Objects First With Java: A Practical Introduction Using BlueJ, 3/e (Paperback) (Java物件導向程式設計:使用BlueJ的實用入門(第三版))
David J. Barnes, Michael Kolling
- 出版商: Prentice Hall
- 出版日期: 2006-06-15
- 定價: $1,020
- 售價: 6.0 折 $612
- 語言: 英文
- 頁數: 520
- 裝訂: Paperback
- ISBN: 013197629X
- ISBN-13: 9780131976290
-
相關分類:
Java 程式語言
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商品描述
Description
The book has a very clear identity.
It takes a truly objects first approach to teaching problem solving using Java. These are complicated concepts so the book uses the development environment BlueJ to help the student’s understanding. BlueJ has a strong emphasis on visualization and interaction techniques, and allows the students to manipulate objects and call methods as a first exercise. BlueJ is free and freely available, and has been developed specifically for teaching.
The book is loaded with projects so that the student can really get a grip on actually solving problems; and it takes a “spiral approach”, introducing a topic in a simple context early on, then revisiting it later in the book to deepen understanding. It also comes with a CD containing JDK, BlueJ, a BlueJ tutorial and code for all the projects. The website contains style guide for all examples, PowerPoints for lecturers and also a Solutions Manual.
Table of Contents
Foreword
Preface to the instructor
List of projects discussed in detail in this book
Acknowledgements
Part 1 Foundations of object orientation
Chapter 1 Objects and classes
1.1 Objects and classes
1.2 Creating objects
1.3 Calling methods
1.4 Parameters
1.5 Data types
1.6 Multiple instances
1.7 State
1.8 What is in an object?
1.9 Object interaction
1.10 Source code
1.11 Another example
1.12 Return values
1.13 Objects as parameters
1.14 Summary
Chapter 2 Understanding class definitions
2.1 Ticket machines
2.1.1 Exploring the behavior of a naïve ticket machine
2.2 Examining a class definition
2.3 Fields, constructors, and methods
2.3.1 Fields
2.3.2 Constructors
2.4 Passing data via parameters
2.5 Assignment
2.6 Accessor methods
2.7 Mutator methods
2.8 Printing from methods
2.9 Summary of the naïve ticket machine
2.10 Reflecting on the design of the ticket machine
2.11 Making choices: the conditional statement
2.12 A further conditional-statement example
2.13 Local variables
2.14 Fields, parameters, and local variables
2.15 Summary of the better ticket machine
2.16 Self-review exercises
2.17 Reviewing a familiar example
2.18 Summary
Chapter 3 Object interaction
3.1 The clock example
3.2 Abstraction and modularization
3.3 Abstraction in software
3.4 Modularization in the clock example
3.5 Implementing the clock display
3.6 Class diagrams versus object diagrams
3.7 Primitive types and object types
3.8 The ClockDisplay source code
3.8.1 Class NumberDisplay
3.8.2 String concatenation
3.8.3 The modulo operator
3.8.4 Class ClockDisplay
3.9 Objects creating objects
3.10 Multiple constructors
3.11 Method calls
3.11.1 Internal method calls
3.11.2 External method calls
3.11.3 Summary of the clock display
3.12 Another example of object interaction
3.12.1 The mail system example
3.12.2 The this keyword
3.13 Using a debugger
3.13.1 Setting breakpoints
3.13.2 Single stepping
3.13.3 Stepping into methods
3.14 Method calling revisited
3.15 Summary
Chapter 4 Grouping objects
4.1 Grouping objects in flexible-size collections
4.2 A personal notebook
4.3 A first look at library classes
4.3.1 An example of using a library
4.4 Object structures with collections
4.5 Generic classes
4.6 Numbering within collections
4.7 Removing an item from a collection
4.8 Processing a whole collection
4.8.1 The for-each loop
4.8.2 The while loop
4.8.3 Iterating over a collection
4.8.4 Index access versus iterators
4.9 Summary of the notebook example
4.10 Another example: an auction system
4.10.1 The Lot class
4.10.2 The Auction class
4.10.3 Anonymous objects
4.10.4 Using collections
4.11 Flexible collection summary
4.12 Fixed-size collections
4.12.1 A log-file analyzer
4.12.2 Declaring array variables
