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这篇文章主要讲解了“PostgreSQL中create_sort_plan函数实现逻辑是什么”,文中的讲解内容简单清晰,易于学习与理解,下面请大家跟着小编的思路慢慢深入,一起来研究和学习“PostgreSQL中create_sort_plan函数实现逻辑是什么”吧!
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Plan
所有计划节点通过将Plan结构作为第一个字段从Plan结构“派生”。这确保了在将节点转换为计划节点时,一切都能正常工作。(在执行器中以通用方式传递时,节点指针经常被转换为Plan *)
/* ---------------- * Plan node * * All plan nodes "derive" from the Plan structure by having the * Plan structure as the first field. This ensures that everything works * when nodes are cast to Plan's. (node pointers are frequently cast to Plan* * when passed around generically in the executor) * 所有计划节点通过将Plan结构作为第一个字段从Plan结构“派生”。 * 这确保了在将节点转换为计划节点时,一切都能正常工作。 * (在执行器中以通用方式传递时,节点指针经常被转换为Plan *) * * We never actually instantiate any Plan nodes; this is just the common * abstract superclass for all Plan-type nodes. * 从未实例化任何Plan节点;这只是所有Plan-type节点的通用抽象超类。 * ---------------- */ typedef struct Plan { NodeTag type;//节点类型 /* * 成本估算信息;estimated execution costs for plan (see costsize.c for more info) */ Cost startup_cost; /* 启动成本;cost expended before fetching any tuples */ Cost total_cost; /* 总成本;total cost (assuming all tuples fetched) */ /* * 优化器估算信息;planner's estimate of result size of this plan step */ double plan_rows; /* 行数;number of rows plan is expected to emit */ int plan_width; /* 平均行大小(Byte为单位);average row width in bytes */ /* * 并行执行相关的信息;information needed for parallel query */ bool parallel_aware; /* 是否参与并行执行逻辑?engage parallel-aware logic? */ bool parallel_safe; /* 是否并行安全;OK to use as part of parallel plan? */ /* * Plan类型节点通用的信息.Common structural data for all Plan types. */ int plan_node_id; /* unique across entire final plan tree */ List *targetlist; /* target list to be computed at this node */ List *qual; /* implicitly-ANDed qual conditions */ struct Plan *lefttree; /* input plan tree(s) */ struct Plan *righttree; List *initPlan; /* Init Plan nodes (un-correlated expr * subselects) */ /* * Information for management of parameter-change-driven rescanning * parameter-change-driven重扫描的管理信息. * * extParam includes the paramIDs of all external PARAM_EXEC params * affecting this plan node or its children. setParam params from the * node's initPlans are not included, but their extParams are. * * allParam includes all the extParam paramIDs, plus the IDs of local * params that affect the node (i.e., the setParams of its initplans). * These are _all_ the PARAM_EXEC params that affect this node. */ Bitmapset *extParam; Bitmapset *allParam; } Plan;
create_plan->create_plan_recurse->create_projection_plan函数创建计划树,执行投影操作并通过递归的方式为子访问路径生成执行计划。create_sort_plan函数创建Sort计划节点。
//---------------------------------------------------------------- create_projection_plan /* * create_projection_plan * * Create a plan tree to do a projection step and (recursively) plans * for its subpaths. We may need a Result node for the projection, * but sometimes we can just let the subplan do the work. * 创建计划树,执行投影操作并通过递归的方式为子访问路径生成执行计划. * 一般来说需要一个Result节点用于投影操作,但有时候可以让子计划执行此项任务. */ static Plan * create_projection_plan(PlannerInfo *root, ProjectionPath *best_path, int flags) { Plan *plan; Plan *subplan; List *tlist; bool needs_result_node = false; /* * Convert our subpath to a Plan and determine whether we need a Result * node. * 转换subpath为Plan,并确定是否需要Result节点. * * In most cases where we don't need to project, creation_projection_path * will have set dummypp, but not always. First, some createplan.c * routines change the tlists of their nodes. (An example is that * create_merge_append_plan might add resjunk sort columns to a * MergeAppend.) Second, create_projection_path has no way of knowing * what path node will be placed on top of the projection path and * therefore can't predict whether it will require an exact tlist. For * both of these reasons, we have to recheck here. * 在大多数情况下,我们不需要投影运算,creation_projection_path将设置dummypp标志,但并不总是如此。 * 首先,一些createplan.c中的函数更改其节点的tlist。 * (例如,create_merge_append_plan可能会向MergeAppend添加resjunk sort列)。 * 其次,create_projection_path无法知道将在投影路径顶部放置哪些路径节点,因此无法预测它是否需要一个确切的tlist。 * 由于这两个原因,我们不得不在这里重新检查。 */ if (use_physical_tlist(root, &best_path->path, flags)) { /* * Our caller doesn't really care what tlist we return, so we don't * actually need to project. However, we may still need to ensure * proper sortgroupref labels, if the caller cares about those. * 如果我们的调用者并不关心返回的结果tlist,所以实际上不需要投影运算。 * 然而,如果调用者关心sortgroupref标签,可能仍然需要确保正确的sortgroupref数据。 */ subplan = create_plan_recurse(root, best_path->subpath, 0); tlist = subplan->targetlist; if (flags & CP_LABEL_TLIST) apply_pathtarget_labeling_to_tlist(tlist, best_path->path.pathtarget); } else if (is_projection_capable_path(best_path->subpath)) { /* * Our caller requires that we return the exact tlist, but no separate * result node is needed because the subpath is projection-capable. * Tell create_plan_recurse that we're going to ignore the tlist it * produces. * 调用者要求返回精确的tlist,但是不需要单独的Result节点,因为子路径支持投影。 * 调用create_plan_recurse时忽略它生成的tlist。 */ subplan = create_plan_recurse(root, best_path->subpath, CP_IGNORE_TLIST); tlist = build_path_tlist(root, &best_path->path); } else { /* * It looks like we need a result node, unless by good fortune the * requested tlist is exactly the one the child wants to produce. * 看起来需要一个Result节点,除非幸运的是,请求的tlist正是子节点想要生成的。 */ subplan = create_plan_recurse(root, best_path->subpath, 0); tlist = build_path_tlist(root, &best_path->path); needs_result_node = !tlist_same_exprs(tlist, subplan->targetlist); } /* * If we make a different decision about whether to include a Result node * than create_projection_path did, we'll have made slightly wrong cost * estimates; but label the plan with the cost estimates we actually used, * not "corrected" ones. (XXX this could be cleaned up if we moved more * of the sortcolumn setup logic into Path creation, but that would add * expense to creating Paths we might end up not using.) * 如果我们对是否包含一个Result节点做出与create_projection_path不同的决定, * 我们就会做出略微错误的成本估算; * 但是在这个计划上标上我们实际使用的成本估算,而不是“修正的”成本估算。 * (如果我们将更多的sortcolumn设置逻辑移到路径创建中,这个问题就可以解决了, * 但是这会增加创建路径的成本,而最终可能不会使用这些路径。) */ if (!needs_result_node) { /* Don't need a separate Result, just assign tlist to subplan */ //不需要单独的Result节点,把tlist赋值给subplan plan = subplan; plan->targetlist = tlist; /* Label plan with the estimated costs we actually used */ //标记估算成本 plan->startup_cost = best_path->path.startup_cost; plan->total_cost = best_path->path.total_cost; plan->plan_rows = best_path->path.rows; plan->plan_width = best_path->path.pathtarget->width; plan->parallel_safe = best_path->path.parallel_safe; /* ... but don't change subplan's parallel_aware flag */ } else { /* We need a Result node */ //需要Result节点 plan = (Plan *) make_result(tlist, NULL, subplan); copy_generic_path_info(plan, (Path *) best_path); } return plan; } //---------------------------------------------------------------- create_sort_plan /* * create_sort_plan * * Create a Sort plan for 'best_path' and (recursively) plans * for its subpaths. * 创建Sort计划节点 */ static Sort * create_sort_plan(PlannerInfo *root, SortPath *best_path, int flags) { Sort *plan; Plan *subplan; /* * We don't want any excess columns in the sorted tuples, so request a * smaller tlist. Otherwise, since Sort doesn't project, tlist * requirements pass through. * 我们不希望在排序元组中有任何多余的列,所以希望得到一个更小的tlist。 * 否则,由于Sort不执行投影运算,tlist就会通过完整的保留传递。 */ subplan = create_plan_recurse(root, best_path->subpath, flags | CP_SMALL_TLIST); /* * make_sort_from_pathkeys() indirectly calls find_ec_member_for_tle(), * which will ignore any child EC members that don't belong to the given * relids. Thus, if this sort path is based on a child relation, we must * pass its relids. * make_sort_from_pathkeys()间接调用find_ec_member_for_tle(),它将忽略不属于给定relid的任何子EC成员。 * 因此,如果这个排序路径是基于子关系的,我们必须传递它的relids。 */ plan = make_sort_from_pathkeys(subplan, best_path->path.pathkeys, IS_OTHER_REL(best_path->subpath->parent) ? best_path->path.parent->relids : NULL); copy_generic_path_info(&plan->plan, (Path *) best_path); return plan; } //------------------------------------------------ build_path_tlist /* * Build a target list (ie, a list of TargetEntry) for the Path's output. * 构建用于输出的target链表(比如TargetEntry节点链表) * * This is almost just make_tlist_from_pathtarget(), but we also have to * deal with replacing nestloop params. * 该函数几乎就是make_tlist_from_pathtarget()的实现逻辑,但还必须处理替换nestloop参数。 */ static List * build_path_tlist(PlannerInfo *root, Path *path) { List *tlist = NIL; Index *sortgrouprefs = path->pathtarget->sortgrouprefs; int resno = 1; ListCell *v; foreach(v, path->pathtarget->exprs) { Node *node = (Node *) lfirst(v); TargetEntry *tle; /* * If it's a parameterized path, there might be lateral references in * the tlist, which need to be replaced with Params. There's no need * to remake the TargetEntry nodes, so apply this to each list item * separately. * 如果是参数化路径,那么tlist中可能有横向引用,需要用Params替换。 * 不需要重新构建TargetEntry节点,因此可以将其单独应用于每个链表项。 */ if (path->param_info) node = replace_nestloop_params(root, node); tle = makeTargetEntry((Expr *) node, resno, NULL, false); if (sortgrouprefs) tle->ressortgroupref = sortgrouprefs[resno - 1]; tlist = lappend(tlist, tle); resno++; } return tlist; }
测试脚本如下
testdb=# explain select dw.*,grjf.grbh,grjf.xm,grjf.ny,grjf.je testdb-# from t_dwxx dw,lateral (select gr.grbh,gr.xm,jf.ny,jf.je testdb(# from t_grxx gr inner join t_jfxx jf testdb(# on gr.dwbh = dw.dwbh testdb(# and gr.grbh = jf.grbh) grjf testdb-# order by dw.dwbh; QUERY PLAN ------------------------------------------------------------------------------------------ Sort (cost=20070.93..20320.93 rows=100000 width=47) Sort Key: dw.dwbh -> Hash Join (cost=3754.00..8689.61 rows=100000 width=47) Hash Cond: ((gr.dwbh)::text = (dw.dwbh)::text) -> Hash Join (cost=3465.00..8138.00 rows=100000 width=31) Hash Cond: ((jf.grbh)::text = (gr.grbh)::text) -> Seq Scan on t_jfxx jf (cost=0.00..1637.00 rows=100000 width=20) -> Hash (cost=1726.00..1726.00 rows=100000 width=16) -> Seq Scan on t_grxx gr (cost=0.00..1726.00 rows=100000 width=16) -> Hash (cost=164.00..164.00 rows=10000 width=20) -> Seq Scan on t_dwxx dw (cost=0.00..164.00 rows=10000 width=20) (11 rows)
启动gdb,设置断点,进入create_projection_plan函数
(gdb) b create_projection_plan Breakpoint 2 at 0x7b95a8: file createplan.c, line 1627. (gdb) c Continuing. Breakpoint 2, create_projection_plan (root=0x26c1258, best_path=0x2722d00, flags=1) at createplan.c:1627 1627 bool needs_result_node = false;
转换subpath为Plan,并确定是否需要Result节点,并且判断是否需要生成Result节点
... (gdb) n 1642 if (use_physical_tlist(root, &best_path->path, flags)) (gdb) n 1655 else if (is_projection_capable_path(best_path->subpath)) (gdb) 1673 subplan = create_plan_recurse(root, best_path->subpath, 0);
查看best_path&best_path->subpath变量
