BCNF & Lossless Decomposition
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Transcript of BCNF & Lossless Decomposition
BCNF & Lossless Decomposition
Prof. Sin-Min Lee
Department of Computer Science
Normalization
Review on Keys • superkey: a set of attributes which will uniquely
identify each tuple in a relation• candidate key: a minimal superkey• primary key: a chosen candidate key• secondary key: all the rest of candiate keys• prime attribute: an attribute that is a part of a
candidate key (key column)• nonprime attribute: a nonkey column
Normalization
Functional Dependency Type by Keys • ‘whole (candidate) key nonprime attribute’: full
FD (no violation)• ‘partial key nonprime attribute’: partial FD
(violation of 2NF)• ‘nonprime attribute nonprime attribute’:
transitive FD (violation of 3NF)• ‘not a whole key prime attribute’: violation of
BCNF
Functional Dependencies• Let R be a relation schema
R and R
• The functional dependency
holds on R iff for any legal relations r(R), whenever two tuples t1 and t2
of r have same values for , they have same values for .
t1[] = t2 [] t1[ ] = t2 [ ]
• On this instance, A B does NOT hold, but B A does hold.
1 41 53 7
A B
1. Closure • Given a set of functional dependencies, F, its
closure, F+ , is all FDs that are implied by FDs in F.
• e.g. If A B, and B C,
• then clearly A C
Armstrong’s Axioms• We can find F+ by applying Armstrong’s Axioms:
– if , then (reflexivity)– if , then (augmentation)– if , and , then (transitivity)
• These rules are – sound (generate only functional dependencies that actually
hold) and – complete (generate all functional dependencies that hold).
Additional rules• If and , then (union)
• If , then and (decomposition)
• If and , then
(pseudotransitivity)
The above rules can be inferred from Armstrong’s
axioms.
Example• R = (A, B, C, G, H, I)
F = { A B A CCG HCG I B 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 augmenting CG I to infer CG CGI, and augmenting of CG H to infer CGI HI, and then transitivity
2. Closure of an attribute set• Given a set of attributes A and a set of FDs F, closure of A under F is
the set of all attributes implied by A
• In other words, the largest B such that:• A B• Redefining super keys:• The closure of a super key is the entire relation schema• Redefining candidate keys:• 1. It is a super key• 2. No subset of it is a super key
Computing the closure for A
• Simple algorithm
• 1. Start with B = A.
• 2. Go over all functional dependencies, , in F+
• 3. If B, then
• Add to B
• 4. Repeat till B changes
Example• R = (A, B, C, G, H, I)F = { A B
A CCG HCG I B 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 ?
1. It is a super key.
2. (A+) = BC, (G+) = G.
YES.
Uses of attribute set closures
• Determining superkeys and candidate keys
• Determining if A B is a valid FD• Check if A+ contains B
• Can be used to compute F+
Database Normalization
Functional dependency (FD) means that if
there is only one possible value of Y for every value of X, then
Y is Functionally dependent on X.
Is the following FDs hold?
YX
X Y Z10 B1 C1
10 B2 C2
11 B4 C1
12 B3 C4
13 B1 C1
14 B3 C4
YX
YZ
ZY
XY
• Functional Dependency is “good”. With functional dependency the primary key (Attribute A) determines the value of all the other non-key attributes (Attributes B,C,D,etc.)
• Transitive dependency is “bad”. Transitive dependency exists if the primary/candidate key (Attribute A) determines non-key Attribute B, and Attribute B determines non-key Attribute C.
• If a relation schema has more than one key, each is called a candidate key
• An attribute in a relation schema R is called prim if it is a member of some candidate key of R
Database Normalization
First Normal Form (1NF)
Each attribute must be atomic (single value)• No repeating columns within a row (composite attributes)• No multi-valued columns.
1NF simplifies attributes• Queries become easier.
