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About This Presentation
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Slide Content
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 1
Profession
A Physician, a Civil Engineer and a Computer Scientist were arguing
about what was the oldest profession in the world.
The Physician remarked,
"Well, in the Bible, it says that God created Eve from a rib taken out of Adam.
This clearly requires surgery, and so I can rightly claim that mine is the oldest
profession in the world."
The Civil Engineer interrupted, and said,
" But even earlier in the book of Genesis, it states that God created the order of
the heavens and the earth from out of the chaos. This was the first and certainly
the most spectacular application of civil engineering. Therefore, fair doctor,
you are wrong; mine is the oldest profession in the world.“
The Computer Scientist leaned back in the chair, smiled and
then said confidently,
"Ah, but what do you think created the chaos ? "
Profession
A Physician, a Civil Engineer and a Computer Scientist were arguing
about what was the oldest profession in the world.
The Physician remarked,
"Well, in the Bible, it says that God created Eve from a rib taken out of Adam.
This clearly requires surgery, and so I can rightly claim that mine is the oldest
profession in the world."
The Civil Engineer interrupted, and said,
" But even earlier in the book of Genesis, it states that God created the order of
the heavens and the earth from out of the chaos. This was the first and certainly
the most spectacular application of civil engineering. Therefore, fair doctor,
you are wrong; mine is the oldest profession in the world.“
The Computer Scientist leaned back in the chair, smiled and
then said confidently,
"Ah, but what do you think created the chaos ? "
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Chapter 1: Introduction
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Chapter 1: Introduction
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 3
Objectives of the Class
Appreciate Software Engineering:
Build complex software systems in the context of frequent change
Understand how to
produce a high quality software system within time
while dealing with complexity and change
Acquire technical knowledge (main emphasis)
Acquire managerial knowledge
Understand the Software Lifecycle
Process vs Product
Learn about different software lifecycles
Greenfield Engineering – from scratch,
Interface Engineering – a kind of Reengineering for legacy systems,
Reengineering – [Hammer & Champy, 1993]
Objectives of the Class
Appreciate Software Engineering:
Build complex software systems in the context of frequent change
Understand how to
produce a high quality software system within time
while dealing with complexity and change
Acquire technical knowledge (main emphasis)
Acquire managerial knowledge
Understand the Software Lifecycle
Process vs Product
Learn about different software lifecycles
Greenfield Engineering – from scratch,
Interface Engineering – a kind of Reengineering for legacy systems,
Reengineering – [Hammer & Champy, 1993]
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 4
Acquire Technical Knowledge
Understand System Modeling
Learn About Modeling
Using (~20% and some) Aspects of UML (Unified Modeling Language)
Learn about modeling at different phases of software lifecycle:
Requirements Elicitation [Chap. 4] –---------------------- Deliverable 1
(Requirements) Analysis* [Chap 5] ----------------------- Deliverable 2
Architectural Design [Chap 6 & 7] ----------------------- Deliverable 3
Object/Component Design [Chap 8] ---------------------- Deliverable 4
Coding [Chap 10] ---------------------- Deliverable 5
Testing [Chap 11] ---------------------- Deliverable 6
(during
demo)
*An old school of thought mixing the domain model with the solution model, being design-oriented, and in a
Waterfall fashion.
Learn about Traceability among Models
Learn how to use Tools: CASE (Computer Aided Software Engineering)
Brugge’s
e.g., Rational Rose
Acquire Technical Knowledge
Understand System Modeling
Learn About Modeling
Using (~20% and some) Aspects of UML (Unified Modeling Language)
Learn about modeling at different phases of software lifecycle:
Requirements Elicitation [Chap. 4] –---------------------- Deliverable 1
(Requirements) Analysis* [Chap 5] ----------------------- Deliverable 2
Architectural Design [Chap 6 & 7] ----------------------- Deliverable 3
Object/Component Design [Chap 8] ---------------------- Deliverable 4
Coding [Chap 10] ---------------------- Deliverable 5
Testing [Chap 11] ---------------------- Deliverable 6
(during
demo)
*An old school of thought mixing the domain model with the solution model, being design-oriented, and in a
Waterfall fashion.
