Presentation is loading. Please wait.

Presentation is loading. Please wait.

CPS216: Advanced Database Systems Notes 08:Query Optimization (Plan Space, Query Rewrites) Shivnath Babu.

Published byTyrone Samson Austin Modified over 8 years ago

Similar presentations

Presentation on theme: "CPS216: Advanced Database Systems Notes 08:Query Optimization (Plan Space, Query Rewrites) Shivnath Babu."— Presentation transcript:

1 CPS216: Advanced Database Systems Notes 08:Query Optimization (Plan Space, Query Rewrites) Shivnath Babu

2 parse Query rewriting Physical plan generation execute result SQL query parse tree logical query planstatistics physical query plan Query Processing - In class order 2; 16.1 3; 16.2,16.3 1; 13, 15 4; 16.4—16.7

3 Roadmap Query optimization: problem definition Space of physical plans –Counting exercise Approaches for query optimization –Heuristic-based (Oracle calls them rule-based) –Cost-based –Hybrid Heuristics for query optimization (Query rewrites)

4 Query Optimization Problem Pick the best plan from the space of physical plans

5 The Space of Physical Plans is Very Large Algebraic equivalences Different physical operators for the same logical operator –nested loop join, hash join, sort-merge join –index-scan, table-scan Different plumbing details - pipelining vs. materialization Different tree shapes

6 A Plan Counting Exercise Work on blackboard

7 Approaches for Query Optimization Approach 1: Pick some plan –Bad plans can be really bad! Approach 2: Heuristics –Ex: maximize use of indexes (MySQL) Approach 3: Cost-based –“Enumerate”, find cost, pick best –Be smart about how you iterate through the plans. Why? Hybrid

8 Query Optimization in Practice Hybrid Use heuristics, called query rewrite rules –eliminate many of the really bad plans –avoid eliminating good plans Cost-based –Be smart about how you iterate through plans –Ex: dynamic programming, genetic search

9 parse Query rewriting Physical plan generation execute result SQL query parse tree logical query plan statistics physical query plan Initial logical plan “Best” logical plan Logical plan Rewrite rules

10 Why do we need Query Rewriting? Pruning the HUGE space of physical plans –Eliminating redundant conditions/operators –Rules that will improve performance with very high probability Preprocessing –Getting queries into a form that we know how to handle best  Reduces optimization time drastically without noticeably affecting quality

11 Query Rewrite Rules Transform one logical plan into another –Do not use statistics Equivalences in relational algebra Push-down predicates Do projects early Avoid cross-products if possible Use left-deep trees Use of constraints, e.g., uniqueness

12 Example Query Select B,D From R,S Where R.A = “c”  R.C=S.C

13 Example: Parse Tree SELECT FROM WHERE AND B R S R.A=“c” R.CS.C= D Select B,D From R,S Where R.A = “c”  R.C=S.C

14 Along with Parsing … Semantic checks –Do the projected attributes exist in the relations in the From clause? –Ambiguous attributes? –Type checking, ex: R.A > 17.5 Expand views

15 Initial Logical Plan Relational Algebra :  B,D [  R.A=“c”  R.C = S.C (RXS)] Select B,D From R,S Where R.A = “c”  R.C=S.C  B,D  R.A = “c” Λ R.C = S.C X RS

16 Apply Rewrite Rule (1)  B,D [  R.C=S.C [  R.A=“c” (R X S)]]  B,D  R.A = “c” Λ R.C = S.C X RS  B,D  R.A = “c” X RS  R.C = S.C

17 Apply Rewrite Rule (2)  B,D [  R.C=S.C [  R.A=“c” (R)] X S]  B,D  R.A = “c” X R S  R.C = S.C  B,D  R.A = “c” X RS  R.C = S.C

18 Apply Rewrite Rule (3)  B,D [[  R.A=“c” (R)] S]  B,D  R.A = “c” R S  B,D  R.A = “c” X R S  R.C = S.C Natural join

19 Equivalences in Relational Algebra R S =SR Commutativity (R S) T = R(S T) Associativity Also holds for: Cross Products, Union, Intersection R x S = S x R (R x S) x T = R x (S x T) R U S = S U R R U (S U T) = (R U S) U T

