International Computer Institute, Izmir, Turkey Database Design and Normal Forms

1. International Computer Institute, Izmir, TurkeyDatabase Design and Normal Forms Asst.Prof.Dr.İlker KocabaşUBİ502 at http://ube.ege.edu.tr/~ikocabas

2. Database Design and Normal Forms • First Normal Form • Functional Dependencies • Decomposition • Boyce-Codd Normal Form • Database Design Process

3. First Normal Form • A domain is atomic if its elements are considered to be indivisible units • Examples of non-atomic domains: • Set-valued attributes, composite attributes • Identifiers like UBİ502 that can be broken up into parts • A relational schema R is in first normal form if the domains of all attributes of R are atomic • Non-atomic values • complicate storage • encourage redundancy • interpretation of non-atomic values built into application programs • $cid = substring( $result [ “course-id” ], 1, 3 );

4. First Normal Form (cont) • Atomicity: not an intrinsic property of the elements of the domain • Atomicity is a property of how the elements of the domain are used • E.g. strings containing a possible delimiter (here: space) • cities = “Melbourne Sydney” (non-atomic: space separated list) • surname = “Fortescue Smythe” (atomic: compound surname) • E.g. strings encoding two separate fields • student_id = CS1234 • If the first two characters are extracted to find the department, the domain of student identifiers is not atomic • leads to encoding of information in application program rather than in the database

5. Pitfalls (Traps) in Relational Database Design • Relational database design requires that we find a “good” collection of relation schemas • A bad design may lead to • redundant information • difficulty in representing certain information • difficulty in checking integrity constraints • Design Goals: • Avoid redundant data • Ensure that relationships among attributes are represented • Facilitate the checking of updates for violation of integrity constraints

6. Example of Bad Design • Consider the relation schema:Lending-schema = (branch-name, branch-city, assets, customer-name, loan-number, amount) • Redundant Information: • Data for branch-name, branch-city, assets are repeated for each loan that a branch makes • Wastes space and complicates updates, introducing possibility of inconsistency of assets value • Difficulty representing certain information: • Cannot store information about a branch if no loans exist • Can use null values, but they are difficult to handle

7. Solution: Decomposition • Break up such redundant tables into multiple tables • this operation is called decomposition • E.g. consider Lending-schema again: Lending-schema = (branch-name, branch-city, assets, customer-name, loan-number, amount) • now decompose as follows: Branch-schema = (branch-name, branch-city,assets) Loan-info-schema = (customer-name, loan-number, branch-name, amount) • Want to ensure that the original data is recoverable • all attributes of the original schema (R) must appear in the decomposition (R1, R2), i.e. R = R1  R2 • decomposition must be a lossless-join decomposition

8. Lossless-Join Decomposition: Definition • Let R, R1, R2be schemas and where R = R1  R2 • R1, R2 is a lossless-join decomposition of R • if, for all possible relations r(R) • r =R1 (r)⋈ R2 (r) • Here “possible” means “meaningful in the context of the particular database design” • we will formalize this notion using functional dependencies

9. Lossless-Join Decomposition: Example • Example of Non Lossless-Join Decomposition Decomposition of R = (A, B) R2 = (A) R2 = (B) A B A B A B     1 2 1 2    1 2 1   1 2 B(r) A(r) r A (r) ⋈ B (r) Thus, r is different to A (r) ⋈ B (r) and so A,B is not a lossless-join decomposition of R.

