Post on 19-Dec-2015
transcript
Query Compiler
By:Payal Gupta
Roll No:106(225)
Professor :Tsau Young Lin
Pushing Selections It is, replacing the left side of one of the
rules by its right side.In pushing selections we first a selection as
far up the tree as it would go, and then push the selections down all possible branches.
Let’s take an example:S t a r s I n ( t i t l e , year, starName)Movie(title, year, length, incolor, studioName,
producerC#)
Define view MoviesOf 1996 by: CREATE VIEW MoviesOfl996 AS SELECT * FROM Movie ,WHERE year = 1996;
"which stars worked for which studios in 1996?“ can be given by a SQL Query:
SELECT starName, studioName FROM MoviesOfl996 NATURAL JOIN
StarsIn;
ΠstarName,studioName
O Year=1996 StarsIn
Movie
Logical query plan constructed from definition of a query and view
ΠstarName,studioName
O Year=1996
StarsInMovie
Year=1996O
Improving the query plan by moving selections up and down the tree
"pushing" projections really involves introducing a new projection somewhere below an existing projection.
projection keeps the number of tuples the same and only reduces the length of tuples.
To describe the transformations of extended projection Consider a term E + x on the list for a projection, where E is an attribute or an expression involving attributes and constants and x is an output attribute.
Laws Involving Projection
ExampleLet R(a, b, c) and S(c, d, e) be two relations.
Consider the expression x,+,,,, b+y(R w S). The input attributes of the projection are a,b, and e, and c is the only join attribute. We may apply the law for pushing projections below joins to get the equivalent expression:
Πa+e->x,b->y(Πa,b,c(R) Πc,e(S))
Eliminating this projection and getting a third equivalent expression:Πa+e->x, b->y( R Πc,e(S))
In addition, we can perform a projection entirely before a bag union. That is:
ΠL(R UB S)= ΠL(R) )UB ΠL(S)
Laws About Joins and Productslaws that follow directly from the definition of the
join:
R c S = c( R * S)
R S = ΠL( c ( R * S) ) , where C is the condition that equates each pair of attributes from R and S with the same name. and L is a list that includes one attribute from each equated pair and all the other attributes of R and S.
We identify a product followed by a selection as a join of some kind.
O
O
Laws Involving Duplicate EliminationThe operator δ which eliminates duplicates
from a bag can be pushed through many but not all operators.
In general, moving a δ down the tree reduces the size of intermediate relations and may therefore beneficial.
Moreover, sometimes we can move δ to a position where it can be eliminated altogether,because it is applied to a relation that is known not to possess duplicates.
δ (R)=R if R has no duplicates. Important cases of such a relation R include:
a) A stored relation with a declared primary key, and
b) A relation that is the result of a γ operation, since grouping creates a relation with no duplicates.
Several laws that "push" δ through other operators are:
δ (R*S) =δ(R) * δ(S)δ (R S)=δ(R) δ(S)δ (R c S)=δ(R) c δ(S)δ ( c (R))= c (δ(R))
We can also move the δ to either or both of the arguments of an intersection:
δ (R ∩B S) = δ(R) ∩B S = R ∩B δ (S) = δ(R) ∩B
δ (S)
O O
Laws Involving Grouping and AggregationWhen we consider the operator γ, we find that
the applicability of many transformations depends on the details of the aggregate operators used. Thus we cannot state laws in the generality that we used for the other operators. One exception is that a γ absorbs a δ . Precisely:
δ(γL(R))=γL(R)
let us call an operator γ duplicate-impervious if the only aggregations in L are MIN and/or MAX then:
γ L(R) = γ L (δ(R)) provided γL is duplicate-impervious.
ExampleSuppose we have the relations MovieStar(name , addr , gender, birthdate) StarsIn(movieTitle, movieyear, starname) and we want to know for each year the
birthdate of the youngest star to appear in a movie that year. We can express this query as:
SELECT movieyear, MAX(birth date) FROM MovieStar, StarsIn WHERE name = starName GROUP BY movieyear;
γ movieYear, MAX ( birthdate )
name = starName
MovieStar StarsIn
Initial logical query plan for the query
O
Some transformations that we can apply to Fig are
1. Combine the selection and product into an equijoin.
2.Generate a δ below the γ , since the γ is duplicate- impervious.
3. Generate a Π between the γ and the introduced δ to project onto movie-Year and birthdate, the only attributes relevant to the γ
γ movieYear, MAX ( birthdate )
Π movieYear, birthdate
δ
name = starName
MovieStar StarsIn
Another query plan for the query
γ movieYear, MAX ( birthdate )
Π movieYear, birthdate
name = starName
δ δ
Π birthdate,name Π movieYear,starname
MovieStar StarsIn
third query plan for Example
Thank You