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本篇内容主要讲解“PostgreSQL中create_index_path函数有什么作用”,感兴趣的朋友不妨来看看。本文介绍的方法操作简单快捷,实用性强。下面就让小编来带大家学习“PostgreSQL中create_index_path函数有什么作用”吧!
函数build_index_paths中的子函数create_index_path实现了索引扫描成本的估算主逻辑。
IndexOptInfo
回顾IndexOptInfo索引信息结构体
typedef struct IndexOptInfo { NodeTag type; Oid indexoid; /* Index的OID,OID of the index relation */ Oid reltablespace; /* Index的表空间,tablespace of index (not table) */ RelOptInfo *rel; /* 指向Relation的指针,back-link to index's table */ /* index-size statistics (from pg_class and elsewhere) */ BlockNumber pages; /* Index的pages,number of disk pages in index */ double tuples; /* Index的元组数,number of index tuples in index */ int tree_height; /* 索引高度,index tree height, or -1 if unknown */ /* index descriptor information */ int ncolumns; /* 索引的列数,number of columns in index */ int nkeycolumns; /* 索引的关键列数,number of key columns in index */ int *indexkeys; /* column numbers of index's attributes both * key and included columns, or 0 */ Oid *indexcollations; /* OIDs of collations of index columns */ Oid *opfamily; /* OIDs of operator families for columns */ Oid *opcintype; /* OIDs of opclass declared input data types */ Oid *sortopfamily; /* OIDs of btree opfamilies, if orderable */ bool *reverse_sort; /* 倒序?is sort order descending? */ bool *nulls_first; /* NULLs值优先?do NULLs come first in the sort order? */ bool *canreturn; /* 索引列可通过Index-Only Scan返回?which index cols can be returned in an * index-only scan? */ Oid relam; /* 访问方法OID,OID of the access method (in pg_am) */ List *indexprs; /* 非简单索引列表达式链表,如函数索引,expressions for non-simple index columns */ List *indpred; /* 部分索引的谓词链表,predicate if a partial index, else NIL */ List *indextlist; /* 索引列(TargetEntry结构体链表),targetlist representing index columns */ List *indrestrictinfo; /* 父关系的baserestrictinfo列表, * 不包含索引谓词隐含的所有条件 * (除非是目标rel,请参阅check_index_predicates()中的注释), * parent relation's baserestrictinfo * list, less any conditions implied by * the index's predicate (unless it's a * target rel, see comments in * check_index_predicates()) */ bool predOK; /* True,如索引谓词满足查询要求,true if index predicate matches query */ bool unique; /* 是否唯一索引,true if a unique index */ bool immediate; /* 唯一性校验是否立即生效,is uniqueness enforced immediately? */ bool hypothetical; /* 是否虚拟索引,true if index doesn't really exist */ /* Remaining fields are copied from the index AM's API struct: */ //从Index Relation拷贝过来的AM(访问方法)API信息 bool amcanorderbyop; /* does AM support order by operator result? */ bool amoptionalkey; /* can query omit key for the first column? */ bool amsearcharray; /* can AM handle ScalarArrayOpExpr quals? */ bool amsearchnulls; /* can AM search for NULL/NOT NULL entries? */ bool amhasgettuple; /* does AM have amgettuple interface? */ bool amhasgetbitmap; /* does AM have amgetbitmap interface? */ bool amcanparallel; /* does AM support parallel scan? */ /* Rather than include amapi.h here, we declare amcostestimate like this */ void (*amcostestimate) (); /* 访问方法的估算函数,AM's cost estimator */ } IndexOptInfo;
Cost相关
注意:实际使用的参数值通过系统配置文件定义,而不是这里的常量定义!
typedef double Cost; /* execution cost (in page-access units) */ /* defaults for costsize.c's Cost parameters */ /* NB: cost-estimation code should use the variables, not these constants! */ /* 注意:实际值通过系统配置文件定义,而不是这里的常量定义! */ /* If you change these, update backend/utils/misc/postgresql.sample.conf */ #define DEFAULT_SEQ_PAGE_COST 1.0 //顺序扫描page的成本 #define DEFAULT_RANDOM_PAGE_COST 4.0 //随机扫描page的成本 #define DEFAULT_CPU_TUPLE_COST 0.01 //处理一个元组的CPU成本 #define DEFAULT_CPU_INDEX_TUPLE_COST 0.005 //处理一个索引元组的CPU成本 #define DEFAULT_CPU_OPERATOR_COST 0.0025 //执行一次操作或函数的CPU成本 #define DEFAULT_PARALLEL_TUPLE_COST 0.1 //并行执行,从一个worker传输一个元组到另一个worker的成本 #define DEFAULT_PARALLEL_SETUP_COST 1000.0 //构建并行执行环境的成本 #define DEFAULT_EFFECTIVE_CACHE_SIZE 524288 /*先前已有介绍, measured in pages */ double seq_page_cost = DEFAULT_SEQ_PAGE_COST; double random_page_cost = DEFAULT_RANDOM_PAGE_COST; double cpu_tuple_cost = DEFAULT_CPU_TUPLE_COST; double cpu_index_tuple_cost = DEFAULT_CPU_INDEX_TUPLE_COST; double cpu_operator_cost = DEFAULT_CPU_OPERATOR_COST; double parallel_tuple_cost = DEFAULT_PARALLEL_TUPLE_COST; double parallel_setup_cost = DEFAULT_PARALLEL_SETUP_COST; int effective_cache_size = DEFAULT_EFFECTIVE_CACHE_SIZE; Cost disable_cost = 1.0e10;//1后面10个0,通过设置一个巨大的成本,让优化器自动放弃此路径 int max_parallel_workers_per_gather = 2;//每次gather使用的worker数
create_index_path
该函数创建索引扫描路径节点,其中调用函数cost_index计算索引扫描成本.