20 Rules: Project Let: X = set of attributes Y = set of attributes XY = X U Y  xy (R) =  x [  y (R)]

21 Let p = predicate with only R attribs q = predicate with only S attribs m = predicate with only R,S attribs  p (R S) =  q (R S) = Rules:  combined [  p (R)] S R [  q (S)]

22 Rules:  combined (continued)  p  q (R S) = [  p (R)] [  q (S)]  p  q  m (R S) =  m [ (  p R) (  q S) ]  pvq (R S) = [ (  p R) S ] U [ R (  q S) ]

23  p1  p2 (R)   p1 [  p2 (R)]  p (R S)  [  p (R)] S R S  S R  x [  p (R)]   x {  p [  xz (R)] } Which are “good” transformations?

24 Conventional wisdom: do projects early Example: R(A,B,C,D,E) x={E} P: (A=3)  (B=“cat”)  x {  p (R)} vs.  E {  p {  ABE (R)} }

25 But: What if we have A, B indexes? B = “cat” A=3 Intersect pointers to get pointers to matching tuples

26 Bottom line: No transformation is always good Some are usually good: –Push selections down –Avoid cross-products if possible –Subqueries  Joins

27 More Query Rewrite Rules Transform one logical plan into another –Do not use statistics Equivalences in relational algebra Push-down predicates Do projects early Avoid cross-products if possible Use left-deep trees Subqueries  Joins Use of constraints, e.g., uniqueness

28 Avoid Cross Products (if possible) Which join trees avoid cross-products? If you can't avoid cross products, perform them as late as possible Select B,D From R,S,T,U Where R.A = S.B  R.C=T.C  R.D = U.D

29 Use Left Deep Plans What are some left-deep, right-deep, and bushy plans for this query? Why is this heuristic useful? –Reason #1: We maximize the possibility of using indexes –Reason #2: Better for nested-loop join What about hash joins? Homework: Construct examples where (i) right-deep plan is best, (ii) where bushy is best Select B,D From R,S,T,U Where R.A = S.A  R.A=T.A  R.A = U.A

30 More Query Rewrite Rules Transform one logical plan into another –Do not use statistics Equivalences in relational algebra Push-down predicates Do projects early Avoid cross-products if possible Use left-deep trees Subqueries  Joins Use of constraints, e.g., uniqueness

31 SQL Query with an Uncorrelated Subquery Find the movies with stars born in 1960 MovieStar(name, address, gender, birthdate) StarsIn(title, year, starName) SELECT title FROM StarsIn WHERE starName IN ( SELECT name FROM MovieStar WHERE birthdate LIKE ‘%1960’ );

32 Parse Tree SELECT FROM WHERE IN title StarsIn ( ) starName SELECT FROM WHERE LIKE name MovieStar birthDate ‘%1960’

33 Generating Relational Algebra  title  StarsIn IN  name  birthdate LIKE ‘%1960’ starName MovieStar Two-argument selection

34 Rewrite Rule for Two-argument Selection with Conditions Involving IN  Lexp IN Rexp Two-argument selection  Lexp Rexp δ X

35 Applying the Rewrite Rule  title  StarsIn IN  name  birthdate LIKE ‘%1960’ starName MovieStar  title  starName=name StarsIn δ  birthdate LIKE ‘%1960’ MovieStar   name

36 Improving the Logical Query Plan  title starName=name StarsIn  name  birthdate LIKE ‘%1960’ MovieStar  title  starName=name StarsIn δ  birthdate LIKE ‘%1960’ MovieStar   name

37 SQL Query with an Correlated Subquery MovieStar(name, address, gender, birthdate) StarsIn(title, year, starName) SELECT title FROM StarsIn WHERE starName IN ( SELECT name FROM MovieStar WHERE name LIKE ‘Tom%’ and year = birthdate + 30 );

38 parse Query rewriting Physical plan generation execute result SQL query parse tree logical query planstatistics physical query plan Query Processing - In class order 2; 16.1 3; 16.2,16.3 1; 13, 15 4; 16.4—16.7

Download ppt "CPS216: Advanced Database Systems Notes 08:Query Optimization (Plan Space, Query Rewrites) Shivnath Babu."

Similar presentations

CS 44321 CS4432: Database Systems II Logical Plan Rewriting.