1NF
Deptno Dname Location10 IT Leeds, Bradford, Kent
20 Research Hundredfold
30 Marketing Leeds
Deptno Dname10 IT
20 Research
30 Marketing
Deptno Location10 Leeds
10 Bradfprd
10 Kent
20 Hundredfold
30 Leeds
Second Normal Form (2NF)
Each attribute must be functionally dependent on the primary key.• If the primary key is a single attribute, then the relation is in 2NF• The test for 2NF involves testing for FDs whose left-hand-side
attribute are part of the primary key• Disallow partial dependency, where non-keys attributes depend on
part of a composite primary key • In short, remove partial dependencies
2NF improves data integrity.• Prevents update, insert, and delete anomalies.
2NFPNo PName PLoc EmpNo EName Salary Address HoursNo
Given the following FDs:
Assuming all attributes are atomic, is the above relation in the 1NF, 2NF ?
Relation X1 Relation X3
Relation X2
AddressSalaryNameEmpNo
LocDnamePNo
HoursNoEmpNoPNo
,,
,
,
PNo PName PLoc
EmpNo EName Salary Address
PNo EmpNo HoursNo
Third Normal Form (3NF)Remove transitive dependencies.
Transitive dependencyA non-prime attribute is dependent on another, non-prime A non-prime attribute is dependent on another, non-prime attribute or attributesattribute or attributesAttribute is the result of a calculationAttribute is the result of a calculation
Examples:Area code attribute based on City attribute of a customerTotal price attribute of order entry based on quantity attribute and unit price attribute (calculated value)
Solution:• Any transitive dependencies are moved into a smaller table.
Transitive Dependence
Give a relation R,
Assume the following FD hold:
Note : Both Ename and Address attributes are non-key attributes in R, and since
Address depends on a non-Prime attribute Name, which depends on the primary
key(EmpNo), a transitive dependency exists
EmpNo EName Salary Address
AddressEmpNoAddresstEnameEnameEmpNo ,,
AddressEname
EmpNo EName Salary Ename Address
R1 R2
Note : If address is a prime attribute Then R is in 3NF
Modification Anomalies
• What happens when you want to– add a new book?– change the address of a patron?– delete a patron record?
PatronName
PatronAddress
BookID
BookTitle
BookAuthor
BorrowDate
DueDate
ReturnDate
SmithJonesHartHicksRiceJones
12 Elk25 Sun73 Sera22 Main69 Witt25 Sun
AAABBBCCCAAADDDCCC
PeaceWarSystemPeaceSpringSystem
BartHineVangBartLyonVang
2/42/42/52/122/61/26
2/182/182/192/252/202/7
2/152/192/232/282/82/6
Modification Anomalies• Deletion anomaly
– deleting one fact about an entity deletes a fact about another entity
• Insertion anomaly– cannot insert one fact about an entity unless a
fact about another entity is also added
• Update anomaly– changing one fact about an entity requires
multiple changes to a table
Referential Integrity Constraint
• When we split a relation, we must pay attention to the references across the newly formed relations
• E.g., a book must exist before it can be checked out:– CHECKOUT [BookID] BOOK [BookID]
• The DBMS or the applications will have to check/enforce constraints
Boyce-Codd Normal Form
• Every determinant is a candidate key– ADVISER(SID,Major,Fname)
– STU-ADV(SID,Fname)ADV-SUBJ(Fname,Subject)
Multi-valued Dependency• Two or more functionally independent multi-
valued attributes are dependent on another attribute– EMPLOYEE(Name,Dependent,Project)
• Data redundancy and modification anomalies
• 4NF: BCNF & no multi-valued dependencies– EMPLOYEE(Name,Dependent)– EMPLOYEE(Name, Project)
• Boyce-Codd Normal Form (BCNF)
– A relation is in Boyce-Codd normal form (BCNF) if every determinant in the table is a candidate key.
(A determinant is any attribute whose value determines other values with a row.)
– If a table contains only one candidate key, the 3NF and the BCNF are equivalent.
– BCNF is a special case of 3NF.
Database NormalizationDatabase Normalization
A Table That Is In 3NF But Not In BCNF
Figure 5.7
The Decomposition of a Table Structure to Meet BCNF Requirements
Figure 5.8
Lossless-join Decomposition● For the case of R = (R1, R2), we require that
for all possible relations r on schema R
r = R1 (r ) |X| 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
● 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 |X| R2)
Dependency Preservation● Let Fi be the set of dependencies F +
that include only attributes in Ri. ● A decomposition is dependency preserving, if
(F1 F2 … Fn )+ = F +
● If it is not, then checking updates for violation of functional dependencies may require computing joins, which is expensive.