10. Goal — Formalize the notion of good design • Process: • Decide whether a particular relation R is in “good” form. • In the case that a relation R is not in “good” form, decompose it into a set of relations {R1, R2, ..., Rn} such that • each relation is in good form • the decomposition is a lossless-join decomposition • Our theory is based on functional dependencies • Constraints on the set of legal relations • Require that the value for a certain set of attributes determines uniquely the value for another set of attributes • generalizes the notion of a key • Functional dependencies allow us to formalize good database design

11. Functional Dependencies: Definition • Let R be a relation schema   R and   R • The functional dependency (FD)  holds on R iff • for any legal relations r(R) • whenever any two tuples t1and t2 of r agree on the attributes  • they also agree on the attributes  • i.e.(t1) = (t2)   (t1) =  (t2) • Example: Consider r(A,B) with the following instance of r: • On this instance, AB does NOT hold, but BA does hold • 4 1 5 3 7

12. Functional Dependency : AnotherDefinition • A functional dependencyoccurs when the value of one (set of) attribute(s) determines the value of a second (set of) attribute(s): StudentID  StudentName StudentID  (DormName, DormRoom, Fee) • The attribute on the left side of the functional dependency is called the determinant. • Functional dependencies may be based on equations: ExtendedPrice = Quantity X UnitPrice (Quantity, UnitPrice)  ExtendedPrice • Function dependencies are not equations!

13. Composite Determinants • Composite determinant= a determinant of a functional dependency that consists of more than one attribute (StudentName, ClassName)  (Grade) Functional Dependency Rules • If A  (B, C), then A  B and A C. • If (A,B)  C, then neither A nor B determines C by itself.

14. B1...Bm then they must also agree here Functional Dependencies: Visualization General form of a FD: A1...An B1...Bm A1...An t u if t and u agree here

15. Functional Dependencies vs Keys • FDs can express the same constraints we could express using keys: • Superkeys: • K is a superkey for relation schema R if and only if K R • Candidate keys: • K is a candidate key for R if and only if • K R, and • there is no K’  K such that K’ R • However,FDs are more general • i.e. we can express constraints that cannot be expressed using keys

16. Functional Dependencies vs Keys (cont) • Example of FDs that can’t be represented using keys: • Consider the following Loan-info-schema: Loan-info-schema = (customer-name, loan-number, branch-name, amount). We expect these FDs to hold: loan-numberamount loan-number  branch-name We could try to express this by making loan-number the key,however the following FD does not hold: loan-number customer-name

17. Functional Dependencies (cont) • Movies(title, year, length, studioName, starName) title year length studioName starName Star Wars 1977 124 Fox Carrie Fisher Star Wars 1977 124 Fox Harrison Ford Mighty Ducks 1991 104 Disney Emilio Estevez Wayne’s World 1992 95 Paramount Dana Carvey Wayne’s World 1992 95 Paramount Mike Meyers • FD: title, year  length, studioName • not an FD: title, year  starName • candidate key, a minimal K such that K R • propose: K = {title, year, starName} • check: does K functionally determine R? • to answer this question we’ll need to look at closures

18. Functional Dependencies (cont) • An FD is an assertion about a schema, not an instance • If we only consider an instance, we can’t tell if an FD holds • e.g. inspecting the movies relation, we might suggest thatlength  title, since no two films in the table have the same length • However, we cannot assert this FD for the movies relation, since we know it is not true of the domain in general • Thus, identifying FDs is part of the data modelling process

19. Modification Anomalies • Deletion anomaly • Insertion anomaly • Update anomaly • Movies(title, year, length, studioName, starName) title year length studioName starName Star Wars 1977 124 Fox Carrie Fisher Star Wars 1977 124 Fox Harrison Ford Mighty Ducks 1991 104 Disney Emilio Estevez Wayne’s World 1992 95 Paramount Dana Carvey Wayne’s World 1992 95 Paramount Mike Meyers • Update lenght on Row-1 is an anomaly, two different lenghts are recorded.

20. Normal Forms • Relations are categorized as a normal formbased on which modification anomalies or other problems they are subject to:

21. Normal Forms • 1NF—a table that qualifies as a relation is in 1NF. • 2NF—a relation is in 2NF if all of its non-key attributes are dependent on all of the primary keys. • 3NF—a relation is in 3NF if it is in 2NF and has no determinants except the primary key. • Boyce-Codd Normal Form (BCNF)—a relation is in BCNF if every determinant is a candidate key. “I swear to construct my tables so that all non-keycolumns are dependent on the key, the whole key and nothing but the key, so help me Codd.”

