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Query Optimization SPRING 2006 CENG 352 Database Management Systems 1 Query Evaluation • Problem: An SQL query is declarative – does not specify a query execution plan. • A relational algebra expression is procedural – there is an associated query execution plan. • Solution: Convert SQL query to an equivalent relational algebra and evaluate it using the associated query execution plan. – But which equivalent expression is best? SPRING 2006 CENG 352 Database Management Systems 2 Naive Conversion SELECT DISTINCT TargetList FROM R1, R2, …, RN WHERE Condition is equivalent to TargetList (Condition (R1 R2 ... RN)) but this may imply a very inefficient query execution plan. Example: Name (Id=ProfId CrsCode=‘CS532’ (Professor Teaching)) • Result can be < 100 bytes • But if each relation is 50K then we end up computing an intermediate result Professor Teaching of size 1G before shrinking it down to just a few bytes. Problem: Find an equivalent relational algebra expression that can be evaluated “efficiently”. SPRING 2006 CENG 352 Database Management Systems 3 Query Processing Architecture SPRING 2006 CENG 352 Database Management Systems 4 Query Optimizer • Uses heuristic algorithms to evaluate relational algebra expressions. This involves: 1. Enumerating alternative plans (Typically a subset of all possible plans). • Needs equivalence rules 2. Estimating the cost of each enumerated plan and choosing the plan with the lowest estimated cost. • Query optimizers actually do not “optimize” – just try to find “reasonably good” evaluation strategies SPRING 2006 CENG 352 Database Management Systems 5 Selection and Projection Rules • Break complex selection into simpler ones: – Cond1Cond2 (R) Cond1 (Cond2 (R) ) • Break projection into stages: – attr (R) attr ( attr (R)), if attr attr • Commute projection and selection: – attr (Cond(R)) Cond ( attr (R)), if attr all attributes in Cond SPRING 2006 CENG 352 Database Management Systems 6 Commutativity and Associativity of Join (and Cartesian Product as Special Case) • Join commutativity: R S S R – used to reduce cost of nested loop evaluation strategies (smaller relation should be in outer loop) • Join associativity: R (S T) (R S) T – used to reduce the size of intermediate relations in computation of multirelational join – first compute the join that yields smaller intermediate result • N-way join has T(N) N! different evaluation plans – T(N) is the number of different binary trees with N leaf nodes – N! is the number of permutations • Query optimizer cannot look at all plans (might take longer to find an optimal plan than to compute query brute-force). Hence it does not necessarily produce optimal plan SPRING 2006 CENG 352 Database Management Systems 7 Pushing Selections and Projections • Cond (R S) R Cond S – Cond relates attributes of both R and S – Reduces size of intermediate relation since rows can be discarded sooner • Cond (R S) Cond (R) S – Cond involves only the attributes of R – Reduces size of intermediate relation since rows of R are discarded sooner • attr(R S) attr(attr (R) S), if attributes(R) attr attr – reduces the size of an operand of product SPRING 2006 CENG 352 Database Management Systems 8 Equivalence Example • C1 C2 C3 (R S) C1 (C2 (C3 (R S) ) ) C1 (C2 (R) C3 (S) ) C2 (R) C1 C3 (S) assuming C2 involves only attributes of R, C3 involves only attributes of S, and C1 relates attributes of R and S SPRING 2006 CENG 352 Database Management Systems 9 Estimating Cost - Example 1 SELECT P.Name FROM Professor P, Teaching T WHERE P.Id = T.ProfId -- join condition AND P. DeptId = ‘CS’ AND T.Semester = ‘F1994’ Name(DeptId=‘CS’ Semester=‘F1994’(Professor Name Master query execution plan (nothing pushed) Id=ProfId Teaching)) DeptId=‘CS’ Semester=‘F1994’ Id=ProfId Professor SPRING 2006 Teaching CENG 352 Database Management Systems 10 Metadata on Tables (in system catalog) – Professor (Id, Name, DeptId) • size: 200 pages, 1000 rows, 50 departments • indexes: clustered, 2-level B+tree on DeptId, hash on Id – Teaching (ProfId, CrsCode, Semester) • size: 1000 pages, 10,000 rows, 4 semesters • indexes: clustered, 2-level B+tree on Semester; hash on ProfId – Definition: Weight of an attribute – average number of rows that have a particular value • weight of Id = 1 (it is a key) • weight of ProfId = 10 (10,000 classes/1000 professors) SPRING 2006 CENG 352 Database Management Systems 11 Estimating Cost - Example 1 • Join - block-nested loops with 52 page buffer (50 pages – input for Professor, 1 page – input for Teaching, 1 – output page – Scanning Professor (outer loop): 200 page transfers, (4 iterations, 50 transfers each) – Finding matching rows in Teaching (inner loop): 1000 page transfers for each iteration of outer loop – Total cost = 200+4*1000 = 4200 page