Learn about Traceability among Models
Learn how to use Tools: CASE (Computer Aided Software Engineering)
Brugge’s
e.g., Rational Rose
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 5
Readings
Required:
Bernd Bruegge, Allen Dutoit: “Object-Oriented Software
Engineering: Using UML, Patterns, and Java”, Prentice Hall, 2003.
Recommended:
Applying UML and Patterns: An Introduction to Object-Oriented
Analysis and Design and the Unified Process, 2nd ed., C. Larman
Erich Gamma, Richard Helm, Ralph Johnson, John Vlissides:
“Design Patterns”, Addison-Wesley, 1996.
Grady Booch, James Rumbaugh, Ivar Jacobson, “The Unified
Modeling Language User Guide”, Addison Wesley, 1999.
K. Popper, “Objective Knowledge, an Evolutionary Approach,
Oxford Press, 1979.
Additional books may be recommended during individuals lectures
Lecture Notes will adapt Bruegge’s,
but with additional points and questions
possibly from very different perspectives.
Readings
Required:
Bernd Bruegge, Allen Dutoit: “Object-Oriented Software
Engineering: Using UML, Patterns, and Java”, Prentice Hall, 2003.
Recommended:
Applying UML and Patterns: An Introduction to Object-Oriented
Analysis and Design and the Unified Process, 2nd ed., C. Larman
Erich Gamma, Richard Helm, Ralph Johnson, John Vlissides:
“Design Patterns”, Addison-Wesley, 1996.
Grady Booch, James Rumbaugh, Ivar Jacobson, “The Unified
Modeling Language User Guide”, Addison Wesley, 1999.
K. Popper, “Objective Knowledge, an Evolutionary Approach,
Oxford Press, 1979.
Additional books may be recommended during individuals lectures
Lecture Notes will adapt Bruegge’s,
but with additional points and questions
possibly from very different perspectives.
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 6
Outline of Today’s Lecture
Software Engineering – Why, What and How?
Modeling complex systems
Functional vs. object-oriented decomposition
Software Lifecycle Modeling
Reuse:
Design Patterns
Frameworks
Concluding remarks
Outline of Today’s Lecture
Software Engineering – Why, What and How?
Modeling complex systems
Functional vs. object-oriented decomposition
Software Lifecycle Modeling
Reuse:
Design Patterns
Frameworks
Concluding remarks
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 7
Why Software Engineering?
Used w. extensive rework,
but later abandoned
20%
Used as delivered
2%
Usable w. rework
3%
9 software projects totaling $96.7 million: Where The Money Went
[Report to Congress, Comptroller General, 1979]
Delivered, but never
successfully used
45%
Paid for, but
not delivered
30%
Take a look at the Standish Report (The “Chaos” Report)
Why Software Engineering?
Used w. extensive rework,
but later abandoned
20%
Used as delivered
2%
Usable w. rework
3%
9 software projects totaling $96.7 million: Where The Money Went
[Report to Congress, Comptroller General, 1979]
Delivered, but never
successfully used
45%
Paid for, but
not delivered
30%
Take a look at the Standish Report (The “Chaos” Report)
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 8
Software Engineering: A Problem Solving Activity
Analysis: Understand the nature of the problem and break the
problem into pieces
Synthesis: Put the pieces together into a large structure
For problem solving we use
Techniques (methods):
Formal procedures for producing results using some well-defined
notation
Methodologies:
Collection of techniques applied across software development and
unified by a philosophical approach
Tools:
Instrument or automated systems to accomplish a technique
Isn’t there something more fundamental than problem “solving”?
Software Engineering: A Problem Solving Activity
Analysis: Understand the nature of the problem and break the
problem into pieces
Synthesis: Put the pieces together into a large structure
For problem solving we use
Techniques (methods):
Formal procedures for producing results using some well-defined
notation
Methodologies:
Collection of techniques applied across software development and
unified by a philosophical approach
Tools:
Instrument or automated systems to accomplish a technique
Isn’t there something more fundamental than problem “solving”?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 920
Software Engineering: Definition
Software Engineering is a collection of techniques,
methodologies and tools that help
with the production of
a high quality software system
with a given budget
before a given deadline
while change occurs.
