, List *windowFuncs, WindowClause *winclause, List *qual, bool topwindow) { WindowAggPath *pathnode = makeNode(WindowAggPath); /* qual can only be set for the topwindow */ Assert(qual == NIL || topwindow); pathnode->path.pathtype = T_WindowAgg; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; /* WindowAgg preserves the input sort order */ pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; pathnode->winclause = winclause; pathnode->qual = qual; pathnode->topwindow = topwindow; /* * For costing purposes, assume that there are no redundant partitioning * or ordering columns; it's not worth the trouble to deal with that * corner case here. So we just pass the unmodified list lengths to * cost_windowagg. */ cost_windowagg(&pathnode->path, root, windowFuncs, winclause, subpath->startup_cost, subpath->total_cost, subpath->rows); /* add tlist eval cost for each output row */ pathnode->path.startup_cost += target->cost.startup; pathnode->path.total_cost += target->cost.startup + target->cost.per_tuple * pathnode->path.rows; return pathnode; } /* * create_setop_path * Creates a pathnode that represents computation of INTERSECT or EXCEPT * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'cmd' is the specific semantics (INTERSECT or EXCEPT, with/without ALL) * 'strategy' is the implementation strategy (sorted or hashed) * 'distinctList' is a list of SortGroupClause's representing the grouping * 'flagColIdx' is the column number where the flag column will be, if any * 'firstFlag' is the flag value for the first input relation when hashing; * or -1 when sorting * 'numGroups' is the estimated number of distinct groups * 'outputRows' is the estimated number of output rows */ SetOpPath * create_setop_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, SetOpCmd cmd, SetOpStrategy strategy, List *distinctList, AttrNumber flagColIdx, int firstFlag, double numGroups, double outputRows) { SetOpPath *pathnode = makeNode(SetOpPath); pathnode->path.pathtype = T_SetOp; pathnode->path.parent = rel; /* SetOp doesn't project, so use source path's pathtarget */ pathnode->path.pathtarget = subpath->pathtarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; /* SetOp preserves the input sort order if in sort mode */ pathnode->path.pathkeys = (strategy == SETOP_SORTED) ? subpath->pathkeys : NIL; pathnode->subpath = subpath; pathnode->cmd = cmd; pathnode->strategy = strategy; pathnode->distinctList = distinctList; pathnode->flagColIdx = flagColIdx; pathnode->firstFlag = firstFlag; pathnode->numGroups = numGroups; /* * Charge one cpu_operator_cost per comparison per input tuple. We assume * all columns get compared at most of the tuples. */ pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost + cpu_operator_cost * subpath->rows * list_length(distinctList); pathnode->path.rows = outputRows; return pathnode; } /* * create_recursiveunion_path * Creates a pathnode that represents a recursive UNION node * * 'rel' is the parent relation associated with the result * 'leftpath' is the source of data for the non-recursive term * 'rightpath' is the source of data for the recursive term * 'target' is the PathTarget to be computed * 'distinctList' is a list of SortGroupClause's representing the grouping * 'wtParam' is the ID of Param representing work table * 'numGroups' is the estimated number of groups * * For recursive UNION ALL, distinctList is empty and numGroups is zero */ RecursiveUnionPath * create_recursiveunion_path(PlannerInfo *root, RelOptInfo *rel, Path *leftpath, Path *rightpath, PathTarget *target, List *distinctList, int wtParam, double numGroups) { RecursiveUnionPath *pathnode = makeNode(RecursiveUnionPath); pathnode->path.pathtype = T_RecursiveUnion; pathnode->path.parent = rel; pathnode->path.pathtarget = target; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && leftpath->parallel_safe && rightpath->parallel_safe; /* Foolish, but we'll do it like joins for now: */ pathnode->path.parallel_workers = leftpath->parallel_workers; /* RecursiveUnion result is always unsorted */ pathnode->path.pathkeys = NIL; pathnode->leftpath = leftpath; pathnode->rightpath = rightpath; pathnode->distinctList = distinctList; pathnode->wtParam = wtParam; pathnode->numGroups = numGroups; cost_recursive_union(&pathnode->path, leftpath, rightpath); return pathnode; } /* * create_lockrows_path * Creates a pathnode that represents acquiring row locks * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'rowMarks' is a list of PlanRowMark's * 'epqParam' is the ID of Param for EvalPlanQual re-eval */ LockRowsPath * create_lockrows_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, List *rowMarks, int epqParam) { LockRowsPath *pathnode = makeNode(LockRowsPath); pathnode->path.pathtype = T_LockRows; pathnode->path.parent = rel; /* LockRows doesn't project, so use source path's pathtarget */ pathnode->path.pathtarget = subpath->pathtarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = false; pathnode->path.parallel_workers = 0; pathnode->path.rows = subpath->rows; /* * The result cannot be assumed sorted, since locking might cause the sort * key columns to be replaced with new values. */ pathnode->path.pathkeys = NIL; pathnode->subpath = subpath; pathnode->rowMarks = rowMarks; pathnode->epqParam = epqParam; /* * We should charge something extra for the costs of row locking and * possible refetches, but it's hard to say how much. For now, use * cpu_tuple_cost per row. */ pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost + cpu_tuple_cost * subpath->rows; return pathnode; } /* * create_modifytable_path * Creates a pathnode that represents performing INSERT/UPDATE/DELETE/MERGE * mods * * 'rel' is the parent relation associated with the result * 'subpath' is a Path producing source data * 'operation' is the operation type * 'canSetTag' is true if we set the command tag/es_processed * 'nominalRelation' is the parent RT index for use of EXPLAIN * 'rootRelation' is the partitioned table root RT index, or 0 if none * 'partColsUpdated' is true if any partitioning columns are being updated, * either from the target relation or a descendent partitioned table. * 'resultRelations' is an integer list of actual RT indexes of target rel(s) * 'updateColnosLists' is a list of UPDATE target column number lists * (one sublist per rel); or NIL if not an UPDATE * 'withCheckOptionLists' is a list of WCO lists (one per rel) * 'returningLists' is a list of RETURNING tlists (one per rel) * 'rowMarks' is a list of PlanRowMarks (non-locking only) * 'onconflict' is the ON CONFLICT clause, or NULL * 'epqParam' is the ID of Param for EvalPlanQual re-eval * 'mergeActionLists' is a list of lists of MERGE actions (one per rel) */ ModifyTablePath * create_modifytable_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, CmdType operation, bool canSetTag, Index nominalRelation, Index rootRelation, bool partColsUpdated, List *resultRelations, List *updateColnosLists, List *withCheckOptionLists, List *returningLists, List *rowMarks, OnConflictExpr *onconflict, List *mergeActionLists, int epqParam) { ModifyTablePath *pathnode = makeNode(ModifyTablePath); Assert(operation == CMD_MERGE || (operation == CMD_UPDATE ? list_length(resultRelations) == list_length(updateColnosLists) : updateColnosLists == NIL)); Assert(withCheckOptionLists == NIL || list_length(resultRelations) == list_length(withCheckOptionLists)); Assert(returningLists == NIL || list_length(resultRelations) == list_length(returningLists)); pathnode->path.pathtype = T_ModifyTable; pathnode->path.parent = rel; /* pathtarget is not interesting, just make it minimally valid */ pathnode->path.pathtarget = rel->reltarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = false; pathnode->path.parallel_workers = 0; pathnode->path.pathkeys = NIL; /* * Compute cost & rowcount as subpath cost & rowcount (if RETURNING) * * Currently, we don't charge anything extra for the actual table * modification work, nor for the WITH CHECK OPTIONS or RETURNING * expressions if any. It would only be window dressing, since * ModifyTable is always a top-level node and there is no way for the * costs to change any higher-level planning choices. But we might want * to make it look better sometime. */ pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost; if (returningLists != NIL) { pathnode->path.rows = subpath->rows; /* * Set width to match the subpath