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Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
3
Physical Design
1
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Introduction
 Database Design Methodology







requirements specification
ER/EER modelling
validation of ER/EER models; aggregation of different views
transformation of ER/EER model into relational model
normalisation
physical design
monitor and tune operational system
2
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Outline
 overview of physical design
 base relations and enterprise constraints
• known from before
 transactions analysis
 file organisation and indexes
3
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
1
4
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Physical Design – Rationale
 all the documentation produced until physical design
represents a detailed specification of what we intend
to build, of what is required
 informally, physical design is the process that
transforms these specifications into a good working
system, using the functionality provided by the
chosen DMBS
5
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Overview of Physical Design
 express logical model using the DDL language of the
chosen/target DBMS
 design optimal storage
 design user views
 design security mechanisms
in next lecture
6
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Express Logical Model in Target DBMSd
 essentially covered in the first term
 design and implement base relations
 analyse and document derived data
 design enterprise constraints
7
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Design Base Relations
 are domains supported?
 are attribute constraints supported?
• NOT NULL, UNIQUE
 are keys supported?
 candidate
• primary
• alternate (UNIQUE + NOT NULL)
 foreign
• referential integrity
• FK rules
8
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Analyse and Document Derived Data
 derived attributes
 not present in the relational model;
 but present in the EER model
• it is possible that not all derived attributes are documented thus far
• then, this issue can be given further consideration at this point
 trade-off
 calculate a derived attribute each time it is being used
• may be too time-expensive
 store it in the database
• redundancy, therefore more space required (space-expensive) and
possibility of inconsistencies
• to maintain consistency – integrity constraints of active rules; now
this may become time-expensive
9
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Design Enterprise Constraints
 support for integrity constraints
 e.g., SQL’s
• CONSTRAINT … CHECK … NOT EXISTS …
 support for active rules or triggers
 e.g., Postgres’:
• CREATE RULE … ON UPDATE TO … WHERE … DO …
 example?
10
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Design Optimal Storage
 criteria




maximise transaction throughput
maximise response time
minimise storage space
(they determine and are determined by the system resources)
 issues
 transactions analysis
 file organisation and indexes
11
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
2
12
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Analyse Transactions
 identify critical transactions to the functionality of the
information system
 e.g., transactions that should never fail
 identify transactions that put a significant load on the
DBMS
 run frequently
 processing time is high
 identify the periods when the database system is
heavily used (down to individual transactions)
 identify type of users by whom or locations from
where the database is going to be heavily used
13
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Map Transactions [Paths] to Relations
 identifies mostly used
relations
 matrix
 transactions
 relations
 elements of the matrix:
• Y/N (i.e. used, not used)
• number of accesses
(per hour, day …)
T1
T2
T3
T4
I R UD
I R UD
I R UD
I R UD
rel 1
rel 2
rel 3
rel 4
rel 5
14
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Determine Frequency Information
 determine average, maximum and minimum number
of times a transaction runs per hour, per day, …
 transaction usage map
 determine peak periods
 determine demanding transactions that have in
common some of the resources they access
 problems due to locking
15
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Bookings for Personal Tutor
 (A) check availability
• see if tutor is available
at a specific time
 (B) see my appointments
• list all my appointments
for given period
 (C) see details of my
appointments
• list all my appointments,
including the tutor’s
nameand office
Student
Tutor
name
office
email
With
(A)
name
programme
email
(C)
For
Booking
day
time
topic
(B)
16
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Transaction Usage Maps
frequency: per hour
Student
300
Tutor
20
1
1
With
(A)
avg: 20
max: 200
For
avg: 20
(C) max: 100
0..*
Booking
1500
0..*
(B)
avg: 40
max: 150
17
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Analyse Data Usage
 more detailed analysis
 (relations) attributes and the type of access
• updated attributes – not candidates for access structures
 attributes used in predicates
• are candidates for access structures
 attributes involved in joins
• candidates for access structures
 attributes affecting performance of critical transactions
• higher priority for access structures
 transaction analysis form
• refer to Connolly, p.490
18
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Analyse Transactions - Conclusion
 essentially, the transaction analysis identifies the
critical aspects related to the usage of the database
(e.g., relations used frequently, attributes involved in
“expensive predicates”, …)
 on its basis, file organisations and indexes can be
chosen
19
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
3
20
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
File Organisation
 data has to be stored in an efficient way
• all 4 operations (insert, retrieve, update and delete) require
efficiency
 efficient has different meanings in different contexts
 different storage structures or file organisations
represent efficient ways for different contexts; e.g.
• “heap” structure is suitable for bulk-loading and bulk-retrieval
(all student names, all programmes, …)
• “hash” structure is suitable for “exact match” queries (student
name = ‘Joe Bloggs’)
 note that a structure that is efficient in one context
may not be efficient in a different context
21
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Index
 a structure that allows the DBMS to locate records in
a table/file more quickly
 the decision as of
 which attributes to be chosen as indexes, and
 which type of indexes they should be (which type of file
organisation)
… is determined by the results of the transaction
analysis
22
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
File Organisation vs Index
 file organisation – method of storing data on disk,
with our without the use of indexes
 index – data structure used to access records more
quickly
 primary and clustering index – part of the storage of the
actual records; the records themselves are physically
ordered according to the index
 secondary index – auxiliary data structure; the records may
be (usually are) unordered according to the index;
 index is sometimes used to mean secondary index
 the issue of indexes is subsumed by the issue of file
organisation
23
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
File Structures/Types