Dependency Preservation● To check if a dependency is preserved
in a decomposition of R into R1, R2, …, Rn we apply the following test (with attribute closure done with respect to F)
● result = while (changes to result) do
for each Ri in the decompositiont = (result Ri)+ Ri
result = result t● If result contains all attributes in , then the
functional dependency is preserved.
Dependency Preservation
● We apply the test on all dependencies in F to check if a decomposition is dependency preserving
● This procedure takes polynomial time, instead of the exponential time required to compute F+ and (F1 F2 … Fn)+
FD Example● R = (A, B, C )
F = {A B, B C}Key = {A}
● R is not in BCNF● Decomposition R1 = (A, B), R2 = (B,
C)● R1 and R2 now in BCNF● Lossless-join decomposition● Dependency preserving
A Lossy Decomposition
Aim of Normalization
• Goal for a relational database design is:– BCNF.
– Lossless join.
– Dependency preservation.
• If we cannot achieve this, we accept one of– Lack of dependency preservation
– Redundancy due to use of 3NF
Sample Data for a BCNF Conversion
Table 5.2
Decomposition into BCNF
Perform lossless-join decompositions of each of the following scheme into BCNF schemes: R(A, B, C, D, E) with dependency set {AB CDE, C D, D E}
A B C D A B C D
C D D EA B C E A B C D
C DD E A B C A B C
Given the FDs {B D, AB C, D B} and the relation {A, B, C, D}, give a two distinct lossless join decomposition to BNCF indicating the keys of each of the resulting relations.
A B C D
B D A B C
A B C D
B D A C D
Definition of MVD
• A multivalued dependency (MVD) X ->->Y is an assertion that if two tuples of a relation agree on all the attributes of X, then their components in the set of attributes Y may be swapped, and the result will be two tuples that are also in the relation.
Example
• The name-addr-phones-beersLiked example illustrated the MVD
name->->phones
and the MVD
name ->-> beersLiked.
Picture of MVD X ->->Y
X Y others
equal
exchange
MVD Rules
• Every FD is an MVD.– If X ->Y, then swapping Y ’s between two tuples that
agree on X doesn’t change the tuples.– Therefore, the “new” tuples are surely in the
relation, and we know X ->->Y.
• Complementation : If X ->->Y, and Z is all the other attributes, then X ->->Z.
Fourth Normal Form
• The redundancy that comes from MVD’s is not removable by putting the database schema in BCNF.
• There is a stronger normal form, called 4NF, that (intuitively) treats MVD’s as FD’s when it comes to decomposition, but not when determining keys of the relation.
4NF Definition
• A relation R is in 4NF if whenever X ->->Y is a nontrivial MVD, then X is a superkey.
– “Nontrivial means that:1. Y is not a subset of X, and
2. X and Y are not, together, all the attributes.
– Note that the definition of “superkey” still depends on FD’s only.
BCNF Versus 4NF
• Remember that every FD X ->Y is also an MVD, X ->->Y.
• Thus, if R is in 4NF, it is certainly in BCNF.– Because any BCNF violation is a 4NF
violation.
• But R could be in BCNF and not 4NF, because MVD’s are “invisible” to BCNF.
Normalization
Good Decomposition • dependency preserving decomposition
- it is undesirable to lose functional dependencies during decomposition
• lossless join decomposition
- join of decomposed relations should be able to create the original relation (no spurious tuples)
Decomposition and 4NF
• If X ->->Y is a 4NF violation for relation R, we can decompose R using the same technique as for BCNF.
1. XY is one of the decomposed relations.
2. All but Y – X is the other.
Example
Drinkers(name, addr, phones, beersLiked)
FD: name -> addr
MVD’s: name ->-> phones
name ->-> beersLiked
• Key is {name, phones, beersLiked}.
• All dependencies violate 4NF.