Software Engineering: Definition
Software Engineering is a collection of techniques,
methodologies and tools that help
with the production of
a high quality software system
with a given budget
before a given deadline
while change occurs.
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 10
Scientist vs Engineer
Computer Scientist
Proves theorems about algorithms, designs languages, defines
knowledge representation schemes
Has infinite time…
Engineer
Develops a solution for an application-specific problem for a client
Uses computers & languages, tools, techniques and methods
Software Engineer
Works in multiple application domains
Has only 3 months...
…while changes occurs in requirements and available technology
Isn’t there something more fundamental about “Software” Engineer?
Scientist vs Engineer
Computer Scientist
Proves theorems about algorithms, designs languages, defines
knowledge representation schemes
Has infinite time…
Engineer
Develops a solution for an application-specific problem for a client
Uses computers & languages, tools, techniques and methods
Software Engineer
Works in multiple application domains
Has only 3 months...
…while changes occurs in requirements and available technology
Isn’t there something more fundamental about “Software” Engineer?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 11
Factors affecting the quality of a software system
Complexity:
The system is so complex that no single programmer can understand it
anymore
The introduction of one bug fix causes another bug
Change:
The “Entropy” of a software system increases with each change: Each
implemented change erodes the structure of the system which makes the
next change even more expensive (“Second Law of Software
Dynamics”).
As time goes on, the cost to implement a change will be too high, and
the system will then be unable to support its intended task. This is true
of all systems, independent of their application domain or technological
base.
Factors affecting the quality of a software system
Complexity:
The system is so complex that no single programmer can understand it
anymore
The introduction of one bug fix causes another bug
Change:
The “Entropy” of a software system increases with each change: Each
implemented change erodes the structure of the system which makes the
next change even more expensive (“Second Law of Software
Dynamics”).
As time goes on, the cost to implement a change will be too high, and
the system will then be unable to support its intended task. This is true
of all systems, independent of their application domain or technological
base.
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 12
Complex Server Connections
Complex Server Connections
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 13
Complex Message Flow
Complex Message Flow
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 14
Dealing with Complexity
1.Abstraction
2.Decomposition
3.Hierarchy
What is this?
Dealing with Complexity
1.Abstraction
2.Decomposition
3.Hierarchy
What is this?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 15
1. Models are used to provide abstractions
System Model:
Object Model: What is the structure of the system? What are the objects and how
are they related?
Functional model: What are the functions of the system? How is data flowing
through the system?
Dynamic model: How does the system react to external events? How is the event flow
in the system ?
Task Model:
PERT Chart: What are the dependencies between the tasks?
Schedule: How can this be done within the time limit?
Org Chart: What are the roles in the project or organization?
Issues Model:
What are the open and closed issues? What constraints were posed by the client?
What resolutions were made?
Inherent human limitation to deal with complexity
The 7 +- 2 phenomena
Chunking: Group collection of objects
Ignore unessential details: => Models
1.Abstraction
2.Decomposition
3.Hierarchy
What does this refer to?
In UML?
1. Models are used to provide abstractions
System Model:
Object Model: What is the structure of the system? What are the objects and how
are they related?
Functional model: What are the functions of the system? How is data flowing
through the system?
Dynamic model: How does the system react to external events? How is the event flow
in the system ?
Task Model:
PERT Chart: What are the dependencies between the tasks?
Schedule: How can this be done within the time limit?
Org Chart: What are the roles in the project or organization?
Issues Model:
What are the open and closed issues? What constraints were posed by the client?
What resolutions were made?
Inherent human limitation to deal with complexity
The 7 +- 2 phenomena
Chunking: Group collection of objects
Ignore unessential details: => Models
1.Abstraction
2.Decomposition
3.Hierarchy
What does this refer to?
In UML?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 17
Model-based software Engineering:
Code is a derivation of object model
Problem Statement: A stock exchange lists many companies.