output. XXX this is totally wrong: * we should return an average of the RETURNING tlist widths. But * it's what happened historically, and improving it is a task for * another day. (Again, it's mostly window dressing.) */ pathnode->path.pathtarget->width = subpath->pathtarget->width; } else { pathnode->path.rows = 0; pathnode->path.pathtarget->width = 0; } pathnode->subpath = subpath; pathnode->operation = operation; pathnode->canSetTag = canSetTag; pathnode->nominalRelation = nominalRelation; pathnode->rootRelation = rootRelation; pathnode->partColsUpdated = partColsUpdated; pathnode->resultRelations = resultRelations; pathnode->updateColnosLists = updateColnosLists; pathnode->withCheckOptionLists = withCheckOptionLists; pathnode->returningLists = returningLists; pathnode->rowMarks = rowMarks; pathnode->onconflict = onconflict; pathnode->epqParam = epqParam; pathnode->mergeActionLists = mergeActionLists; return pathnode; } /* * create_limit_path * Creates a pathnode that represents performing LIMIT/OFFSET * * In addition to providing the actual OFFSET and LIMIT expressions, * the caller must provide estimates of their values for costing purposes. * The estimates are as computed by preprocess_limit(), ie, 0 represents * the clause not being present, and -1 means it's present but we could * not estimate its value. * * 'rel' is the parent relation associated with the result * 'subpath' is the path representing the source of data * 'limitOffset' is the actual OFFSET expression, or NULL * 'limitCount' is the actual LIMIT expression, or NULL * 'offset_est' is the estimated value of the OFFSET expression * 'count_est' is the estimated value of the LIMIT expression */ LimitPath * create_limit_path(PlannerInfo *root, RelOptInfo *rel, Path *subpath, Node *limitOffset, Node *limitCount, LimitOption limitOption, int64 offset_est, int64 count_est) { LimitPath *pathnode = makeNode(LimitPath); pathnode->path.pathtype = T_Limit; pathnode->path.parent = rel; /* Limit doesn't project, so use source path's pathtarget */ pathnode->path.pathtarget = subpath->pathtarget; /* For now, assume we are above any joins, so no parameterization */ pathnode->path.param_info = NULL; pathnode->path.parallel_aware = false; pathnode->path.parallel_safe = rel->consider_parallel && subpath->parallel_safe; pathnode->path.parallel_workers = subpath->parallel_workers; pathnode->path.rows = subpath->rows; pathnode->path.startup_cost = subpath->startup_cost; pathnode->path.total_cost = subpath->total_cost; pathnode->path.pathkeys = subpath->pathkeys; pathnode->subpath = subpath; pathnode->limitOffset = limitOffset; pathnode->limitCount = limitCount; pathnode->limitOption = limitOption; /* * Adjust the output rows count and costs according to the offset/limit. */ adjust_limit_rows_costs(&pathnode->path.rows, &pathnode->path.startup_cost, &pathnode->path.total_cost, offset_est, count_est); return pathnode; } /* * adjust_limit_rows_costs * Adjust the size and cost estimates for a LimitPath node according to the * offset/limit. * * This is only a cosmetic issue if we are at top level, but if we are * building a subquery then it's important to report correct info to the outer * planner. * * When the offset or count couldn't be estimated, use 10% of the estimated * number of rows emitted from the subpath. * * XXX we don't bother to add eval costs of the offset/limit expressions * themselves to the path costs. In theory we should, but in most cases those * expressions are trivial and it's just not worth the trouble. */ void adjust_limit_rows_costs(double *rows, /* in/out parameter */ Cost *startup_cost, /* in/out parameter */ Cost *total_cost, /* in/out parameter */ int64 offset_est, int64 count_est) { double input_rows = *rows; Cost input_startup_cost = *startup_cost; Cost input_total_cost = *total_cost; if (offset_est != 0) { double offset_rows; if (offset_est > 0) offset_rows = (double) offset_est; else offset_rows = clamp_row_est(input_rows * 0.10); if (offset_rows > *rows) offset_rows = *rows; if (input_rows > 0) *startup_cost += (input_total_cost - input_startup_cost) * offset_rows / input_rows; *rows -= offset_rows; if (*rows < 1) *rows = 1; } if (count_est != 0) { double