Example, Continued
• Decompose using name -> addr:
1. Drinkers1(name, addr) In 4NF, only dependency is name -> addr.
2. Drinkers2(name, phones, beersLiked) Not in 4NF. MVD’s name ->-> phones and
name ->-> beersLiked apply. No FD’s, so all three attributes form the key.
Example: Decompose Drinkers2
• Either MVD name ->-> phones or name ->-> beersLiked tells us to decompose to:– Drinkers3(name, phones)– Drinkers4(name, beersLiked)
BCNF
• Given a relation schema R, and a set of functional dependencies F, if every FD, A B, is either:
• 1. Trivial
• 2. A is a superkey of R
• Then, R is in BCNF (Boyce-Codd Normal Form)
• Why is BCNF good ?
BCNF
• What if the schema is not in BCNF ?
• Decompose (split) the schema into two pieces.
• Careful: you want the decomposition to be lossless
Achieving BCNF Schemas• For all dependencies A B in F+, check if A is a superkey
• By using attribute closure
• If not, then • Choose a dependency in F+ that breaks the BCNF rules, say A B
• Create R1 = A B
• Create R2 = A (R – B – A)
• Note that: R1 ∩ R2 = A and A AB (= R1), so this is lossless decomposition
• Repeat for R1, and R2• By defining F1+ to be all dependencies in F that contain only attributes in R1
• Similarly F2+
Example 1
B C
• R = (A, B, C)• F = {A B, B C}• Candidate keys = {A}
• BCNF = No. B C violates.
• R1 = (B, C)
• F1 = {B C}
• Candidate keys = {B}
• BCNF = true
• R2 = (A, B)
• F2 = {A B}
• Candidate keys = {A}
• BCNF = true
Example 2-1
A B
• R = (A, B, C, D, E)
• F = {A B, BC D}
• Candidate keys = {ACE}
• BCNF = Violated by {A B, BC D} etc…
• R1 = (A, B)
• F1 = {A B}
• Candidate keys = {A}
• BCNF = true
• R2 = (A, C, D, E)
• F2 = {AC D}
• Candidate keys = {ACE}
• BCNF = false (AC D)
• From A B and BC D by pseudo-transitivity
AC D
• R3 = (A, C, D)
• F3 = {AC D}
• Candidate keys = {AC}
• BCNF = true
• R4 = (A, C, E)• F4 = {} [[ only trivial ]]
• Candidate keys = {ACE}
• BCNF = true
• Dependency preservation ???• We can check: • A B (R1), AC D (R3), • but we lost BC D• So this is not a dependency• -preserving decomposition
Example 2-2
BC D
• R = (A, B, C, D, E)
• F = {A B, BC D}
• Candidate keys = {ACE}
• BCNF = Violated by {A B, BC D} etc…
• R1 = (B, C, D)
• F1 = {BC D}
• Candidate keys = {BC}
• BCNF = true
• R2 = (B, C, A, E)
• F2 = {A B}
• Candidate keys = {ACE}
• BCNF = false (A B)
A B• R3 = (A, B)
• F3 = {A B}
• Candidate keys = {A}
• BCNF = true
• R4 = (A, C, E)• F4 = {} [[ only trivial ]]
• Candidate keys = {ACE}
• BCNF = true
• Dependency preservation ???
• We can check:
• BC D (R1), A B (R3),
• Dependency-preserving
• decomposition
Example 3
A BC
• R = (A, B, C, D, E, H)• F = {A BC, E HA}• Candidate keys = {DE}
• BCNF = Violated by {A BC} etc…
• R1 = (A, B, C)
• F1 = {A BC}
• Candidate keys = {A}
• BCNF = true
• R2 = (A, D, E, H)
• F2 = {E HA}
• Candidate keys = {DE}
• BCNF = false (E HA)
E HA
• R3 = (E, H, A)
• F3 = {E HA}
• Candidate keys = {E}
• BCNF = true
• R4 = (ED)• F4 = {} [[ only trivial ]]• Candidate keys = {DE}
• BCNF = true
• Dependency preservation ???
• We can check:
• A BC (R1), E HA (R3),
• Dependency-preserving
• decomposition