transfers SPRING 2006 CENG 352 Database Management Systems 12 Estimating Cost - Example 1 (cont’d) • Selection and projection – scan rows of intermediate file, discard those that don’t satisfy selection, project on those that do, write result when output buffer is full. • Complete algorithm: – do join, write result to intermediate file on disk – read intermediate file, do select/project, write final result – Problem: unnecessary I/O SPRING 2006 CENG 352 Database Management Systems 13 Pipelining • Solution: use pipelining: – join and select/project act as coroutines, operate as producer/consumer sharing a buffer in main memory. • When join fills buffer; select/project filters it and outputs result • Process is repeated until select/project has processed last output from join – Performing select/project adds no additional cost Intermediate result join SPRING 2006 buffer select/project CENG 352 Database Management Systems output final result 14 Estimating Cost - Example 1 (cont’d) • Total cost: 4200 + (cost of outputting final result) – We will disregard the cost of outputting final result in comparing with other query evaluation strategies, since this will be same for all SPRING 2006 CENG 352 Database Management Systems 15 The resulting Query Execution Plan 1 Name (On-the-fly) DeptId=‘CS’ Semester=‘F1994’ Id=ProfId Professor Pipelining (On-the-fly) (Block Nested Loops) Teaching – Note: different join algorithms (index-nested loop, sort-merge etc.) could have been used for the same tree to get different query execution plans with possibly different costs. SPRING 2006 CENG 352 Database Management Systems 16 Cost Example 2 SELECT P.Name FROM Professor P, Teaching T WHERE P.Id = T.ProfId AND P. DeptId = ‘CS’ AND T.Semester = ‘F1994’ Name(Semester=‘F1994’ (DeptId=‘CS’ (Professor) Name Partially pushed plan: selection pushed to Professor Teaching)) Semester=‘F1994’ DeptId=‘CS’ SPRING 2006 Id=ProfId Professor Id=ProfId Teaching CENG 352 Database Management Systems 17 Cost Example 2 -- selection • Compute DeptId=‘CS’ (Professor) (to reduce size of one join table) using clustered, 2-level B+ tree on DeptId. – 50 departments and 1000 professors; hence weight of DeptId is 20 (roughly 20 CS professors). These rows are in ~4 consecutive pages in Professor. • Cost = 4 (to get rows) + 2 (to search index) = 6 • keep resulting 4 pages in memory and pipe to next step clustered index on DeptId SPRING 2006 CENG 352 Database Management Systems rows of Professor 18 Cost Example 2 -- join • Index-nested loops join using hash index on ProfId of Teaching and looping on the selected professors (computed on previous slide) – Since selection on Semester was not pushed, hash index on ProfId of Teaching can be used – Note: if selection on Semester were pushed, the index on ProfId would have been lost – an advantage of not using a fully pushed query execution plan SPRING 2006 CENG 352 Database Management Systems 19 Cost Example 2 – join (cont’d) – Each professor matches ~10 Teaching rows. Since 20 CS professors, hence 200 teaching records. – All index entries for a particular ProfId are in same bucket. Assume ~1.2 I/Os to get a bucket. • Cost = 1.2 20 (to fetch index entries for 20 CS professors) + 200 (to fetch Teaching rows, since hash index is unclustered) = 224 1.2 ProfId SPRING 2006 20 10 Teaching hash CENG 352 Database Management Systems 20 Cost Example 2 – select/project • Pipe result of join to select (on Semester) and project (on Name) at no I/O cost • Cost of output same as for Example 1 • Total cost: 6 (select on Professor) + 224 (join) = 230 • Comparison: 4200 (example 1) vs. 230 (example 2) !!! SPRING 2006 CENG 352 Database Management Systems 21 Resulting Query Execution Plan 2 Name on the fly Semester=‘F1994’ use clustered B+tree index DeptId=‘CS’ Professor Id=ProfId on the fly indexed nested loop Teaching Note : Other possibilities are block nested-loops, sort-merge. SPRING 2006 CENG 352 Database Management Systems 22 Other Possible Query Trees Name Name DeptId=‘CS’ Id=ProfId Id=ProfId DeptId=‘CS’ Semester=‘F1994’ Semester=‘F1994’ Professor Teaching Professor SPRING 2006 CENG 352 Database Management Systems Teaching 23 Estimating Output Size • It is important to estimate the size of the output of a relational expression – size serves as input to the next stage and affects the choice of how the next stage will be evaluated. • Size estimation uses the following measures on a particular instance of R: – – – – – Tuples(R): number of tuples Blocks(R): number of blocks Values(R.A): number of distinct values of A MaxVal(R.A): maximum value of A MinVal(R.A): minimum value of A SPRING 2006 CENG 352 Database Management Systems 24 Reduction Factor • Consider a query block: SELECT attribute list FROM relation list WHERE term1 term2 ... termn • Every term in WHERE eliminates some