22. Eliminating Modification Anomalies from Functional Dependencies in Relations:Put All Relations into BCNF

23. Functional Dependencies: Uses • We use FDs to: • test relations to see if they are legal under a given set of FDs • If a relation r is legal under a set F of FDs, we say that rsatisfies F • specify constraints on the set of legal relations • We say that Fholds onR if all legal relations on R satisfy the set of FDs F • Note: A specific instance of a relation schema may satisfy an FD even if the FD does not hold on all legal instances. • For example, a specific instance of Loan-schema may, by chance, satisfy loan-number customer-name

24. Aside: Trivial Functional Dependencies • An FD is trivial if it is satisfied by all instances of a relation • E.g. • customer-name, loan-number customer-name • customer-name customer-name • In general,  is trivial if  • Permitting such FDs makes certain definitions and algorithms easier to state

25. FD Closure: Definition • Given a set F of fds, there are other FDs logically implied by F • E.g. If A  B and B  C, then we can infer that A  C • The set of all FDs implied by F is the closure of F, written F+ • We can find all ofF+by applying Armstrong’s Axioms: • if   , then   (reflexivity) • if  , then    (augmentation) • if  , and   , then   (transitivity) • Additional rules (derivable from Armstrong’s Axioms): • If   holds and  holds, then    holds (union) • If    holds, then   holds and  holds (decomposition) • If   holds and   holds, then   holds (pseudotransitivity)

26. FD Closure: Example • R = (A, B, C, G, H, I)F = { A BA CCG HCG IB H} • some members of F+ • A H • by transitivity from A B and B H • AG I • by augmenting A C with G, to get AG CG and then transitivity with CG I • CG HI • by union rule with CG H and CG I

27. To compute the closure of a set of FDs F: F+ = Frepeatfor each FD f in F+ apply reflexivity and augmentation rules on fadd the resulting FDs to F+for each pair of FDs f1and f2 in F+iff1 and f2 can be combined using transitivitythen add the resulting FD to F+until F+ does not change any further (NOTE: More efficient algorithms exist) Computing FD Closure

28. Minimal Cover of an FD Set • The opposite of closure: what is the “minimal” set of FDs equivalent to F, having no redundant FDs (or extraneous attributes) • Sets of FDs may have redundant FDs that can be inferred from the others • Eg: A  C is redundant in: {A  B, B  C, A  C} • Parts of an FD may be redundant • E.g. on RHS: {A  B, B  C, A  CD} can be simplified to {A  B, B  C, A  D} • E.g. on LHS: {A  B, B  C, AC  D} can be simplified to {A  B, B  C, A  D} • (We’ll cover these later under the heading of extraneous attributes) • (NB Textbook calls this “canonical” cover, though there is no guarantee of uniqueness.)

29. Closure of Attribute Sets • Given a set of attributes a, define the closureof aunderF (denoted by a+) as the set of attributes that are functionally determined by a under F:ais in F+   a+ • Algorithm to compute a+, the closure of a under F result := a;while (changes to result) do for each in F do begin if  result then result := result end

30. Closure of Attribute Sets: Example • R = (A, B, C, G, H, I) • F = {A BA C CG HCG IB H} • (AG)+ 1. result = AG 2. result = ABCG (A C and A  B) 3. result = ABCGH (CG H and CG  AGBC) 4. result = ABCGHI (CG I and CG  AGBCH) • Is AG a candidate key? • Is AG a superkey? • Does AG R? == Is (AG)+  R • Is any subset of AG a superkey? • Does AR? == Is (A)+  R • Does GR? == Is (G)+  R

31. Testing for superkey: To test if  is a superkey, we compute +, and check if +contains all attributes of R Testing FDs To check if a FD    holds (or, in other words, is in F+), just check if   + i.e. compute +by using attribute closure, and then check if it contains  Is a simple and cheap test, and very useful Closure of Attribute Sets: Uses