Each company is identified by a ticker symbol
public class StockExchange
{
public Vector m_Company = new Vector();
};
public class Company
{
public int m_tickerSymbol
public Vector m_StockExchange = new Vector();
};
Implementation phase results in code
Analysis phase results in object model (UML Class Diagram):
StockExchange
Company
tickerSymbol
Lists
**
A good software engineer writes as little code as possible
Is this a “problem”?
Where is the design, then?
Model-based software Engineering:
Code is a derivation of object model
Problem Statement: A stock exchange lists many companies.
Each company is identified by a ticker symbol
public class StockExchange
{
public Vector m_Company = new Vector();
};
public class Company
{
public int m_tickerSymbol
public Vector m_StockExchange = new Vector();
};
Implementation phase results in code
Analysis phase results in object model (UML Class Diagram):
StockExchange
Company
tickerSymbol
Lists
**
A good software engineer writes as little code as possible
Is this a “problem”?
Where is the design, then?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 18
Example of an Issue: Galileo vs the Church
What is the center of the Universe?
Church: The earth is the center of the universe. Why? Aristotle
says so.
Galileo: The sun is the center of the universe. Why? Copernicus
says so. Also, the Jupiter’s moons rotate round Jupiter, not around
Earth.
Example of an Issue: Galileo vs the Church
What is the center of the Universe?
Church: The earth is the center of the universe. Why? Aristotle
says so.
Galileo: The sun is the center of the universe. Why? Copernicus
says so. Also, the Jupiter’s moons rotate round Jupiter, not around
Earth.
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 19
Issue-Modeling
Issue:
What is the
Center of the
Universe?
Proposal1:
The earth!
Proposal2:
The sun!
Pro:
Copernicus
says so.
Pro:
Aristotle
says so.
Pro:
Change will disturb
the people.
Con:
Jupiter’s moons rotate
around Jupiter, not
around Earth.
Resolution (1615):
The church
decides proposal 1
is right
Resolution (1998):
The church declares
proposal 1 was wrong
Anything missing?
Issue-Modeling
Issue:
What is the
Center of the
Universe?
Proposal1:
The earth!
Proposal2:
The sun!
Pro:
Copernicus
says so.
Pro:
Aristotle
says so.
Pro:
Change will disturb
the people.
Con:
Jupiter’s moons rotate
around Jupiter, not
around Earth.
Resolution (1615):
The church
decides proposal 1
is right
Resolution (1998):
The church declares
proposal 1 was wrong
Anything missing?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 20
Which decomposition is the right one?
2. Decomposition
A technique used to master complexity (“divide and conquer”)
Functional decomposition
The system is decomposed into modules
Each module is a major processing step (function) in the
application domain
Modules can be decomposed into smaller modules
Object-oriented decomposition
The system is decomposed into classes (“objects”)
Each class is a major abstraction in the application domain
Classes can be decomposed into smaller classes
1.Abstraction
2.Decomposition
3.Hierarchy
Which decomposition is the right one?
2. Decomposition
A technique used to master complexity (“divide and conquer”)
Functional decomposition
The system is decomposed into modules
Each module is a major processing step (function) in the
application domain
Modules can be decomposed into smaller modules
Object-oriented decomposition
The system is decomposed into classes (“objects”)
Each class is a major abstraction in the application domain
Classes can be decomposed into smaller classes
1.Abstraction
2.Decomposition
3.Hierarchy
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 21
Functional Decomposition
Top Level functions
Level 1 functions
Level 2 functions
Machine Instructions
System
Function
Load R10 Add R1, R10
Read Input Transform
Produce
Output
Transform
Produce
Output
Read Input
Is this about the requirements or a design?