4.12.3 Creating array objects
4.12.4 Using array objects
4.12.5 Analyzing the log file
4.12.6 The for loop
4.13 Summary
Chapter 5 More sophisticated behavior
5.1 Documentation for library classes
5.2 The TechSupport system
5.2.1 Exploring the TechSupport system
5.2.2 Reading the code
5.3 Reading class documentation
5.3.1 Interfaces versus implementation
5.3.2 Using library-class methods
5.3.3 Checking string equality
5.4 Adding random behavior
5.4.1 The Random class
5.4.2 Random numbers with limited range
5.4.3 Generating random responses
5.4.4 Reading documentation for parameterized classes
5.5 Packages and import
5.6 Using maps for associations
5.6.1 The concept of a map
5.6.2 Using a HashMap
5.6.3 Using a map for the TechSupport system
5.7 Using sets
5.8 Dividing strings
5.9 Finishing the TechSupport system
5.10 Writing class documentation
5.10.1 Using javadoc in BlueJ
5.10.2 Elements of class documentation
5.11 Public versus private
5.11.1 Information hiding
5.11.2 Private methods and public fields
5.12 Learning about classes from their interfaces
5.13 Class variables and constants
5.13.1 The static key word
5.13.2 Constants
5.14 Summary
Chapter 6 Well-behaved objects
6.1 Introduction
6.2 Testing and debugging
6.3 Unit testing within BlueJ
6.3.1 Using inspectors
6.3.2 Positive versus negative testing
6.4 Test automation
6.4.1 Regression testing
6.4.2 Automated checking of test results
6.4.3 Recording a test
6.4.4 Fixtures
6.5 Modularization and interfaces
6.6 A debugging scenario
6.7 Commenting and style
6.8 Manual walkthroughs
6.8.1 A high-level walkthrough
6.8.2 Checking state with a walkthrough
6.8.3 Verbal walkthroughs
6.9 Print statements
6.9.1 Turning debugging information on or off
6.10 Choosing a test strategy
6.11 Debuggers
6.12 Putting the techniques into practice
6.13 Summary
Chapter 7 Designing classes
7.1 Introduction
7.2 The world-of-zuul game example
7.3 Introduction to coupling and cohesion
7.4 Code duplication
7.5 Making extensions
7.5.1 The task
7.5.2 Finding the relevant source code
7.6 Coupling
7.6.1 Using encapsulation to reduce coupling
7.7 Responsibility-driven design
7.7.1 Responsibilities and coupling
7.8 Localizing change
7.9 Implicit coupling
7.10 Thinking ahead
7.11 Cohesion
7.11.1 Cohesion of methods
7.11.2 Cohesion of classes
7.11.3 Cohesion for readability
7.11.4 Cohesion for reuse
7.12 Refactoring
7.12.1 Refactoring and testing
7.12.2 An example of refactoring
7.13 Refactoring for language independence
7.13.1 Enumerated types
7.13.2 Further decoupling of the command interface
7.14 Design guidelines
7.15 Executing without BlueJ
7.15.1 Class methods
7.15.2 The main method
7.15.3 Limitations of class methods
7.16 Summary
Part 2 Application structures
Chapter 8 Improving structure with inheritance
8.1 The DoME example
8.1.1 DoME classes and objects
8.1.2 DoME source code
8.1.3 Discussion of the DoME application
8.2 Using inheritance
8.3 Inheritance hierarchies
8.4 Inheritance in Java
8.4.1 Inheritance and access rights
8.4.2 Inheritance and initialization
8.5 DoME: adding other item types
8.6 Advantages of inheritance (so far)
8.7 Subtyping
8.7.1 Subclasses and subtypes
8.7.2 Subtyping and assignment
8.7.3 Subtyping and parameter passing
8.7.4 Polymorphic variables
8.7.5 Casting
8.8 The Object class
8.9 Autoboxing and Wrapper classes
8.10 The collection hierarchy
8.11 Summary
Chapter 9 More about inheritance
9.1 The problem: DoME’s print method
9.2 Static type and dynamic type
9.2.1 Calling print from Database
9.3 Overriding
9.4 Dynamic method lookup
9.5 Super call in methods
9.6 Method polymorphism
9.7 Object methods: toString
9.8 Protected access
9.9 Another example of inheritance with overriding
9.10 Summary
Chapter 10 Further abstraction techniques
10.1 Simulations
10.2 The foxes-and-rabbits simulation
10.2.1 The foxes-and-rabbits project
10.2.2 The Rabbit class
10.2.3 The Fox class
10.2.4 The Simulator class: setup
10.2.5 The Simulator class: a simulation step
10.2.6 Taking steps to improve the simulation