//----------------------------------------------- create_index_path /* * create_index_path * Creates a path node for an index scan. * 创建索引扫描路径节点 * * 'index' is a usable index. * 'indexclauses' is a list of RestrictInfo nodes representing clauses * to be used as index qual conditions in the scan. * 'indexclausecols' is an integer list of index column numbers (zero based) * the indexclauses can be used with. * '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 ForwardScanDirection or BackwardScanDirection * for an ordered index, or NoMovementScanDirection for * an unordered index. * '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,//优化器信息 IndexOptInfo *index,//索引信息 List *indexclauses,//索引约束条件链表 List *indexclausecols,//索引约束条件列编号链表,与indexclauses一一对应 List *indexorderbys,//ORDER BY原始表达式链表 List *indexorderbycols,//ORDER BY列编号链表 List *pathkeys,//排序路径键 ScanDirection indexscandir,//扫描方向 bool indexonly,//纯索引扫描? Relids required_outer,//需依赖的外部Relids double loop_count,//用于估计缓存的重复次数 bool partial_path)//是否并行索引扫描 { IndexPath *pathnode = makeNode(IndexPath);//构建节点 RelOptInfo *rel = index->rel;//索引对应的Rel List *indexquals, *indexqualcols; pathnode->path.pathtype = indexonly ? T_IndexOnlyScan : T_IndexScan;//路径类型 pathnode->path.parent = rel;//Relation pathnode->path.pathtarget = rel->reltarget;//路径最终的投影列 pathnode->path.param_info = get_baserel_parampathinfo(root, rel, required_outer);//参数化信息 pathnode->path.parallel_aware = false;// pathnode->path.parallel_safe = rel->consider_parallel;//是否并行 pathnode->path.parallel_workers = 0;//worker数目 pathnode->path.pathkeys = pathkeys;//排序路径键 /* Convert clauses to the executor can handle */ //转换条件子句(clauses)为执行器可处理的索引表达式(indexquals) expand_indexqual_conditions(index, indexclauses, indexclausecols, &indexquals, &indexqualcols); /* 填充路径节点信息,Fill in the pathnode */ pathnode->indexinfo = index; pathnode->indexclauses = indexclauses; pathnode->indexquals = indexquals; pathnode->indexqualcols = indexqualcols; pathnode->indexorderbys = indexorderbys; pathnode->indexorderbycols = indexorderbycols; pathnode->indexscandir = indexscandir; cost_index(pathnode, root, loop_count, partial_path);//估算成本 return pathnode; } //------------------------------------ expand_indexqual_conditions /* * expand_indexqual_conditions * Given a list of RestrictInfo nodes, produce a list of directly usable * index qual clauses. * 给定RestrictInfo节点(约束条件),产生直接可用的索引表达式子句 * * Standard qual clauses (those in the index's opfamily) are passed through * unchanged. Boolean clauses and "special" index operators are expanded * into clauses that the indexscan machinery will know what to do with. * RowCompare clauses are simplified if necessary to create a clause that is * fully checkable by the index. * 标准的条件子句(位于索引opfamily中)可不作修改直接使用. * 布尔子句和"special"索引操作符扩展为索引扫描执行器可以处理的子句. * 如需要,RowCompare子句将简化为可由索引完全检查的子句。 * * In addition to the expressions themselves, there are auxiliary lists * of the index column numbers that the clauses are meant to be used with; * we generate an updated column number list for the result. (This is not * the identical list because one input clause sometimes produces more than * one output clause.) * 除了表达式本身之外,还有索引列号的辅助链表,这些子句将使用这些列号.这些列号 * 将被更新用于结果返回(不是相同的链表,因为一个输入子句有时会产生多个输出子句。). * * The input clauses are sorted by column number, and so the output is too. * (This is depended on in various places in both planner and executor.) * 输入子句通过列号排序,输出子句也是如此. */ void expand_indexqual_conditions(IndexOptInfo *index, List *indexclauses, List *indexclausecols, List **indexquals_p, List **indexqualcols_p) { List *indexquals = NIL; List *indexqualcols = NIL; ListCell *lcc, *lci; forboth(lcc, indexclauses, lci, indexclausecols)//扫描索引子句链表和匹配的列号 { RestrictInfo *rinfo = (RestrictInfo *) lfirst(lcc); int indexcol = lfirst_int(lci); Expr *clause = rinfo->clause;//条件子句 Oid curFamily; Oid curCollation; Assert(indexcol < index->nkeycolumns); curFamily = index->opfamily[indexcol];//索引列的opfamily curCollation = index->indexcollations[indexcol];//排序规则 /* First check for boolean cases */ if (IsBooleanOpfamily(curFamily))//布尔 { Expr *boolqual; boolqual = expand_boolean_index_clause((Node *) clause, indexcol, index);//布尔表达式 if (boolqual) { indexquals = lappend(indexquals, make_simple_restrictinfo(boolqual));//添加到结果中 indexqualcols = lappend_int(indexqualcols, indexcol);//列号 continue; } } /* * Else it must be an opclause (usual case), ScalarArrayOp, * RowCompare, or NullTest */ if (is_opclause(clause))//普通的操作符子句 { indexquals = list_concat(indexquals, expand_indexqual_opclause(rinfo, curFamily, curCollation));//合并到结果链表中 /* expand_indexqual_opclause can produce multiple clauses */ while (list_length(indexqualcols) < list_length(indexquals)) indexqualcols = lappend_int(indexqualcols, indexcol); } else if (IsA(clause, ScalarArrayOpExpr))//ScalarArrayOpExpr { /* no extra work at this time */ indexquals = lappend(indexquals, rinfo); indexqualcols = lappend_int(indexqualcols, indexcol); } else if (IsA(clause, RowCompareExpr))//RowCompareExpr { indexquals = lappend(indexquals, expand_indexqual_rowcompare(rinfo, index, indexcol)); indexqualcols = lappend_int(indexqualcols, indexcol); } else if (IsA(clause, NullTest))//NullTest { Assert(index->amsearchnulls); indexquals = lappend(indexquals, rinfo); indexqualcols = lappend_int(indexqualcols, indexcol); } else elog(ERROR, "unsupported indexqual type: %d", (int) nodeTag(clause)); } *indexquals_p = indexquals;//结果赋值 *indexqualcols_p = indexqualcols; } //------------------------------------ cost_index /* * cost_index * Determines and returns the cost of scanning a relation using an index. * 确定和返回索引扫描的成本 * * 'path' describes the indexscan under consideration, and is complete * except for the fields to be set by this routine * path-位于考虑之列的索引扫描路径,除了本例程要设置的字段外其他信息已完整. * * 'loop_count' is the number of repetitions of the indexscan to factor into * estimates of caching behavior * loop_count-用于估计缓存的重复次数 * * In addition to rows, startup_cost and total_cost, cost_index() sets the * path's indextotalcost and indexselectivity fields. These values will be * needed if the IndexPath is used in a BitmapIndexScan. * 除了行、startup_cost和total_cost之外,函数cost_index * 还设置了访问路径的indextotalcost和indexselectivity字段。 * 如果在位图索引扫描中使用IndexPath,则需要这些值。 * * NOTE: path->indexquals must contain only clauses usable as index * restrictions. Any additional quals evaluated as qpquals may reduce the * number of returned tuples, but they won't reduce the number of tuples * we have to fetch from the table, so they don't reduce the scan cost. * 注意:path->indexquals必须仅包含用作索引约束条件的子句。任何作为qpquals评估的 * 额外条件可能会减少返回元组的数量,但它们不会减少必须从表中获取的元组 * 数量,因此它们不会降低扫描成本。 */ void cost_index(IndexPath *path, PlannerInfo *root, double loop_count, bool partial_path) { IndexOptInfo *index = path->indexinfo;//索引信息 RelOptInfo *baserel = index->rel;//RelOptInfo信息 bool indexonly = (path->path.pathtype == T_IndexOnlyScan);//是否纯索引扫描 amcostestimate_function amcostestimate;//索引访问方法成本估算函数 List *qpquals;//qpquals链表 Cost startup_cost = 0;//启动成本 Cost run_cost = 0;//执行成本 Cost cpu_run_cost = 0;//cpu执行成本 Cost indexStartupCost;//索引启动成本 Cost indexTotalCost;//索引总成本 Selectivity indexSelectivity;//选择率 double indexCorrelation,// csquared;// double spc_seq_page_cost, spc_random_page_cost; Cost min_IO_cost,//最小IO成本 max_IO_cost;//最大IO成本 QualCost qpqual_cost;//表达式成本 Cost cpu_per_tuple;//每个tuple处理成本 double tuples_fetched;//取得的元组数量 double pages_fetched;//取得的page数量 double rand_heap_pages;//随机访问的堆page数量 double index_pages;//索引page数量 /* Should only be applied to base relations */ Assert(IsA(baserel, RelOptInfo) && IsA(index, IndexOptInfo)); Assert(baserel->relid > 0); Assert(baserel->rtekind == RTE_RELATION); /* * Mark the path with the correct row estimate, and identify which quals * will need to be enforced as qpquals. We need not check any quals that * are implied by the index's predicate, so we can use indrestrictinfo not * baserestrictinfo as the list of relevant restriction clauses for the * rel. */ if (path->path.param_info)//存在参数化信息 { path->path.rows = path->path.param_info->ppi_rows; /* qpquals come from the rel's restriction clauses and ppi_clauses */ qpquals = list_concat( extract_nonindex_conditions(path->indexinfo->indrestrictinfo, path->indexquals), extract_nonindex_conditions(path->path.param_info->ppi_clauses, path->indexquals)); } else { path->path.rows = baserel->rows;//基表的估算行数 /* qpquals come from just the rel's restriction clauses */跑 qpquals = extract_nonindex_conditions(path->indexinfo->indrestrictinfo, path->indexquals);//从rel的约束条件子句中获取qpquals } if (!enable_indexscan) startup_cost += disable_cost;//禁用索引扫描 /* we don't need to check enable_indexonlyscan; indxpath.c does that */ /* * Call index-access-method-specific code to estimate the processing cost * for scanning the index, as well as the selectivity of the index (ie, * the fraction of main-table tuples we will have to retrieve) and its * correlation to the main-table tuple order. We need a cast here because * relation.h uses a weak function type to avoid including amapi.h. */ amcostestimate = (amcostestimate_function) index->amcostestimate;//索引访问路径成本估算函数 amcostestimate(root, path, loop_count, &indexStartupCost, &indexTotalCost, &indexSelectivity, &indexCorrelation, &index_pages);//调用函数btcostestimate /* * Save amcostestimate's results for possible use in bitmap scan planning. * We don't bother to save indexStartupCost or indexCorrelation, because a * bitmap scan doesn't care about either. */ path->indextotalcost = indexTotalCost;//赋值 path->indexselectivity = indexSelectivity; /* all costs for touching