Functional Decomposition
Top Level functions
Level 1 functions
Level 2 functions
Machine Instructions
System
Function
Load R10 Add R1, R10
Read Input Transform
Produce
Output
Transform
Produce
Output
Read Input
Is this about the requirements or a design?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 22
Functional Decomposition
Functionality is spread all over the system
Maintainer must understand the whole system to make a single
change to the system
Consequence:
Codes are hard to understand
Code that is complex and impossible to maintain
User interface is often awkward and non-intuitive
Example: Microsoft Powerpoint’s Autoshapes
Functional Decomposition
Functionality is spread all over the system
Maintainer must understand the whole system to make a single
change to the system
Consequence:
Codes are hard to understand
Code that is complex and impossible to maintain
User interface is often awkward and non-intuitive
Example: Microsoft Powerpoint’s Autoshapes
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 23
Autoshape
Functional Decomposition: Autoshape
Draw
Rectangle
Draw
Oval
Draw
Circle
DrawChange
Mouse
click
Change
Rectangle
Change
Oval
Change
Circle
How is this different from OO?
How are Functionally-Oriented systems different from OO systems?
Autoshape
Functional Decomposition: Autoshape
Draw
Rectangle
Draw
Oval
Draw
Circle
DrawChange
Mouse
click
Change
Rectangle
Change
Oval
Change
Circle
How is this different from OO?
How are Functionally-Oriented systems different from OO systems?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 24
OO-Decomposition - Class Identification
Class identification is crucial to object-oriented modeling
Basic assumption:
1.We can find the classes for a new software system: We call this
Greenfield Engineering
2.We can identify the classes in an existing system: We call this
Reengineering
3.We can create a class-based interface to any system: We call this
Interface Engineering
Why can we do this? Philosophy, science, experimental
evidence
What are the limitations? Depending on the purpose of the
system different objects might be found
How can we identify the purpose of a system?
Then, depending on the purpose, could a functional decomposition be better than an OO decomposition?
Which is UML for, functional- or OO-decomposition?
OO-Decomposition - Class Identification
Class identification is crucial to object-oriented modeling
Basic assumption:
1.We can find the classes for a new software system: We call this
Greenfield Engineering
2.We can identify the classes in an existing system: We call this
Reengineering
3.We can create a class-based interface to any system: We call this
Interface Engineering
Why can we do this? Philosophy, science, experimental
evidence
What are the limitations? Depending on the purpose of the
system different objects might be found
How can we identify the purpose of a system?
Then, depending on the purpose, could a functional decomposition be better than an OO decomposition?
Which is UML for, functional- or OO-decomposition?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 25
Model of an Eskimo
Eskimo
Size
Dress()
Smile()
Sleep()
Shoe
Size
Color
Type
Wear()
*
Coat
Size
Color
Type
Wear()
Is this a good model?
Model of an Eskimo
Eskimo
Size
Dress()
Smile()
Sleep()
Shoe
Size
Color
Type
Wear()
*
Coat
Size
Color
Type
Wear()
Is this a good model?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 26
Iterative Modeling then leads to ....
Eskimo
Size
Dress()
Smile()
Sleep()
Cave
Lighting
Enter()
Leave()
lives in
but is it the right model?
Entrance*
Outside
Temperature
Light
Season
Hunt()
Organize()
moves
around
Windhole
Diameter
MainEntrance
Size
Iterative Modeling then leads to ....
Eskimo
Size
Dress()
Smile()
Sleep()
Cave
Lighting
Enter()
Leave()
lives in
but is it the right model?
Entrance*
Outside
Temperature
Light
Season
Hunt()
Organize()
moves
around
Windhole
Diameter
MainEntrance
Size
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 27
Alternative Model: The Head of an Indian
Indian
Hair
Dress()
Smile()
Sleep()
Mouth
NrOfTeeths
Size
open()
speak()
*
Ear
Size
listen()
Face
Nose
smile()
close_eye()
Is this a good model?
Alternative Model: The Head of an Indian
Indian
Hair
Dress()
Smile()
Sleep()
Mouth
NrOfTeeths
Size
open()
speak()
*
Ear
Size
listen()
Face
Nose
smile()
close_eye()
Is this a good model?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 28
3. Hierarchy
2 important hierarchies
"Part of" hierarchy
"Is-kind-of" hierarchy
1.Abstraction
2.Decomposition
3.Hierarchy
3. Hierarchy
2 important hierarchies
"Part of" hierarchy
"Is-kind-of" hierarchy
1.Abstraction
2.Decomposition
3.Hierarchy
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 29
Part of Hierarchy
Computer
I/O Devices CPU Memory
Cache ALU Program
Counter
Part of Hierarchy
Computer
I/O Devices CPU Memory
Cache ALU Program
Counter
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 30
Is-Kind-of Hierarchy (Taxonomy)
Cell
Muscle Cell Blood Cell
Nerve Cell
Striate Smooth Red White Cortical Pyramidal
Any issue?
