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Lecture 5: Relational calculus

Lecture 5: Relational calculus. www.cl.cam.ac.uk/Teaching/current/Databases/. Relational calculus. There are two versions of the relational calculus: Tuple relational calculus (TRC) Domain relational calculus (DRC) Both TRC and DRC are simple subsets of first-order logic

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Lecture 5: Relational calculus

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  1. Lecture 5:Relational calculus www.cl.cam.ac.uk/Teaching/current/Databases/

  2. Relational calculus • There are two versions of the relational calculus: • Tuple relational calculus (TRC) • Domain relational calculus(DRC) • Both TRC and DRC are simple subsets of first-order logic • The difference is the level at which variables are used: for fields (domains) or for tuples • The calculus is non-procedural (‘declarative’) compared to the relational algebra

  3. Domain relational calculus • Queries have the form {<x1,…,xn>| F(x1,…,xn)}where x1,…,xn are domain variables and F is a formula with free variables {x1,…,xn} • Answer: all tuples <v1,…,vn> that make F(v1,…,vn) true

  4. Example Find all sailors with a rating above 7 {<I,N,R,A> | <I,N,R,A>Sailors  R>7} • The condition <I,N,R,A>Sailors ensures that the domain variables are bound to the appropriate fields of the Sailors tuple

  5. Example • Simple projection:{<I,N> | R,A.<I,N,R,A>Sailors} • Simple projection and selection:{<I,N> | R,A.<I,N,R,A>Sailors  N=`Julia’}

  6. DRC formulae • Atomicformulae: a ::= • <x1,…,xn>R • xibinop xj, xibinopc, cbinop xj, unopc, unop xi • DRC Formulae: P, Q ::= • a • P, PQ, PQ • x.P • x.P • Recall that x and x are binders for x

  7. Example Find the names of sailors rated >7 who’ve reserved boat 103 {<N> | I,A,R.<I,N,R,A>Sailors  R>7  SI,BI,D.(<SI,BI,D>Reserves  I=SI  BI=103)} • Note the use of  and = to ‘simulate’ join

  8. Example Find the names of sailors rated >7 who’ve reserved a red boat {<N> | I,A,R.<I,N,R,A>Sailors  R>7  SI,BI,D. (<SI,BI,D>Reserves  SI=I  B,C. (<B,C>Boats  B=BI  C=‘red’))}

  9. Example Find the names of sailors who have reserved at least two boats {<N> | I,R,A. <I,N,R,A>Sailors  BI1,BI2,D1,D2.<I,BI1,D1>Reserves  <I,BI2,D2>Reserves  BI1BI2 }

  10. Example Find names of sailors who’ve reserved all boats

  11. Example Find names of sailors who’ve reserved all boats {<N> | I,R,A. <I,N,R,A>Sailors  B,C. ((<B,C>Boats)  (<SI,BI,D>Reserves. I=SI  BI=B)) } {<N> | I,R,A. <I,N,R,A>Sailors  <B,C>Boats. <SI,BI,D>Reserves. I=SI  BI=B)) }

  12. Tuple relational calculus • Similar to DRC except that variables range over tuples rather than field values • For example, the query “Find all sailors with rating above 7” is represented in TRC as follows: {S | SSailors  S.rating>7}

  13. Semantics of TRC queries • In general a TRC query is of the form {t | P} where FV(P)={t} • The answer to such a query is the set of all tuples T for which P[T/t] is true

  14. Recall P ranges over tuple values Example Find names and ages of sailors with a rating above 7 {P | SSailors. S.rating>7 P.sname=S.sname P.age=S.age}

  15. Example Find the names of sailors who have reserved at least two boats { P | SSailors. R1Reserves. R2Reserves. S.sid=R1.sid  R1.sid=R2.sid  R1.bid  R2.bid  P.sname=S.sname}

  16. Equivalence with relational algebra • This equivalence was first considered by Codd in 1972 • Codd introduced the notion of relational completeness • A language is relationally complete if it can express all the queries expressible in the relational algebra.

  17. Encoding relational algebra • Let’s consider the first direction of the equivalence: can the relational algebra be coded up in the (domain) relational calculus? • This translation can be done systematically, we define a translation function [-] • Simple case: [R] = {<x1,…,xn> | <x1,…,xn>R}

  18. Encoding selection • Assume [e] = {<x1,…,xn> | F } • Then [sc(e)] = {<x1,…,xn> | F  C’} where C’ is obtained from C by replacing each attribute with the corresponding variable

  19. Encoding relational calculus • Can we code up the relational calculus in the relational algebra? • At the moment, NO! • Given our syntax we can define ‘problematic’ queries such as {S |  (SSailors)} • This (presumably) means the set of all tuples that are not sailors, which is an infinite set… 

  20. Safe queries • A query is said to be safe if no matter how we instantiate the relations, it always produces a finite answer • Unfortunately, safety (a semantic condition) is undecidable • That is, given a arbitrary query, no program can decide if it is safe • Fortunately, we can define a restricted syntactic class of queries which are guaranteed to be safe  • Safe queries can be encoded in the relational algebra

  21. Summary You should now understand • The relational calculus • Tuple relational calculus • Domain relational calculus • Translation from relational algebra to relational calculus • Safe queries and relational completeness Next lecture: Basic SQL

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