Heap / unordered
Index Sequential Access Method
Hash
B+ tree
24
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Heap / Unordered
 records are written in the file in the same way as they
are inserted, at the end of the file
 insertion is efficient, in particular for bulk-loading
 there is no ordering
 retrieval is very inefficient if it involves predicates/conditions
 similarly update and deletion
 the space freed by deleted records is not
automatically reused
 administrator has to run routines
25
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Indexed Sequential Access (ISAM) / Ordered
 records are ordered on the basis of some attributes –
the index field
 primary index – ordering attributes are a key
• one index value to a tuple
 clustering index – ordering attributes are not a key
• one index value to a group of tuples
 sequentially ordered secondary indexes can also be
created
 what is the difference be between a clustering index and a
secondary sequential index?
26
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Use of ISAM Files
 recommended
 exact matching (based on the index field)
 range of values (based on the index field)
 drawback
 ISAM indexes are static (created when the file is created)
 not recommended
 updates to index field
• the access key sequence deteriorates
27
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Hash (“random” or “direct” access)
 a hash function calculates the address where each
record is to be stored
 the calculation is performed on the basis of some fields
 records appear to be randomly distributed across the file
space
 the function should be chosen such that it leads to an as
good as possible distribution of the records in the
available space
 problem : most hashing functions do not guarantee a unique
address, because the file space much smaller than possible
values of hash field
• address generated by hash function  BUCKET (with SLOTS)
• COLLISION (SYNONYMS)  same bucket, different slots
 hash attributes – secondary index
28
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Use of Hash Files
 recommended
 for retrievals based on exact matches, in particular when the
access order (the order in which queries arise) is random
 not recommended




retrieval based on pattern match
retrieval based on ranges of values
retrieval based on other fields than the exact hash filed
when the hash field is frequently updated
29
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
B+ Tree
 B  Balanced tree
 more versatile than the hash structure
 details – optional issue
 recommended




exact match (index filed)
pattern matching (index filed)
range of values (index filed)
part index filed specification
 advantage
 B+ tree is dynamic – it grows as the relation grows
 performance does not deteriorate with updates
 B+ tree – secondary index
30
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Choosing Indexes
 consider results from transactions analysis
 primary/clustering index
 attribute(s) used in joins
 attribute(s) most often used to access the relation
 secondary indexes
 trade-off: maintenance of an index vs. efficiency of queries
• work in class on maintenance operations
 choosing secondary indexes




index primary key (if not already a primary index)
index attributes often involved in joins and selection criteria
do not index attributes which are frequently updated
…
31
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
File Organisation - Conclusion
 pre-defined file-structures exists that provide better
efficiency of certain database operations in certain
contexts
32
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
–
33
Term 2, 2004, Lecture 5, Physical Design
Marian Ursu, Department of Computing, Goldsmiths College
Conclusions
 physical design
 what it consists of
 transaction analysis
 identifies “hot-spots” of the database
 file organisation and indexes
 make work with the “hot-spots” more efficient
34