Is-Kind-of Hierarchy (Taxonomy)
Cell
Muscle Cell Blood Cell
Nerve Cell
Striate Smooth Red White Cortical Pyramidal
Any issue?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 31
So where are we right now?
Three ways to deal with complexity:
Abstraction
Decomposition
Hierarchy
Object-oriented decomposition is a good methodology
Unfortunately, depending on the purpose of the system, different
objects can be found
How can we do it right?
Many different possibilities
Our current approach: Start with a description of the functionality
(Use case model), then proceed to the object model
This leads us to the software lifecycle
*An old school of thought mixing the domain model with the solution model, being design-oriented, and in a Waterfall fashion.
So where are we right now?
Three ways to deal with complexity:
Abstraction
Decomposition
Hierarchy
Object-oriented decomposition is a good methodology
Unfortunately, depending on the purpose of the system, different
objects can be found
How can we do it right?
Many different possibilities
Our current approach: Start with a description of the functionality
(Use case model), then proceed to the object model
This leads us to the software lifecycle
*An old school of thought mixing the domain model with the solution model, being design-oriented, and in a Waterfall fashion.
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 32
Software Lifecycle Definition
Software lifecycle:
Set of activities and their relationships to each other to support the
development of a software system
Typical Lifecycle questions:
Which activities should I select for the software project?
What are the dependencies between activities?
How should I schedule the activities?
Software Lifecycle Definition
Software lifecycle:
Set of activities and their relationships to each other to support the
development of a software system
Typical Lifecycle questions:
Which activities should I select for the software project?
What are the dependencies between activities?
How should I schedule the activities?
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 33
Software Lifecycle Activities
Application
Domain
Objects
SubSystems
class...
class...
class...
Solution
Domain
Objects
Source
Code
Test
Cases
?
Expressed in
Terms Of
Structured By
Implemented
By
Realized By
Verified
By
System
Design
Object
Design
Implemen-
tation
Testing
class....?
Requirements
Elicitation
Use Case
Model
Requirements
Analysis
Each activity produces one or more models
Deliverable 1 Deliverable 2Deliverable 3Deliverable 4Deliverable 5Deliverable 6
Deliverable 0
Software Lifecycle Activities
Application
Domain
Objects
SubSystems
class...
class...
class...
Solution
Domain
Objects
Source
Code
Test
Cases
?
Expressed in
Terms Of
Structured By
Implemented
By
Realized By
Verified
By
System
Design
Object
Design
Implemen-
tation
Testing
class....?
Requirements
Elicitation
Use Case
Model
Requirements
Analysis
Each activity produces one or more models
Deliverable 1 Deliverable 2Deliverable 3Deliverable 4Deliverable 5Deliverable 6
Deliverable 0
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 34
Reusability: Design Patterns and Frameworks
Design Pattern:
A small set of classes that provide a template solution to a recurring
design problem
Reusable design knowledge on a higher level than data structures
(link lists, binary trees, etc)
Framework:
A moderately large set of classes that collaborate to carry out a set
of responsibilities in an application domain.
Examples: User Interface Builder
Provide architectural guidance during the design phase
Provide a foundation for software components industry
Reusability: Design Patterns and Frameworks
Design Pattern:
A small set of classes that provide a template solution to a recurring
design problem
Reusable design knowledge on a higher level than data structures
(link lists, binary trees, etc)
Framework:
A moderately large set of classes that collaborate to carry out a set
of responsibilities in an application domain.