count_rows; if (count_est > 0) count_rows = (double) count_est; else count_rows = clamp_row_est(input_rows * 0.10); if (count_rows > *rows) count_rows = *rows; if (input_rows > 0) *total_cost = *startup_cost + (input_total_cost - input_startup_cost) * count_rows / input_rows; *rows = count_rows; if (*rows < 1) *rows = 1; } } /* * reparameterize_path * Attempt to modify a Path to have greater parameterization * * We use this to attempt to bring all child paths of an appendrel to the * same parameterization level, ensuring that they all enforce the same set * of join quals (and thus that that parameterization can be attributed to * an append path built from such paths). Currently, only a few path types * are supported here, though more could be added at need. We return NULL * if we can't reparameterize the given path. * * Note: we intentionally do not pass created paths to add_path(); it would * possibly try to delete them on the grounds of being cost-inferior to the * paths they were made from, and we don't want that. Paths made here are * not necessarily of general-purpose usefulness, but they can be useful * as members of an append path. */ Path * reparameterize_path(PlannerInfo *root, Path *path, Relids required_outer, double loop_count) { RelOptInfo *rel = path->parent; /* Can only increase, not decrease, path's parameterization */ if (!bms_is_subset(PATH_REQ_OUTER(path), required_outer)) return NULL; switch (path->pathtype) { case T_SeqScan: return create_seqscan_path(root, rel, required_outer, 0); case T_SampleScan: return (Path *) create_samplescan_path(root, rel, required_outer); case T_IndexScan: case T_IndexOnlyScan: { IndexPath *ipath = (IndexPath *) path; IndexPath *newpath = makeNode(IndexPath); /* * We can't use create_index_path directly, and would not want * to because it would re-compute the indexqual conditions * which is wasted effort. Instead we hack things a bit: * flat-copy the path node, revise its param_info, and redo * the cost estimate. */ memcpy(newpath, ipath, sizeof(IndexPath)); newpath->path.param_info = get_baserel_parampathinfo(root, rel, required_outer); cost_index(newpath, root, loop_count, false); return (Path *) newpath; } case T_BitmapHeapScan: { BitmapHeapPath *bpath = (BitmapHeapPath *) path; return (Path *) create_bitmap_heap_path(root, rel, bpath->bitmapqual, required_outer, loop_count, 0); } case T_SubqueryScan: { SubqueryScanPath *spath = (SubqueryScanPath *) path; Path *subpath = spath->subpath; bool trivial_pathtarget; /* * If existing node has zero extra cost, we must have decided * its target is trivial. (The converse is not true, because * it might have a trivial target but quals to enforce; but in * that case the new node will too, so it doesn't matter * whether we get the right answer here.) */ trivial_pathtarget = (subpath->total_cost == spath->path.total_cost); return (Path *) create_subqueryscan_path(root, rel, subpath, trivial_pathtarget, spath->path.pathkeys, required_outer); } case T_Result: /* Supported only for RTE_RESULT scan paths */ if (IsA(path, Path)) return create_resultscan_path(root, rel, required_outer); break; case T_Append: { AppendPath *apath = (AppendPath *) path; List *childpaths = NIL; List *partialpaths = NIL; int i; ListCell *lc; /* Reparameterize the children */ i = 0; foreach(lc, apath->subpaths) { Path *spath = (Path *) lfirst(lc); spath = reparameterize_path(root, spath, required_outer, loop_count); if (spath == NULL) return NULL; /* We have to re-split the regular and partial paths */ if (i < apath->first_partial_path) childpaths = lappend(childpaths, spath); else partialpaths = lappend(partialpaths, spath); i++; } return (Path *) create_append_path(root, rel, childpaths, partialpaths, apath->path.pathkeys, required_outer, apath->path.parallel_workers, apath->path.parallel_aware, -1); } case T_Material: { MaterialPath *mpath = (MaterialPath *) path; Path *spath = mpath->subpath; spath = reparameterize_path(root, spath, required_outer, loop_count); if (spath == NULL) return NULL; return (Path *) create_material_path(rel, spath); } case T_Memoize: { MemoizePath *mpath = (MemoizePath *) path; Path *spath = mpath->subpath; spath = reparameterize_path(root, spath, required_outer, loop_count); if (spath == NULL) return NULL; return (Path *) create_memoize_path(root, rel, spath, mpath->param_exprs, mpath->hash_operators, mpath->singlerow, mpath->binary_mode, mpath->calls); } default: break; } return NULL; } /* * reparameterize_path_by_child * Given a path parameterized by the parent of the given child relation, * translate the path to be parameterized by the given child relation. * * The function creates a new path of the same type as the given path, but * parameterized by the given child relation. Most fields from the original * path can simply be flat-copied, but any expressions must be adjusted to * refer to the correct varnos, and any paths must be recursively * reparameterized. Other fields that refer to specific relids also need * adjustment. * * The cost, number of rows, width and parallel path properties depend upon * path->parent, which does not change during the translation. Hence those * members are copied as they are. * * Currently, only a few path types are supported here, though more could be * added at need. We return NULL if we can't reparameterize the given path. */ Path * reparameterize_path_by_child(PlannerInfo *root, Path *path, RelOptInfo *child_rel) { #define FLAT_COPY_PATH(newnode, node, nodetype) \ ( (newnode) = makeNode(nodetype), \ memcpy((newnode), (node), sizeof(nodetype)) ) #define ADJUST_CHILD_ATTRS(node) \ ((node) = \ (List *) adjust_appendrel_attrs_multilevel(root, (Node *) (node), \ child_rel, \ child_rel->top_parent)) #define REPARAMETERIZE_CHILD_PATH(path) \ do { \ (path) = reparameterize_path_by_child(root, (path), child_rel); \ if ((path) == NULL) \ return NULL; \ } while(0) #define REPARAMETERIZE_CHILD_PATH_LIST(pathlist) \ do { \ if ((pathlist) != NIL) \ { \ (pathlist) = reparameterize_pathlist_by_child(root, (pathlist), \ child_rel); \ if ((pathlist) == NIL) \ return NULL; \ } \ } while(0) Path *new_path; ParamPathInfo *new_ppi; ParamPathInfo *old_ppi; Relids required_outer; /* * If the path is not parameterized by parent of the given relation, it * doesn't need reparameterization. */ if (!path->param_info || !bms_overlap(PATH_REQ_OUTER(path), child_rel->top_parent_relids)) return path; /* * If possible, reparameterize the given path, making a copy. * * This function is currently only applied to the inner side of a nestloop * join that is being partitioned by the partitionwise-join code. Hence, * we need only support path types that plausibly arise in that context. * (In particular, supporting sorted path types would be a waste of code * and cycles: even if we translated them here, they'd just lose in * subsequent cost comparisons.) If we do see an unsupported path type, * that just means we won't be able to generate a partitionwise-join plan * using that path type. */ switch (nodeTag(path)) { case T_Path: FLAT_COPY_PATH(new_path, path, Path); break; case T_IndexPath: { IndexPath *ipath; FLAT_COPY_PATH(ipath, path, IndexPath); ADJUST_CHILD_ATTRS(ipath->indexclauses); new_path = (Path *) ipath; } break; case T_BitmapHeapPath: { BitmapHeapPath *bhpath; FLAT_COPY_PATH(bhpath, path, BitmapHeapPath); REPARAMETERIZE_CHILD_PATH(bhpath->bitmapqual); new_path = (Path *) bhpath; } break; case T_BitmapAndPath: { BitmapAndPath *bapath; FLAT_COPY_PATH(bapath, path, BitmapAndPath); REPARAMETERIZE_CHILD_PATH_LIST(bapath->bitmapquals); new_path = (Path *) bapath; } break; case T_BitmapOrPath: { BitmapOrPath *bopath; FLAT_COPY_PATH(bopath, path, BitmapOrPath); REPARAMETERIZE_CHILD_PATH_LIST(bopath->bitmapquals); new_path = (Path *) bopath; } break; case T_ForeignPath: { ForeignPath *fpath; ReparameterizeForeignPathByChild_function rfpc_func; FLAT_COPY_PATH(fpath, path, ForeignPath); if (fpath->fdw_outerpath) REPARAMETERIZE_CHILD_PATH(fpath->fdw_outerpath); if (fpath->fdw_restrictinfo) ADJUST_CHILD_ATTRS(fpath->fdw_restrictinfo); /* Hand over to FDW if needed. */ rfpc_func = path->parent->fdwroutine->ReparameterizeForeignPathByChild; if (rfpc_func) fpath->fdw_private = rfpc_func(root, fpath->fdw_private, child_rel); new_path = (Path *) fpath; } break; case T_CustomPath: { CustomPath *cpath; FLAT_COPY_PATH(cpath, path, CustomPath); REPARAMETERIZE_CHILD_PATH_LIST(cpath->custom_paths); if (cpath->custom_restrictinfo) ADJUST_CHILD_ATTRS(cpath->custom_restrictinfo); if (cpath->methods && cpath->methods->ReparameterizeCustomPathByChild) cpath->custom_private = cpath->methods->ReparameterizeCustomPathByChild(root, cpath->custom_private, child_rel); new_path = (Path *) cpath; } break; case T_NestPath: { JoinPath *jpath; NestPath *npath; FLAT_COPY_PATH(npath, path, NestPath); jpath = (JoinPath *) npath; REPARAMETERIZE_CHILD_PATH(jpath->outerjoinpath); REPARAMETERIZE_CHILD_PATH(jpath->innerjoinpath); ADJUST_CHILD_ATTRS(jpath->joinrestrictinfo); new_path = (Path *) npath; } break; case T_MergePath: { JoinPath *jpath; MergePath *mpath; FLAT_COPY_PATH(mpath, path, MergePath); jpath = (JoinPath *) mpath; REPARAMETERIZE_CHILD_PATH(jpath->outerjoinpath); REPARAMETERIZE_CHILD_PATH(jpath->innerjoinpath); ADJUST_CHILD_ATTRS(jpath->joinrestrictinfo); ADJUST_CHILD_ATTRS(mpath->path_mergeclauses); new_path = (Path *) mpath; } break; case T_HashPath: { JoinPath *jpath; HashPath *hpath; FLAT_COPY_PATH(hpath, path, HashPath); jpath = (JoinPath *) hpath; REPARAMETERIZE_CHILD_PATH(jpath->outerjoinpath); REPARAMETERIZE_CHILD_PATH(jpath->innerjoinpath); ADJUST_CHILD_ATTRS(jpath->joinrestrictinfo); ADJUST_CHILD_ATTRS(hpath->path_hashclauses); new_path = (Path *) hpath; } break; case T_AppendPath: { AppendPath *apath; FLAT_COPY_PATH(apath, path, AppendPath); REPARAMETERIZE_CHILD_PATH_LIST(apath->subpaths); new_path = (Path *) apath; } break; case T_MaterialPath: { MaterialPath *mpath; FLAT_COPY_PATH(mpath, path, MaterialPath); REPARAMETERIZE_CHILD_PATH(mpath->subpath); new_path = (Path *) mpath; } break; case T_MemoizePath: { MemoizePath *mpath; FLAT_COPY_PATH(mpath, path, MemoizePath); REPARAMETERIZE_CHILD_PATH(mpath->subpath); ADJUST_CHILD_ATTRS(mpath->param_exprs); new_path = (Path *) mpath; } break; case T_GatherPath: { GatherPath *gpath; FLAT_COPY_PATH(gpath, path, GatherPath); REPARAMETERIZE_CHILD_PATH(gpath->subpath); new_path = (Path *) gpath; } break; default: /* We don't know how to reparameterize this path. */ return NULL; } /* * Adjust the parameterization information, which refers to the topmost * parent. The topmost parent can be multiple levels away from the given * child, hence use multi-level expression adjustment routines. */ old_ppi = new_path->param_info; required_outer = adjust_child_relids_multilevel(root, old_ppi->ppi_req_outer, child_rel, child_rel->top_parent); /* If we already have a PPI for this parameterization, just return it */ new_ppi = find_param_path_info(new_path->parent, required_outer); /* * If not, build a new one and link it to the list of PPIs. For the same * reason as explained in mark_dummy_rel(), allocate new PPI in the same * context the given RelOptInfo is in. */ if (new_ppi == NULL) { MemoryContext oldcontext; RelOptInfo *rel = path->parent; oldcontext = MemoryContextSwitchTo(GetMemoryChunkContext(rel)); new_ppi = makeNode(ParamPathInfo); new_ppi->ppi_req_outer = bms_copy(required_outer); new_ppi->ppi_rows = old_ppi->ppi_rows; new_ppi->ppi_clauses = old_ppi->ppi_clauses; ADJUST_CHILD_ATTRS(new_ppi->ppi_clauses); new_ppi->ppi_serials = bms_copy(old_ppi->ppi_serials); rel->ppilist = lappend(rel->ppilist, new_ppi); MemoryContextSwitchTo(oldcontext); } bms_free(required_outer); new_path->param_info = new_ppi; /* * Adjust the path target if the parent of the outer relation is * referenced in the targetlist. This can happen when only the parent of * outer relation is laterally referenced in this relation. */ if (bms_overlap(path->parent->lateral_relids, child_rel->top_parent_relids)) { new_path->pathtarget = copy_pathtarget(new_path->pathtarget); ADJUST_CHILD_ATTRS(new_path->pathtarget->exprs); } return new_path; } /* * reparameterize_pathlist_by_child * Helper function to reparameterize a list of paths by given child rel. */ static List * reparameterize_pathlist_by_child(PlannerInfo *root, List *pathlist, RelOptInfo *child_rel) { ListCell *lc; List *result = NIL; foreach(lc, pathlist) { Path *path = reparameterize_path_by_child(root, lfirst(lc), child_rel); if (path == NULL) { list_free(result); return NIL; } result = lappend(result, path); } return result; }