32. Extraneous Attributes • Recall that we could have redundant FDs. Parts of FDs can also be redundant • Consider a set F of FDs and the FD   in F. • Attribute A is extraneous in  if A   and F logically implies (F – {})  {( – A) }. • Attribute A is extraneous in  if A  and the set of functional dependencies (F – {})  {(– A)} logically implies F. • Example: Given F = {AC, ABC } • B is extraneous in AB C because {AC, AB C} logically implies AC (I.e. the result of dropping B from AB C). • Example: Given F = {AC, ABCD} • C is extraneous in ABCD since AB C can be inferred even after deleting C

33. Decomposition • Decompose the relation schema Lending-schema into: Branch-schema = (branch-name, branch-city,assets) Loan-info-schema = (customer-name, loan-number, branch-name, amount) • All attributes of an original schema (R) must appear in the decomposition (R1, R2): R = R1  R2 • Lossless-join decomposition.For all possible relations r on schema R r = R1 (r) ⋈ R2 (r) • A decomposition of R into R1 and R2 is lossless-join if and only if at least one of the following dependencies is in F+: • R1 R2R1 • R1 R2R2

34. Decomposition Using Functional Dependencies When we decompose a relation schema R with a set of FDs F into R1, R2,.., Rn we want • Lossless-join decomposition: Otherwise decomposition would result in information loss • No redundancy: The relations Ri should be in BCNF • Dependency preservation: Let Fibe the set of FDs F+ that include only attributes in Ri • Preferably the decomposition should be dependency preserving, that is, (F1 F2  …  Fn)+ = F+ • Otherwise, checking updates for violation of FDs may require computing joins, which is expensive

35. Example • R = (A, B, C)F = {A B, B C) • Can be decomposed in two different ways • R1 = (A, B), R2 = (B, C) • Lossless-join decomposition: R1  R2 = {B} and B BC • Dependency preserving • R1 = (A, B), R2 = (A, C) • Lossless-join decomposition: R1  R2 = {A} and A  AB • Not dependency preserving (cannot check B C without computing R1 ⋈R2)

36. Summary • First Normal Form • Functional Dependencies • Decomposition • to eliminate redundancy • lossless-join • dependency preserving • Next Up: • Boyce-Codd Normal Form • Database Design Process

37. Boyce-Codd Normal Form (BCNF) • A relation schema R is in BCNF with respect to a set F of FDs if • for all FDs in F+ of the form   • where   R and   R • at least one of the following holds: •  is trivial (i.e.,  ), or •  is a superkey for R

38. Example • R = (A, B, C)F = {AB B  C}Key = {A} • R is not in BCNF • Decomposition R1 = (A, B), R2 = (B, C) • R1and R2 in BCNF • Lossless-join decomposition • Dependency preserving • Question: How do we decompose a schema to get BCNF schemas in the general case?

39. BCNF Decomposition • First, we need a method to check if a non-trivial dependency on Rviolates BCNF • compute + (the attribute closure of ), and • verify that it includes all attributes of R • ie. + is a superkey of R • if not, then violates BCNF

40. BCNF Decomposition Algorithm result := {R};done := false;compute F+;while (not done) do if (there is a schema Riin result that is not in BCNF)then beginlet   be a nontrivial functional dependency that holds on Risuch that  Riis not in F+, and   = ;result := (result – Ri )  (Ri – )  (,  );end else done := true; Note: each Riis in BCNF, and decomposition is lossless-join

41. Example of BCNF Decomposition • R = (branch-name, branch-city, assets, customer-name, loan-number, amount) F = {branch-name assets branch-city loan-number amount branch-name} Key = {loan-number, customer-name} • Is R in BCNF? • Are there non-trivial FDs in which the LHS is not a superkey? • FD: branch-name assets branch-city • Is branch-name a superkey? (no) • FD: loan-number amount branch-name • Is loan-number a superkey? (no)