index itself included here */ startup_cost += indexStartupCost; run_cost += indexTotalCost - indexStartupCost; /* estimate number of main-table tuples fetched */ tuples_fetched = clamp_row_est(indexSelectivity * baserel->tuples);//取得的元组数量 /* fetch estimated page costs for tablespace containing table */ get_tablespace_page_costs(baserel->reltablespace, &spc_random_page_cost, &spc_seq_page_cost);//表空间访问page成本 /*---------- * Estimate number of main-table pages fetched, and compute I/O cost. * * When the index ordering is uncorrelated with the table ordering, * we use an approximation proposed by Mackert and Lohman (see * index_pages_fetched() for details) to compute the number of pages * fetched, and then charge spc_random_page_cost per page fetched. * * When the index ordering is exactly correlated with the table ordering * (just after a CLUSTER, for example), the number of pages fetched should * be exactly selectivity * table_size. What's more, all but the first * will be sequential fetches, not the random fetches that occur in the * uncorrelated case. So if the number of pages is more than 1, we * ought to charge * spc_random_page_cost + (pages_fetched - 1) * spc_seq_page_cost * For partially-correlated indexes, we ought to charge somewhere between * these two estimates. We currently interpolate linearly between the * estimates based on the correlation squared (XXX is that appropriate?). * * If it's an index-only scan, then we will not need to fetch any heap * pages for which the visibility map shows all tuples are visible. * Hence, reduce the estimated number of heap fetches accordingly. * We use the measured fraction of the entire heap that is all-visible, * which might not be particularly relevant to the subset of the heap * that this query will fetch; but it's not clear how to do better. *---------- */ if (loop_count > 1)//次数 > 1 { /* * For repeated indexscans, the appropriate estimate for the * uncorrelated case is to scale up the number of tuples fetched in * the Mackert and Lohman formula by the number of scans, so that we * estimate the number of pages fetched by all the scans; then * pro-rate the costs for one scan. In this case we assume all the * fetches are random accesses. */ pages_fetched = index_pages_fetched(tuples_fetched * loop_count, baserel->pages, (double) index->pages, root); if (indexonly) pages_fetched = ceil(pages_fetched * (1.0 - baserel->allvisfrac)); rand_heap_pages = pages_fetched; max_IO_cost = (pages_fetched * spc_random_page_cost) / loop_count; /* * In the perfectly correlated case, the number of pages touched by * each scan is selectivity * table_size, and we can use the Mackert * and Lohman formula at the page level to estimate how much work is * saved by caching across scans. We still assume all the fetches are * random, though, which is an overestimate that's hard to correct for * without double-counting the cache effects. (But in most cases * where such a plan is actually interesting, only one page would get * fetched per scan anyway, so it shouldn't matter much.) */ pages_fetched = ceil(indexSelectivity * (double) baserel->pages); pages_fetched = index_pages_fetched(pages_fetched * loop_count, baserel->pages, (double) index->pages, root); if (indexonly) pages_fetched = ceil(pages_fetched * (1.0 - baserel->allvisfrac)); min_IO_cost = (pages_fetched * spc_random_page_cost) / loop_count; } else //次数 <= 1 { /* * Normal case: apply the Mackert and Lohman formula, and then * interpolate between that and the correlation-derived result. */ pages_fetched = index_pages_fetched(tuples_fetched, baserel->pages, (double) index->pages, root);//取得的page数量 if (indexonly) pages_fetched = ceil(pages_fetched * (1.0 - baserel->allvisfrac));//纯索引扫描 rand_heap_pages = pages_fetched;//随机访问的堆page数量 /* max_IO_cost is for the perfectly uncorrelated case (csquared=0) */ //最大IO成本,假定所有的page都是随机访问获得(csquared=0) max_IO_cost = pages_fetched * spc_random_page_cost; /* min_IO_cost is for the perfectly correlated case (csquared=1) */ //最小IO成本,假定索引和堆数据都是顺序存储(csquared=1) pages_fetched = ceil(indexSelectivity * (double) baserel->pages); if (indexonly) pages_fetched = ceil(pages_fetched * (1.0 - baserel->allvisfrac)); if (pages_fetched > 0) { min_IO_cost = spc_random_page_cost; if (pages_fetched > 1) min_IO_cost += (pages_fetched - 1) * spc_seq_page_cost; } else min_IO_cost = 0; } if (partial_path)//并行 { /* * For index only scans compute workers based on number of index pages * fetched; the number of heap pages we fetch might be so small as to * effectively rule out parallelism, which we don't want to do. */ if (indexonly) rand_heap_pages = -1; /* * Estimate the number of parallel workers required to scan index. Use * the number of heap pages computed considering heap fetches won't be * sequential as