of the result tuples. • A reduction factor is associated with each term. • The number of tuples in the result is estimated as the maximum size (i.e. product of cardinalities) times the product of reduction factors. SPRING 2006 CENG 352 Database Management Systems 25 Computing reduction factors • reduction (Ri.A=val) = 1 Values(Ri.A) – if no index and no statistics about the distinct values: 1/10 (arbitrarily). • reduction (Ri.A > val) = MaxVal(Ri.A) – val MaxVal(Ri.A) – MinVal(Ri.A) – No index, not of arithmetic type: 1/2 (arbitrarily). SPRING 2006 CENG 352 Database Management Systems 26 Reduction factors • reduction (Ri.A=Rj.B) = 1 max(Values(Ri.A), Values(Rj.B)) – if only one of the columns have an index: 1 Values(R.A) – if no index: 1/10 arbitrarily SPRING 2006 CENG 352 Database Management Systems 27 Reduction Due to Complex Conditions • reduction(Cond1 AND Cond2) = reduction(Cond1) reduction(Cond2) • reduction(Cond1 OR Cond2) = min(1, reduction(Cond1) + reduction(Cond2)) SPRING 2006 CENG 352 Database Management Systems 28 Reduction Due to TargetList • reduction(TargetList) = number-of-attributes (TargetList) i number-of-attributes (Ri) SPRING 2006 CENG 352 Database Management Systems 29 Choosing Query Execution Plan • Step 1: Choose a logical plan • Step 2: Reduce search space • Step 3: Use a heuristic search to further reduce complexity SPRING 2006 CENG 352 Database Management Systems 30 Step 1: Choosing a Logical Plan • Involves choosing a query tree, which indicates the order in which algebraic operations are applied • Heuristic: Pushed trees are good, but sometimes “nearly fully pushed” trees are better due to indexing (as we saw in the example) • So: Take the initial “master plan” tree and produce a fully pushed tree plus several nearly fully pushed trees. SPRING 2006 CENG 352 Database Management Systems 31 Step 2: Reduce Search Space • Deal with associativity of binary operators (join, union, …) A B C Logical query execution plan SPRING 2006 D D A B C Equivalent query tree C D A B Equivalent left deep query tree CENG 352 Database Management Systems 32 Step 2 (cont’d) • Two issues: – Choose a particular shape of a tree (like in the previous slide) • Equals the number of ways to parenthesize N-way join – grows very rapidly – Choose a particular permutation of the leaves • E.g., 4! permutations of the leaves A, B, C, D SPRING 2006 CENG 352 Database Management Systems 33 Step 2: Dealing With Associativity • Too many trees to evaluate: settle on a particular shape: left-deep tree. – Used because it allows pipelining: P1 P2 A B X X C P3 Y Y D – Property: once a row of X has been output by P1, it need not be output again (but C may have to be processed several times in P2 for successive portions of X) – Advantage: none of the intermediate relations (X, Y) have to be completely materialized and saved on disk. • Important if one such relation is very large, but the final result is small SPRING 2006 CENG 352 Database Management Systems 34 Step 3: Heuristic Search • The choice of left-deep trees still leaves open too many options (N! permutations): – (((A – (((C B) A) C) D) D), B), ….. • A heuristic (often dynamic programming based) algorithm is used to get a ‘good’ plan SPRING 2006 CENG 352 Database Management Systems 35 Step 3: Dynamic Programming Algorithm • To compute a join of E1, E2, …, EN in a leftdeep manner: – Start with 1-relation expressions (can involve , ) – Choose the best and “nearly best” plans for each (a plan is considered nearly best if its output has some “interesting” form, e.g., is sorted) – Combine these 1-relation plans into 2-relation expressions. Retain only the best and nearly best 2relation plans – Do same for 3-relation expressions, etc. SPRING 2006 CENG 352 Database Management Systems 36 Enumeration of Plans • ORDER BY, GROUP BY, aggregates etc. handled as a final step, using either an `interestingly ordered’ plan or an additonal sorting operator. • An N-1 way plan is not combined with an additional relation unless there is a join condition between them, unless all predicates in WHERE have been used up. – i.e., avoid Cartesian products if possible. • In spite of pruning plan space, this approach is still exponential in the # of tables. SPRING 2006 CENG 352 Database Management Systems 37 Example 1 • Pass1: – Sailors: B+ tree on rating Hash on sid Reserves: B+ tree on bid Sailors: B+ tree matches rating>5, and is probably cheapest. However, if this selection is expected to retrieve a lot of tuples, and index is unclustered, file scan may be cheaper. sname sid=sid bid=100 rating > 5 • Still, B+ tree plan kept (because tuples are in rating order). – Reserves: B+ tree on bid matches bid=100; cheapest. Reserves Sailors Pass 2: – We consider each plan retained from Pass 1 as the outer, and consider how to join it with the (only) other relation. e.g., Reserves as outer: Hash index can be used to get Sailors tuples that satisfy sid = outer tuple’s sid value. SPRING 2006 CENG 352 Database Management Systems 38 Example 2 sid,count(*) as numres SELECT S.sid, COUNT(*) As numres FROM Boats B, Reserves R, Sailors S WHERE R.sid = S.sid and B.bid = R.bid and B.color = ‘red GROUP BY S.sid GROUP BYsid sid=sid • Available Indexes : Sailors: B+ tree on sid Hash on sid Reserves: B+ tree on sid B+ tree on bid (clustered) Boats: B+ tree on color Hash on color SPRING 2006 CENG 352 Database Management Systems Sailors bid=bid color = red Reserves Boats 39 • Pass 1: Find best plans for each file. – Sailors: File scan – Reserves: File scan – Boats: hash index on color, B+ tree index on color • Pass 2: Possible joins are considered. – – – – – – – – Reserves Boats Reserves Sailors Sailors Boats Sailors Reserves Boats (access B+ tree) Sailors Boats (access B+ tree) Reserves Boats (access hash) Sailors Boats (access hash) Reserves SPRING 2006 CENG 352 Database Management Systems •For each such pair, consider every join method and for each join method consider every access path for the inner relation. •For each pair keep the cheapest of the plans & the cheapest plan that generates tuples in sorted order 40 • Pass 3: For each plan retained in pass 2, taken as outer relation, consider how to join remaining relation as inner one. Example plan for this pass: Boats (via hash) Reserves (via B+tree) (sort-merge) Result is joined with Sailors (via B+ tree) (sort merge) • GROUP BY is considered after all joins. It requires sorting on sid. SPRING 2006 CENG 352 Database Management Systems 41 Translating Complex SQL Queries into R.A. • As an example consider the following SQL query: SELECT sname, age FROM Sailors WHERE rating > SELECT max(rating) FROM Sailors WHERE age = 30 • Decompose into 2 blocks: SELECT max(rating) FROM Sailors WHERE age = 30 Max(rating (age = 30 (Sailors)) SPRING 2006 SELECT sname, age FROM Sailors WHERE rating > constant sname,age (rating>constant (Sailors)) CENG 352 Database Management Systems 42 Query Blocks: Units of Optimization • An SQL query is parsed into a collection of query blocks, and these are optimized one block at a time. • Nested blocks are usually treated as calls to a subroutine, made once per outer tuple. SELECT S.sname FROM Sailors S WHERE S.age IN (SELECT MAX (S2.age) FROM Sailors S2 GROUP BY S2.rating) Outer block Nested block For each block, the plans considered are: – All available access methods, for each reln in FROM clause. – All left-deep join trees (i.e., all ways to join the relations one-ata-time, with the inner reln in the FROM clause, considering all reln permutations and join methods.) SPRING 2006 CENG 352 Database Management Systems 43 Nested Queries • Nested block is optimized independently, with the outer tuple considered as providing a selection condition. • Outer block is optimized with the cost of `calling’ nested block computation taken into account. • Implicit ordering of these blocks means that some good strategies are not considered. The non-nested version of the query is typically optimized better. SPRING 2006 SELECT S.sname FROM Sailors S WHERE EXISTS (SELECT * FROM Reserves R WHERE R.bid=103 AND R.sid=S.sid) Nested block to optimize: SELECT * FROM Reserves R WHERE R.bid=103 AND S.sid= outer value Equivalent non-nested query: SELECT S.sname FROM Sailors S, Reserves R WHERE S.sid=R.sid CENG 352 Database Management 44 AND R.bid=103 Systems Summary • Query optimization is an important task in a relational DBMS. • Must understand optimization in order to understand the performance impact of a given database design (relations, indexes) on a workload (set of queries). • Two parts to optimizing a query: – Consider a set of alternative plans. • Must prune search space; typically, left-deep plans only. – Must estimate cost of each plan that is considered. • Must estimate size of result and cost for each plan node. • Key issues: Statistics, indexes, operator implementations. SPRING 2006 CENG 352 Database Management Systems 45 Summary (Contd.) • Single-relation queries: – – All access paths considered, cheapest is chosen. Issues: Selections that match index, whether index key has all needed fields and/or provides tuples in a desired order. • Multiple-relation queries: – All single-relation plans are first enumerated. • Selections/projections considered as early as possible. Next, for each 1-relation plan, all ways of joining another relation (as inner) are considered. – Next, for each 2-relation plan that is `retained’, all ways of joining another relation (as inner) are considered, etc. – At each level, for each subset of relations, only best plan for each interesting order is `retained’. SPRING 2006 CENGof 352tuples Database Management 46 – Systems