42. Example of BCNF Decomposition (cont) • R = (branch-name, branch-city, assets, customer-name, loan-number, amount) F = {branch-name assets branch-city loan-number amount branch-name} • BCNF Decomposition • consider FDbranch-name assets branch-city •  = branch-name,  = assets branch-city • result := (result – Ri )  (Ri – )  (,  ); • Replace R with  and R- • R1:  = (branch-name,assets, branch-city) • R2: R- = (branch-name, customer-name, loan-number, amount)

43. Example of BCNF Decomposition (cont) • R1 = (branch-name,assets, branch-city)R2 = (branch-name, customer-name, loan-number, amount) F = {branch-name assets branch-city loan-number amount branch-name} • R1 is in BCNF, R2 is not in BCNF • BCNF Decomposition • consider FD loan-number amount branch-name •  = loan-number,  = amount branch-name • Replace R2 with  and R2- • R3:  = (branch-name,loan-number, amount) • R4: R- = (customer-name, loan-number)

44. Example of BCNF Decomposition (cont) • R1 = (branch-name,assets, branch-city)R3 = (branch-name,loan-number, amount)R4 = (customer-name, loan-number) F = {branch-name assets branch-city loan-number amount branch-name} • All relations are now BCNF! • Why does it work – i.e. why is this a lossless-join decomposition?

45. others A’s B’s A’s others B’s Why are BCNF Decompositionslossless-join? • A1...An B1...Bm • For every combination of A’s with others, we repeat the B’s R • So put the B’s in a separate table R1, for which the A’s are keys, and put the remainder in R2 R1 R2

46. Why are BCNF Decompositionslossless-join? (cont) • r = R1 (r) ⋈ R2 (r) ? • Consider R = (A,B,C), FD B  C not in BCNF • BCNF decomposition gives us: R1 = (B, C), R2 = (A, B) • Do we lose any tuples in R1 (r) ⋈ R2 (r) ? • Let t = (a,b,c) be a tuple in r • t projects as (b,c) for R1 and (a,b) for R2 • joining these tuples gives us t back again • thus, we don’t lose any tuples, and so r is contained inR1 (r) ⋈ R2 (r) • Do we gain any tuples in R1 (r) ⋈ R2 (r) ? • Let t = (a,b,c) and u = (d,b,e) be tuples in r • By projecting and joining them, can we create (a,b,e) or (d,b,c)? • Since B  C we know that c=e • So we can’t create any tuple we didn’t already have • Thus, the FD ensures rcontainsR1 (r) ⋈ R2 (r) • Therefore r = R1 (r) ⋈ R2 (r)

47. BCNF and Dependency Preservation • R = (J, K, L)F = {JK L L K}Two candidate keys = JK and JL • R is not in BCNF • Any decomposition of R will fail to preserve JK L • Two solutions: • test FDs across relations • use Third Normal Form It is not always possible to get a BCNF decomposition that is dependency preserving

48. Testing for FDs Across Relations • Suppose that   is a dependency not preserved in a decomposition • Create a new materialized view for   • The materialized view is defined as a projection on   of the join of the relations in the decomposition • Many database systems support materialized views • No extra coding effort for programmer • Declare  as a candidate key on the materialized view • Checking for candidate key is cheaper than checking    • The down-side: • Space overhead: for storing the materialized view • Time overhead: Need to keep materialized view up to date • Database system may not support key declarations on materialized views

49. Aside 1: Third Normal Form • There are some situations where • BCNF is not dependency preserving, and • efficient checking for FD violations is important • Solution: define a weaker normal form, called Third Normal Form. • Allows some redundancy • FDs can be checked on individual relations without computing any joins • There is always a lossless-join, dependency-preserving decomposition into 3NF • Details are beyond the scope of this course

50. Aside 2: SQL Support for FDs • SQL does not provide a direct way of specifying functional dependencies other than superkeys • Can specify FDs using assertions • assertions must express the following type of constraint (t1) = (t2)   (t1) =  (t2) • these are expensive to test (especially if LHS of FD not a key)