for parallel scans the pages are accessed in random * order. */ path->path.parallel_workers = compute_parallel_worker(baserel, rand_heap_pages, index_pages, max_parallel_workers_per_gather); /* * Fall out if workers can't be assigned for parallel scan, because in * such a case this path will be rejected. So there is no benefit in * doing extra computation. */ if (path->path.parallel_workers <= 0) return; path->path.parallel_aware = true; } /* * Now interpolate based on estimated index order correlation to get total * disk I/O cost for main table accesses. * 根据估算的索引顺序关联来插值,以获得主表访问的总I/O成本 */ csquared = indexCorrelation * indexCorrelation; run_cost += max_IO_cost + csquared * (min_IO_cost - max_IO_cost); /* * Estimate CPU costs per tuple. * 估算处理每个元组的CPU成本 * * What we want here is cpu_tuple_cost plus the evaluation costs of any * qual clauses that we have to evaluate as qpquals. */ cost_qual_eval(&qpqual_cost, qpquals, root); startup_cost += qpqual_cost.startup; cpu_per_tuple = cpu_tuple_cost + qpqual_cost.per_tuple; cpu_run_cost += cpu_per_tuple * tuples_fetched; /* tlist eval costs are paid per output row, not per tuple scanned */ startup_cost += path->path.pathtarget->cost.startup; cpu_run_cost += path->path.pathtarget->cost.per_tuple * path->path.rows; /* Adjust costing for parallelism, if used. */ if (path->path.parallel_workers > 0) { double parallel_divisor = get_parallel_divisor(&path->path); path->path.rows = clamp_row_est(path->path.rows / parallel_divisor); /* The CPU cost is divided among all the workers. */ cpu_run_cost /= parallel_divisor; } run_cost += cpu_run_cost; path->path.startup_cost = startup_cost; path->path.total_cost = startup_cost + run_cost; } //------------------------- btcostestimate void btcostestimate(PlannerInfo *root, IndexPath *path, double loop_count, Cost *indexStartupCost, Cost *indexTotalCost, Selectivity *indexSelectivity, double *indexCorrelation, double *indexPages) { IndexOptInfo *index = path->indexinfo; List *qinfos; GenericCosts costs; Oid relid; AttrNumber colnum; VariableStatData vardata; double numIndexTuples; Cost descentCost; List *indexBoundQuals; int indexcol; bool eqQualHere; bool found_saop; bool found_is_null_op; double num_sa_scans; ListCell *lc; /* Do preliminary analysis of indexquals */ qinfos = deconstruct_indexquals(path);//拆解路径,生成条件链表 /* * For a btree scan, only leading '=' quals plus inequality quals for the * immediately next attribute contribute to index selectivity (these are * the "boundary quals" that determine the starting and stopping points of * the index scan). Additional quals can suppress visits to the heap, so * it's OK to count them in indexSelectivity, but they should not count * for estimating numIndexTuples. So we must examine the given indexquals * to find out which ones count as boundary quals. We rely on the * knowledge that they are given in index column order. * 对于btree扫描,只有下一个属性的前导'='条件加上不等号条件 * 有助于索引选择性(这些是确定索引扫描起始和停止的“边界条件”)。 * 额外的条件可以抑制对堆数据的访问,所以在indexSelectivity中 * 统计它们是可以的,但是它们不应该在估算索引元组数目(索引也是元组的一种)的时 * 候统计。因此,必须检查给定的索引条件,以找出哪些被 * 算作边界条件。需依赖索引信息给出的索引列顺序进行判断. * * For a RowCompareExpr, we consider only the first column, just as * rowcomparesel() does. * * If there's a ScalarArrayOpExpr in the quals, we'll actually perform N * index scans not one, but the ScalarArrayOpExpr's operator can be * considered to act the same as it normally does. */ indexBoundQuals = NIL;//索引边界条件 indexcol = 0;//索引列编号 eqQualHere = false;// found_saop = false; found_is_null_op = false; num_sa_scans = 1; foreach(lc, qinfos)//遍历条件链表 { IndexQualInfo *qinfo = (IndexQualInfo *) lfirst(lc); RestrictInfo *rinfo = qinfo->rinfo; Expr *clause = rinfo->clause; Oid clause_op; int op_strategy; if (indexcol != qinfo->indexcol)//indexcol匹配才进行后续处理 { /* Beginning of a new column's quals */ if (!eqQualHere) break; /* done if no '=' qual for indexcol */ eqQualHere = false; indexcol++; if (indexcol != qinfo->indexcol) break; /* no quals at all for indexcol */ } if (IsA(clause, ScalarArrayOpExpr))//ScalarArrayOpExpr { int alength = estimate_array_length(qinfo->other_operand); found_saop = true; /* count up number of SA scans induced by indexBoundQuals only */ if (alength > 1) num_sa_scans *= alength; } else if (IsA(clause, NullTest)) { NullTest *nt = (NullTest *) clause; if (nt->nulltesttype == IS_NULL) { found_is_null_op = true; /* IS NULL is like = for selectivity determination purposes */ eqQualHere = true; } } /* * We would need to commute the clause_op if not varonleft, except * that we only care if it's equality or not, so that refinement is * unnecessary. */ clause_op = qinfo->clause_op; /* check for equality operator */ if (OidIsValid(clause_op))//普通的操作符 { op_strategy = get_op_opfamily_strategy(clause_op, index->opfamily[indexcol]); Assert(op_strategy != 0); /* not a member of opfamily?? */ if (op_strategy == BTEqualStrategyNumber) eqQualHere = true; } indexBoundQuals = lappend(indexBoundQuals, rinfo); } /* * If index is unique and we found an '=' clause for each column, we can * just assume numIndexTuples = 1 and skip the expensive * clauselist_selectivity calculations. However, a ScalarArrayOp or * NullTest invalidates that theory, even though it sets eqQualHere. * 如果index是唯一的,并且我们为每个列找到了一个'='子句,那么可以 * 假设numIndexTuples = 1,并跳过昂贵的clauselist_selectivity计算结果。 * 这种判断不适用于ScalarArrayOp或NullTest。 */ if (index->unique && indexcol == index->nkeycolumns - 1 && eqQualHere && !found_saop && !found_is_null_op) numIndexTuples = 1.0;//唯一索引 else//非唯一索引 { List *selectivityQuals; Selectivity btreeSelectivity;//选择率 /* * If the index is partial, AND the index predicate with the * index-bound quals to produce a more accurate idea of the number of * rows covered by the bound conditions. */ selectivityQuals = add_predicate_to_quals(index, indexBoundQuals);//添加谓词 btreeSelectivity = clauselist_selectivity(root, selectivityQuals, index->rel->relid, JOIN_INNER, NULL);//获取选择率 numIndexTuples = btreeSelectivity * index->rel->tuples;//索引元组数目 /* * As in genericcostestimate(), we have to adjust for any * ScalarArrayOpExpr quals included in indexBoundQuals, and then round * to integer. */ numIndexTuples = rint(numIndexTuples / num_sa_scans); } /* * Now do generic index cost estimation. * 执行常规的索引成本估算 */ MemSet(&costs, 0, sizeof(costs)); costs.numIndexTuples = numIndexTuples; genericcostestimate(root, path, loop_count, qinfos, &costs); /* * Add a CPU-cost component to represent the costs of initial btree * descent. We don't charge any I/O cost for touching upper btree levels, * since they tend to stay in cache, but we still have to do about log2(N) * comparisons to descend a btree of N leaf tuples. We charge one * cpu_operator_cost per comparison. * 添加一个cpu成本组件来表示初始化BTree树层次下降的成本。 * BTree上层节点可以认为已存在于缓存中,因此不耗成本,但沿着树往下沉时,需要 * 执行log2(N)次比较(N个叶子元组的BTree)。每次比较,成本为cpu_operator_cost * * If there are ScalarArrayOpExprs, charge this once per SA scan. The * ones after the first one are not startup cost so far as the overall * plan is concerned, so add them only to "total" cost. * 如存在ScalarArrayOpExprs,则每次SA扫描成本增加cpu_operator_cost */ if (index->tuples > 1) /* avoid computing log(0) */ { descentCost = ceil(log(index->tuples) / log(2.0)) * cpu_operator_cost; costs.indexStartupCost += descentCost; costs.indexTotalCost += costs.num_sa_scans * descentCost; } /* * Even though we're not charging I/O cost for touching upper btree pages, * it's still reasonable to charge some CPU cost per page descended * through. Moreover, if we had no such charge at all, bloated indexes * would appear to have the same search cost as unbloated ones, at least * in cases where only a single leaf page is expected to be visited. This * cost is somewhat arbitrarily set at 50x cpu_operator_cost per page * touched. The number of such pages is btree tree height plus one (ie, * we charge for the leaf page too). As above, charge once per SA scan. * BTree树往下遍历时的成本descentCost=(树高+1)*50*cpu_operator_cost */ descentCost = (index->tree_height + 1) * 50.0 * cpu_operator_cost; costs.indexStartupCost += descentCost; costs.indexTotalCost += costs.num_sa_scans * descentCost; /* * If we can get an estimate of the first column's ordering correlation C * from pg_statistic, estimate the index correlation as C for a * single-column index, or C * 0.75 for multiple columns. (The idea here * is that multiple columns dilute the importance of the first column's * ordering, but don't negate it entirely. Before 8.0 we divided the * correlation by the number of columns, but that seems too strong.) * 如果我们可以从pg_statistical中得到第一列排序相关C的估计,那么对于单列索引, * 可以将索引相关性估计为C,对于多列,可以将其估计为C * 0.75。 * (这里的想法是,多列淡化了第一列排序的重要性,但不要完全否定它。 * 在8.0之前,我们将相关性除以列数,这种做法似乎太过了)。 */ MemSet(&vardata, 0, sizeof(vardata)); if (index->indexkeys[0] != 0) { /* Simple variable --- look to stats for the underlying table */ RangeTblEntry *rte = planner_rt_fetch(index->rel->relid, root); Assert(rte->rtekind == RTE_RELATION); relid = rte->relid; Assert(relid != InvalidOid); colnum = index->indexkeys[0]; if (get_relation_stats_hook && (*get_relation_stats_hook) (root, rte, colnum, &vardata)) { /* * The hook took control of acquiring a stats tuple. If it did * supply a tuple, it'd better have supplied a freefunc. */ if (HeapTupleIsValid(vardata.statsTuple) && !vardata.freefunc) elog(ERROR, "no function provided to release variable stats with"); } else { vardata.statsTuple = SearchSysCache3(STATRELATTINH, ObjectIdGetDatum(relid), Int16GetDatum(colnum), BoolGetDatum(rte->inh)); vardata.freefunc = ReleaseSysCache; } } else { /* Expression --- maybe there are stats for the index itself */ relid = index->indexoid; colnum = 1; if (get_index_stats_hook && (*get_index_stats_hook) (root, relid, colnum, &vardata)) { /* * The hook took control of acquiring a stats tuple. If it did * supply a tuple, it'd better have supplied a freefunc. */ if (HeapTupleIsValid(vardata.statsTuple) && !vardata.freefunc) elog(ERROR, "no function provided to release variable stats with"); } else { vardata.statsTuple = SearchSysCache3(STATRELATTINH, ObjectIdGetDatum(relid), Int16GetDatum(colnum), BoolGetDatum(false)); vardata.freefunc = ReleaseSysCache; } } if (HeapTupleIsValid(vardata.statsTuple)) { Oid sortop; AttStatsSlot sslot; sortop = get_opfamily_member(index->opfamily[0], index->opcintype[0], index->opcintype[0], BTLessStrategyNumber); if (OidIsValid(sortop) && get_attstatsslot(&sslot, vardata.statsTuple, STATISTIC_KIND_CORRELATION, sortop, ATTSTATSSLOT_NUMBERS)) { double varCorrelation; Assert(sslot.nnumbers == 1); varCorrelation = sslot.numbers[0]; if (index->reverse_sort[0]) varCorrelation = -varCorrelation; if (index->ncolumns > 1) costs.indexCorrelation = varCorrelation * 0.75; else costs.indexCorrelation = varCorrelation; free_attstatsslot(&sslot); } } ReleaseVariableStats(vardata); *indexStartupCost = costs.indexStartupCost; *indexTotalCost = costs.indexTotalCost; *indexSelectivity = costs.indexSelectivity; *indexCorrelation = costs.indexCorrelation; *indexPages = costs.numIndexPages; } //------------------------- index_pages_fetched /* * index_pages_fetched * Estimate the number of pages actually fetched after accounting for * cache effects. * 估算在考虑缓存影响后实际获取的页面数量。 * * 估算方法是Mackert和Lohman提出的方法: * "Index Scans Using a Finite LRU Buffer: A Validated I/O Model" * We use an approximation proposed by Mackert and Lohman, "Index Scans * Using a Finite LRU Buffer: A Validated I/O Model", ACM Transactions * on Database Systems, Vol. 14, No. 3, September 1989, Pages 401-424. * The Mackert and Lohman approximation is that the number of pages * fetched is * PF = * min(2TNs/(2T+Ns), T) when T <= b * 2TNs/(2T+Ns) when T > b and Ns <= 2Tb/(2T-b) * b + (Ns - 2Tb/(2T-b))*(T-b)/T when T > b and Ns > 2Tb/(2T-b) * where * T = # pages in table * N = # tuples in table * s = selectivity = fraction of table to be scanned * b = # buffer pages available (we include kernel space here) * * We assume that effective_cache_size is the total number of buffer pages * available for the whole query, and pro-rate that space across all the * tables in the query and the index currently under consideration. (This * ignores space needed for other indexes used by the query, but since we * don't know which indexes will get used, we can't estimate that very well; * and in any case counting all the tables may well be an overestimate, since * depending on the join plan not all the tables may be scanned concurrently.) * * The product Ns is the number of tuples fetched; we pass in that * product rather than calculating it here. "pages" is the number of pages * in the object under consideration (either an index or a table). * "index_pages" is the amount to add to the total table space, which was * computed for us by query_planner. * * Caller is expected to have ensured that tuples_fetched is greater than zero * and rounded to integer (see clamp_row_est). The result will likewise be * greater than zero and integral. */ double index_pages_fetched(double tuples_fetched, BlockNumber pages, double index_pages, PlannerInfo *root) { double pages_fetched; double total_pages; double T, b; /* T is # pages in table, but don't allow it to be zero */ T = (pages > 1) ? (double) pages : 1.0; /* Compute number of pages assumed to be competing for cache space */ total_pages = root->total_table_pages + index_pages; total_pages = Max(total_pages, 1.0); Assert(T <= total_pages); /* b is pro-rated share of effective_cache_size */ b = (double) effective_cache_size * T / total_pages; /* force it positive and integral */ if (b <= 1.0) b = 1.0; else b = ceil(b); /* This part is the Mackert and Lohman formula */ if (T <= b) { pages_fetched = (2.0 * T * tuples_fetched) / (2.0 * T + tuples_fetched); if (pages_fetched >= T) pages_fetched = T; else pages_fetched = ceil(pages_fetched); } else { double lim; lim = (2.0 * T * b) / (2.0 * T - b); if (tuples_fetched <= lim) { pages_fetched = (2.0 * T * tuples_fetched) / (2.0 * T + tuples_fetched); } else { pages_fetched = b + (tuples_fetched - lim) * (T - b) / T; } pages_fetched = ceil(pages_fetched); } return pages_fetched; }
测试脚本如下
select a.*,b.grbh,b.je from t_dwxx a, lateral (select t1.dwbh,t1.grbh,t2.je from t_grxx t1 inner join t_jfxx t2 on t1.dwbh = a.dwbh and t1.grbh = t2.grbh) b where a.dwbh = '1001' order by b.dwbh;
启动gdb
(gdb) b create_index_path Breakpoint 1 at 0x78f050: file pathnode.c, line 1037. (gdb) c Continuing.