(gdb) p *best_path $3 = {path = {type = T_ProjectionPath, pathtype = T_Result, parent = 0x2722998, pathtarget = 0x27226f8, param_info = 0x0, parallel_aware = false, parallel_safe = true, parallel_workers = 0, rows = 100000, startup_cost = 20070.931487218411, total_cost = 20320.931487218411, pathkeys = 0x26cfe98}, subpath = 0x2722c68, dummypp = true} (gdb) p *(SortPath *)best_path->subpath $16 = {path = {type = T_SortPath, pathtype = T_Sort, parent = 0x2722998, pathtarget = 0x27212d8, param_info = 0x0, parallel_aware = false, parallel_safe = true, parallel_workers = 0, rows = 100000, startup_cost = 20070.931487218411, total_cost = 20320.931487218411, pathkeys = 0x26cfe98}, subpath = 0x2721e60}
创建subpath(SortPath)的执行计划
(gdb) step create_plan_recurse (root=0x26c1258, best_path=0x2722c68, flags=0) at createplan.c:364 364 check_stack_depth(); (gdb) n 366 switch (best_path->pathtype) (gdb) 447 plan = (Plan *) create_sort_plan(root,
进入create_sort_plan
(gdb) step create_sort_plan (root=0x26c1258, best_path=0x2722c68, flags=0) at createplan.c:1759 1759 subplan = create_plan_recurse(root, best_path->subpath,
SortPath的subpath是HashPath
(gdb) p best_path->subpath->type $17 = T_HashPath (gdb) p *(HashPath *)best_path->subpath $18 = {jpath = {path = {type = T_HashPath, pathtype = T_HashJoin, parent = 0x27210c0, pathtarget = 0x27212d8, param_info = 0x0, parallel_aware = false, parallel_safe = true, parallel_workers = 0, rows = 100000, startup_cost = 3754, total_cost = 8689.6112499999999, pathkeys = 0x0}, jointype = JOIN_INNER, inner_unique = true, outerjoinpath = 0x2720f68, innerjoinpath = 0x26d0598, joinrestrictinfo = 0x2722068}, path_hashclauses = 0x27223c0, num_batches = 1, inner_rows_total = 10000}
完成SortPath执行计划的构建
(gdb) 1774 return plan; (gdb) 1775 } (gdb) p *plan $20 = {plan = {type = T_Sort, startup_cost = 20070.931487218411, total_cost = 20320.931487218411, plan_rows = 100000, plan_width = 47, parallel_aware = false, parallel_safe = true, plan_node_id = 0, targetlist = 0x2723208, qual = 0x0, lefttree = 0x27243d0, righttree = 0x0, initPlan = 0x0, extParam = 0x0, allParam = 0x0}, numCols = 1, sortColIdx = 0x27222a0, sortOperators = 0x2724468, collations = 0x2724488, nullsFirst = 0x27244a8}
回到上一层
(gdb) n create_plan_recurse (root=0x26c1258, best_path=0x2722c68, flags=0) at createplan.c:450 450 break;
回到create_projection_plan函数
(gdb) n 504 return plan; (gdb) 505 } (gdb) create_projection_plan (root=0x26c1258, best_path=0x2722d00, flags=1) at createplan.c:1674 1674 tlist = build_path_tlist(root, &best_path->path);
执行完毕,返回create_plan,结果,最外层的Plan为Sort
(gdb) 1708 return plan; (gdb) 1709 } (gdb) p *plan $22 = {type = T_Sort, startup_cost = 20070.931487218411, total_cost = 20320.931487218411, plan_rows = 100000, plan_width = 47, parallel_aware = false, parallel_safe = true, plan_node_id = 0, targetlist = 0x2724548, qual = 0x0, lefttree = 0x27243d0, righttree = 0x0, initPlan = 0x0, extParam = 0x0, allParam = 0x0} (gdb) n create_plan_recurse (root=0x26c1258, best_path=0x2722d00, flags=1) at createplan.c:504 504 return plan; (gdb) p *plan $23 = {type = T_Sort, startup_cost = 20070.931487218411, total_cost = 20320.931487218411, plan_rows = 100000, plan_width = 47, parallel_aware = false, parallel_safe = true, plan_node_id = 0, targetlist = 0x2724548, qual = 0x0, lefttree = 0x27243d0, righttree = 0x0, initPlan = 0x0, extParam = 0x0, allParam = 0x0} (gdb) n 505 } (gdb) create_plan (root=0x26c1258, best_path=0x2722d00) at createplan.c:329 329 if (!IsA(plan, ModifyTable))
感谢各位的阅读,以上就是“PostgreSQL中create_sort_plan函数实现逻辑是什么”的内容了,经过本文的学习后,相信大家对PostgreSQL中create_sort_plan函数实现逻辑是什么这一问题有了更深刻的体会,具体使用情况还需要大家实践验证。这里是创新互联,小编将为大家推送更多相关知识点的文章,欢迎关注!