CS CS4432: Database Systems II Logical Plan Rewriting.
Query Execution Since our SQL queries are very high level the query processor does a lot of processing to supply all the details. An SQL query is translated.

Query Execution Since our SQL queries are very high level the query processor does a lot of processing to supply all the details. An SQL query is translated.
Query Compiler. The Query Compiler Parses SQL query into parse tree Transforms parse tree into expression tree (logical query plan) Transforms logical.

Query Compiler. The Query Compiler Parses SQL query into parse tree Transforms parse tree into expression tree (logical query plan) Transforms logical.
Cost-Based Transformations. Why estimate costs? Well, sometimes we don’t need cost estimations to decide applying some heuristic transformation. –E.g.

Cost-Based Transformations. Why estimate costs? Well, sometimes we don’t need cost estimations to decide applying some heuristic transformation. –E.g.
Query Execution Optimizing Performance. Resolving an SQL query Since our SQL queries are very high level, the query processor must do a lot of additional.

Query Execution Optimizing Performance. Resolving an SQL query Since our SQL queries are very high level, the query processor must do a lot of additional.
COMP 451/651 Optimizing Performance

COMP 451/651 Optimizing Performance
The Query Compiler Parses SQL query into parse tree Transforms parse tree into expression tree (logical query plan) Transforms logical query plan into.

The Query Compiler Parses SQL query into parse tree Transforms parse tree into expression tree (logical query plan) Transforms logical query plan into.
CMPT 454, Simon Fraser University, Fall 2009, Martin Ester 183 Database Systems II Query Compiler.

CMPT 454, Simon Fraser University, Fall 2009, Martin Ester 183 Database Systems II Query Compiler.
Query Compiler By:Payal Gupta Roll No:106(225) Professor :Tsau Young Lin.

Query Compiler By:Payal Gupta Roll No:106(225) Professor :Tsau Young Lin.
The Query Compiler Section 16.3 DATABASE SYSTEMS – The Complete Book Presented By:Under the supervision of: Deepti KunduDr. T.Y.Lin.

The Query Compiler Section 16.3 DATABASE SYSTEMS – The Complete Book Presented By:Under the supervision of: Deepti KunduDr. T.Y.Lin.
Cost based transformations Initial logical query plan Two candidates for the best logical query plan.

Cost based transformations Initial logical query plan Two candidates for the best logical query plan.
CS 277 - Spring 2002Notes 61 CS 277: Database System Implementation Notes 6: Query Processing Arthur Keller.

CS Spring 2002Notes 61 CS 277: Database System Implementation Notes 6: Query Processing Arthur Keller.
CS 4432query processing - lecture 131 CS4432: Database Systems II Lecture #13 Query Processing Professor Elke A. Rundensteiner.

CS 4432query processing - lecture 131 CS4432: Database Systems II Lecture #13 Query Processing Professor Elke A. Rundensteiner.
CS 4432query processing1 CS4432: Database Systems II.

CS 4432query processing1 CS4432: Database Systems II.
CMSC724: Database Management Systems Instructor: Amol Deshpande

CMSC724: Database Management Systems Instructor: Amol Deshpande
CS 4432logical query rewriting - lecture 151 CS4432: Database Systems II Lecture #15 Logical Query Rewriting Professor Elke A. Rundensteiner.

CS 4432logical query rewriting - lecture 151 CS4432: Database Systems II Lecture #15 Logical Query Rewriting Professor Elke A. Rundensteiner.
The Query Compiler 16.1 Parsing and Preprocessing Meghna Jain(205) Dr. T. Y. Lin.

The Query Compiler 16.1 Parsing and Preprocessing Meghna Jain(205) Dr. T. Y. Lin.
Query Processing & Optimization

Query Processing & Optimization
Algebraic Laws. {P1,P2,…..} {P1,C1>...} parse convert apply laws estimate result sizes consider physical plans estimate costs pick best execute Pi answer.

Algebraic Laws. {P1,P2,…..} {P1,C1>...} parse convert apply laws estimate result sizes consider physical plans estimate costs pick best execute Pi answer.
T HE Q UERY C OMPILER Prepared by : Ankit Patel (226)

T HE Q UERY C OMPILER Prepared by : Ankit Patel (226)

Similar presentations

Ads by Google