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Relational Calculus   Logic, like whiskey, loses its beneficial effect when taken in too large quantities. --Lord Dunsany.

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Presentation on theme: "Relational Calculus   Logic, like whiskey, loses its beneficial effect when taken in too large quantities. --Lord Dunsany."— Presentation transcript:

1 Relational Calculus   Logic, like whiskey, loses its beneficial effect when taken in too large quantities. --Lord Dunsany

2 Relational Calculus Query has the form: {T | p(T)} –p(T) is a formula containing T Answer = tuples T for which p(T) = true.

3 Formulae Atomic formulae: T  Relation T.a op T.b T.a op constant … op is one of A formula can be: – an atomic formula –

4 Free and Bound Variables Quantifiers:  and  Use of or binds X. –A variable that is not bound is free. Recall our definition of a query: –{T | p(T)} Important restriction: — T must be the only free variable in p(T). — all other variables must be bound using a quantifier.

5 Simple Queries Find all sailors with rating above 7 Find names and ages of sailors with rating above 7. –Note: S is a variable of 2 fields (i.e. S is a projection of Sailors) { S |S  Sailors  S.rating > 7} { S |  S1  Sailors ( S1.rating > 7  S.sname = S1.sname  S.age = S1.age )}

6 Find sailors rated > 7 who’ve reserved boat #103 { S | S  Sailors  S.rating > 7   R(R  Reserves  R.sid = S.sid  R.bid = 103) } Joins

7 Joins (continued) This may look cumbersome, but it’s not so different from SQL! { S | S  Sailors  S.rating > 7   R(R  Reserves  R.sid = S.sid   B(B  Boats  B.bid = R.bid  B.color = ‘red’)) } Find sailors rated > 7 who’ve reserved a red boat

8 Universal Quantification Find sailors who’ve reserved all boats { S | S  Sailors   B  Boats (  R  Reserves (S.sid = R.sid  B.bid = R.bid)) }

9 A trickier example… { S | S  Sailors   B  Boats ( B.color = ‘red’   R(R  Reserves  S.sid = R.sid  B.bid = R.bid)) } Find sailors who’ve reserved all Red boats in existence… { S | S  Sailors   B  Boats ( B.color  ‘red’   R(R  Reserves  S.sid = R.sid  B.bid = R.bid)) } Alternatively…

10 a  b is the same as  a  b a T F T F b T TT F

11 A Remark: Unsafe Queries  syntactically correct calculus queries that have an infinite number of answers! Unsafe queries. –e.g., –Solution???? Don’t do that!

12 Your turn … Schema: Movie(title, year, studioName) ActsIn(movieTitle, starName) Star(name, gender, birthdate, salary) Queries to write in Relational Calculus: 1.Find all movies by Paramount studio 2.… movies whose stars are all women 3.… movies starring Kevin Bacon 4.Find stars who have been in a film w/Kevin Bacon 5.Stars within six degrees of Kevin Bacon* 6.Stars connected to K. Bacon via any number of films** * Try two degrees for starters ** Good luck with this one!

13 Answers … 1.Find all movies by Paramount studio {M | M  Movie  M.studioName = ‘Paramount’}

14 Answers … 2.Movies whose stars are all women {M | M  Movie   A  ActsIn((A.movieTitle = M.title)   S  Star(S.name = A.starName  S.gender = ‘F’))}

15 Answers … 3.Movies starring Kevin Bacon {M | M  Movie   A  ActsIn(A.movieTitle = M.title  A.starName = ‘Bacon’))}

16 Answers … 4.Stars who have been in a film w/Kevin Bacon {S | S  Star   A  ActsIn(A.starName = S.name   A2  ActsIn(A2.movieTitle = A.movieTitle  A2.starName = ‘Bacon’))} moviestar A2: S: name… ‘Bacon’ moviestar A:

17 Answers … 5.Stars within six degrees of Kevin Bacon {S | S  Star   A  ActsIn(A.starName = S.name   A2  ActsIn(A2.movieTitle = A.movieTitle   A3  ActsIn(A3.starName = A2.starName   A4  ActsIn(A4.movieTitle = A3.movieTitle  A4.starName = ‘Bacon’))} two

18 Two degrees: S: name… ‘Bacon’ moviestar A2: moviestar A: moviestar A4: moviestar A3:

19 Answers … 6.Stars connected to K. Bacon via any number of films Sorry … that was a trick question –Not expressible in relational calculus!! What about in relational algebra? –We will be able to answer this question shortly …

20 Expressive Power Expressive Power (Theorem due to Codd): –Every query that can be expressed in relational algebra can be expressed as a safe query in relational calculus; the converse is also true. Relational Completeness: Query language (e.g., SQL) can express every query that is expressible in relational algebra/calculus. (actually, SQL is more powerful, as we will see…)

21 Question: Can we express query #6 in relational algebra? A: If we could, then by Codd’s theorem we could also express it in relational calculus. However, we know the latter is not possible, so the answer is no.

22 Summary Formal query languages — simple and powerful. –Relational algebra is operational used as internal representation for query evaluation plans. –Relational calculus is “declarative” query = “what you want”, not “how to compute it” –Same expressive power --> relational completeness. Several ways of expressing a given query –a query optimizer should choose the most efficient version.

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