主要考察t_grxx上的索引访问路径,即t_grxx.dwbh = '1001'(通过等价类产生并下推的限制条件)
(gdb) c Continuing. Breakpoint 1, create_index_path (root=0x2737d70, index=0x274be80, indexclauses=0x274f1f8, indexclausecols=0x274f248, indexorderbys=0x0, indexorderbycols=0x0, pathkeys=0x0, indexscandir=ForwardScanDirection, indexonly=false, required_outer=0x0, loop_count=1, partial_path=false) at pathnode.c:1037 1037 IndexPath *pathnode = makeNode(IndexPath);
索引信息:树高度为1/索引列1个/indexlist链表,元素为TargetEntry,相关信息为varno = 3, varattno = 1,索引访问方法成本估算使用的函数为btcostestimate
(gdb) p *index $3 = {type = T_IndexOptInfo, indexoid = 16752, reltablespace = 0, rel = 0x274b870, pages = 276, tuples = 100000, tree_height = 1, ncolumns = 1, nkeycolumns = 1, indexkeys = 0x274bf90, indexcollations = 0x274bfa8, opfamily = 0x274bfc0, opcintype = 0x274bfd8, sortopfamily = 0x274bfc0, reverse_sort = 0x274c008, nulls_first = 0x274c020, canreturn = 0x274bff0, relam = 403, indexprs = 0x0, indpred = 0x0, indextlist = 0x274c0f8, indrestrictinfo = 0x274dc58, predOK = false, unique = false, immediate = true, hypothetical = false, amcanorderbyop = false, amoptionalkey = true, amsearcharray = true, amsearchnulls = true, amhasgettuple = true, amhasgetbitmap = true, amcanparallel = true, amcostestimate = 0x94f0ad <btcostestimate>}
执行各项赋值操作
(gdb) n 1038 RelOptInfo *rel = index->rel; (gdb) 1042 pathnode->path.pathtype = indexonly ? T_IndexOnlyScan : T_IndexScan; (gdb) 1043 pathnode->path.parent = rel; (gdb) 1044 pathnode->path.pathtarget = rel->reltarget; (gdb) 1045 pathnode->path.param_info = get_baserel_parampathinfo(root, rel, (gdb) 1047 pathnode->path.parallel_aware = false; (gdb) 1048 pathnode->path.parallel_safe = rel->consider_parallel; (gdb) 1049 pathnode->path.parallel_workers = 0; (gdb) 1050 pathnode->path.pathkeys = pathkeys; (gdb) 1053 expand_indexqual_conditions(index, indexclauses, indexclausecols, (gdb) 1057 pathnode->indexinfo = index;
执行expand_indexqual_conditions,给定RestrictInfo节点(约束条件),产生直接可用的索引表达式子句
(gdb) p *indexclauses $4 = {type = T_List, length = 1, head = 0x274f1d8, tail = 0x274f1d8} -->t_grxx.dwbh = '1001' (gdb) p *indexclausecols $9 = {type = T_IntList, length = 1, head = 0x274f228, tail = 0x274f228} (gdb) p indexclausecols->head->data.int_value $10 = 0
进入cost_index函数
(gdb) 1065 cost_index(pathnode, root, loop_count, partial_path); (gdb) step cost_index (path=0x274ecb8, root=0x2737d70, loop_count=1, partial_path=false) at costsize.c:480 480 IndexOptInfo *index = path->indexinfo;
调用访问方法成本估算函数
... (gdb) 547 amcostestimate(root, path, loop_count, (gdb) 557 path->indextotalcost = indexTotalCost;
相关返回值
(gdb) p indexStartupCost $22 = 0.29249999999999998 (gdb) p indexTotalCost $23 = 4.3675000000000006 (gdb) p indexSelectivity $24 = 0.00010012021638664612 (gdb) p indexCorrelation $25 = 0.82452213764190674 (gdb) p index_pages $26 = 1
loop_count=1
599 if (loop_count > 1) (gdb) 651 (double) index->pages, (gdb) p loop_count $27 = 1
取得的page数量,计算IO大小等
(gdb) n 649 pages_fetched = index_pages_fetched(tuples_fetched, (gdb) 654 if (indexonly) (gdb) p pages_fetched $28 = 10 ... (gdb) p max_IO_cost $30 = 40 (gdb) p min_IO_cost $31 = 4
调用完成,查看最终结果
749 path->path.total_cost = startup_cost + run_cost; (gdb) 750 } (gdb) p *path $37 = {path = {type = T_IndexPath, pathtype = T_IndexScan, parent = 0x274b870, pathtarget = 0x274ba98, param_info = 0x0, parallel_aware = false, parallel_safe = true, parallel_workers = 0, rows = 10, startup_cost = 0.29249999999999998, total_cost = 19.993376803383146, pathkeys = 0x0}, indexinfo = 0x274be80, indexclauses = 0x274f1f8, indexquals = 0x274f3a0, indexqualcols = 0x274f3f0, indexorderbys = 0x0, indexorderbycols = 0x0, indexscandir = ForwardScanDirection, indextotalcost = 4.3675000000000006, indexselectivity = 0.00010012021638664612} (gdb) n create_index_path (root=0x2737d70, index=0x274be80, indexclauses=0x274f1f8, indexclausecols=0x274f248, indexorderbys=0x0, indexorderbycols=0x0, pathkeys=0x0, indexscandir=ForwardScanDirection, indexonly=false, required_outer=0x0, loop_count=1, partial_path=false) at pathnode.c:1067 1067 return pathnode;
该SQL语句的执行计划,其中Index Scan using idx_t_grxx_dwbh on public.t_grxx t1 (cost=0.29..19.99...的成本0.29/19.99,与访问路径中的startup_cost/total_cost相对应.
testdb=# explain verbose select a.*,b.grbh,b.je from t_dwxx a, lateral (select t1.dwbh,t1.grbh,t2.je from t_grxx t1 inner join t_jfxx t2 on t1.dwbh = a.dwbh and t1.grbh = t2.grbh) b where a.dwbh = '1001' order by b.dwbh; QUERY PLAN ------------------------------------------------------------------------------------------------------ Nested Loop (cost=0.87..111.60 rows=10 width=37) Output: a.dwmc, a.dwbh, a.dwdz, t1.grbh, t2.je, t1.dwbh -> Nested Loop (cost=0.58..28.40 rows=10 width=29) Output: a.dwmc, a.dwbh, a.dwdz, t1.grbh, t1.dwbh -> Index Scan using t_dwxx_pkey on public.t_dwxx a (cost=0.29..8.30 rows=1 width=20) Output: a.dwmc, a.dwbh, a.dwdz Index Cond: ((a.dwbh)::text = '1001'::text) -> Index Scan using idx_t_grxx_dwbh on public.t_grxx t1 (cost=0.29..19.99 rows=10 width=9) Output: t1.dwbh, t1.grbh, t1.xm, t1.xb, t1.nl Index Cond: ((t1.dwbh)::text = '1001'::text) -> Index Scan using idx_t_jfxx_grbh on public.t_jfxx t2 (cost=0.29..8.31 rows=1 width=13) Output: t2.grbh, t2.ny, t2.je Index Cond: ((t2.grbh)::text = (t1.grbh)::text) (13 rows)
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