Examples: User Interface Builder
Provide architectural guidance during the design phase
Provide a foundation for software components industry
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 35
Summary
Software engineering is a problem solving activity
Developing quality software for a complex problem within a limited
time while things are changing
There are many ways to deal with complexity
Modeling, decomposition, abstraction, hierarchy
Issue models: Show the negotiation aspects
System models: Show the technical aspects
Task models: Show the project management aspects
Use Patterns: Reduce complexity even further
Many ways to deal with change
Tailor the software lifecycle to deal with changing project conditions
Use a nonlinear software lifecycle to deal with changing
requirements or changing technology
Provide configuration management to deal with changing entities
Summary
Software engineering is a problem solving activity
Developing quality software for a complex problem within a limited
time while things are changing
There are many ways to deal with complexity
Modeling, decomposition, abstraction, hierarchy
Issue models: Show the negotiation aspects
System models: Show the technical aspects
Task models: Show the project management aspects
Use Patterns: Reduce complexity even further
Many ways to deal with change
Tailor the software lifecycle to deal with changing project conditions
Use a nonlinear software lifecycle to deal with changing
requirements or changing technology
Provide configuration management to deal with changing entities
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 36
Additional Slides
Additional Slides
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 37
Software Production has a Poor Track Record
Example: Space Shuttle Software
Cost: $10 Billion, millions of dollars more than planned
Time: 3 years late
Quality: First launch of Columbia was cancelled because of a
synchronization problem with the Shuttle's 5 onboard
computers.
Error was traced back to a change made 2 years earlier when a
programmer changed a delay factor in an interrupt handler from
50 to 80 milliseconds.
The likelihood of the error was small enough, that the error caused
no harm during thousands of hours of testing.
Substantial errors still exist.
Astronauts are supplied with a book of known software problems
"Program Notes and Waivers".
Take a look at the Standish Report (The “Chaos” Report)
Software Production has a Poor Track Record
Example: Space Shuttle Software
Cost: $10 Billion, millions of dollars more than planned
Time: 3 years late
Quality: First launch of Columbia was cancelled because of a
synchronization problem with the Shuttle's 5 onboard
computers.
Error was traced back to a change made 2 years earlier when a
programmer changed a delay factor in an interrupt handler from
50 to 80 milliseconds.
The likelihood of the error was small enough, that the error caused
no harm during thousands of hours of testing.
Substantial errors still exist.
Astronauts are supplied with a book of known software problems
"Program Notes and Waivers".
Take a look at the Standish Report (The “Chaos” Report)
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 38
Reusability
A good software design solves a specific problem but is general
enough to address future problems (for example, changing
requirements)
Experts do not solve every problem from first principles
They reuse solutions that have worked for them in the past
Goal for the software engineer:
Design the software to be reusable across application domains and
designs
How?
Use design patterns and frameworks whenever possible
Reusability
A good software design solves a specific problem but is general
enough to address future problems (for example, changing
requirements)
Experts do not solve every problem from first principles
They reuse solutions that have worked for them in the past
Goal for the software engineer:
Design the software to be reusable across application domains and
designs
How?
Use design patterns and frameworks whenever possible
Bernd Bruegge & Allen H. Dutoit Object-Oriented Software Engineering: Using UML, Patterns, and Java 39
Patterns are used by many people
Chess Master:
Openings
Middle games
End games
Writer
Tragically Flawed Hero
(Macbeth, Hamlet)
Romantic Novel
User Manual
Architect
Office Building
Commercial Building
Private Home
Software Engineer
Composite Pattern: A collection
of objects needs to be treated
like a single object
Adapter Pattern (Wrapper):
Interface to an existing system
Bridge Pattern: Interface to an
existing system, but allow it to
be extensible
Patterns are used by many people
Chess Master:
Openings
Middle games
End games
Writer
Tragically Flawed Hero
(Macbeth, Hamlet)
Romantic Novel
User Manual
Architect
Office Building
Commercial Building
Private Home
Software Engineer
Composite Pattern: A collection
of objects needs to be treated
like a single object
Adapter Pattern (Wrapper):
Interface to an existing system
Bridge Pattern: Interface to an
existing system, but allow it to
be extensible
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