10.3 Abstract classes
10.3.1 The Animal superclass
10.3.2 Abstract methods
10.3.3 Abstract classes
10.4 More abstract methods
10.5 Multiple inheritance
10.5.1 An Actor class
10.5.2 Flexibility through abstraction
10.5.3 Selective drawing
10.5.4 Drawable actors: multiple inheritance
10.6 Interfaces
10.6.1 An Actor interface
10.6.2 Multiple inheritance of interfaces
10.6.3 Interfaces as types
10.6.4 Interfaces as specifications
10.6.5 A further example of interfaces
10.6.6 Abstract class or interface?
10.7 Summary of inheritance
10.8 Summary
Chapter 11 Building graphical user interfaces
11.1 Introduction
11.2 Components, layout, and event handling
11.3 AWT and Swing
11.4 The ImageViewer example
11.4.1 First experiments: creating a frame
11.4.2 Adding simple components
11.4.3 Adding menus
11.4.4 Event handling
11.4.5 Centralized receipt of events
11.4.6 Inner classes
11.4.7 Anonymous inner classes
11.5 ImageViewer 1.0: the first complete version
11.5.1 Image-processing classes
11.5.2 Adding the image
11.5.3 Layout
11.5.4 Nested containers
11.5.5 Image filters
11.5.6 Dialogs
11.6 ImageViewer 2.0: improving program structure
11.7 ImageViewer 3.0: more interface components
11.7.1 Buttons
11.7.2 Borders
11.8 Further extensions
11.9 Another example: SoundPlayer338
11.10 Summary
Chapter 12 Handling errors
12.1 The address-book project
12.2 Defensive programming
12.2.1 Client–server interaction
12.2.2 Argument checking
12.3 Server error reporting
12.3.1 Notifying the user
12.3.2 Notifying the client object
12.4 Exception-throwing principles
12.4.1 Throwing an exception
12.4.2 Exception classes
12.4.3 The effect of an exception
12.4.4 Unchecked exceptions
12.4.5 Preventing object creation
12.5 Exception handling
12.5.1 Checked exceptions: the throws clause
12.5.2 Catching exceptions: the try statement
12.5.3 Throwing and catching multiple exceptions
12.5.4 Propagating an exception
12.5.5 The finally clause
12.6 Defining new exception classes
12.7 Using assertions
12.7.1 Internal consistency checks
12.7.2 The assert statement
12.7.3 Guidelines for using assertions
12.7.4 Assertions and the BlueJ unit testing framework
12.8 Error recovery and avoidance
12.8.1 Error recovery
12.8.2 Error avoidance
12.9 Case study: text input/output
12.9.1 Readers, writers, and streams
12.9.2 The address-book-io project
12.9.3 Text output with FileWriter
12.9.4 Text input with FileReader
12.9.5 Scanner: reading input from the terminal
12.9.6 Object serialization
12.10 Summary
Chapter 13 Designing applications
13.1 Analysis and design
13.1.1 The verb/noun method
13.1.2 The cinema booking example
13.1.3 Discovering classes
13.1.4 Using CRC cards
13.1.5 Scenarios
13.2 Class design
13.2.1 Designing class interfaces
13.2.2 User interface design
13.3 Documentation
13.4 Cooperation
13.5 Prototyping
13.6 Software growth
13.6.1 Waterfall model
13.6.2 Iterative development
13.7 Using design patterns
13.7.1 Structure of a pattern
13.7.2 Decorator
13.7.3 Singleton
13.7.4 Factory method
13.7.5 Observer
13.7.6 Pattern summary
13.8 Summary
Chapter 14 A case study
14.1 The case study
14.1.1 The problem description
14.2 Analysis and design
14.2.1 Discovering classes
14.2.2 Using CRC cards
14.2.3 Scenarios
14.3 Class design
14.3.1 Designing class interfaces
14.3.2 Collaborators
14.3.3 The outline implementation
14.3.4 Testing
14.3.5 Some remaining issues
14.4 Iterative development
14.4.1 Development steps
14.4.2 A first stage
14.4.3 Testing the first stage
14.4.4 A later stage of development
14.4.5 Further ideas for development
14.4.6 Reuse
14.5 Another example
14.6 Taking things further
Appendices
A Working with a BlueJ project
B Java data types
C Java control structures
D Operators
E Running Java without BlueJ
F Configuring BlueJ
G Using the debugger
H JUnit unit-testing tools
I Javadoc
J Program style guide
K Important library classes
Index
商品描述(中文翻譯)
這本書具有非常明確的特色。它採用了真正以物件為先的方式來教授使用Java解決問題的方法。這些概念相當複雜,因此本書使用開發環境BlueJ來幫助學生理解。BlueJ強調可視化和互動技術,讓學生可以首先操作物件和呼叫方法。BlueJ是免費且可自由使用的,並且專為教學而開發。
這本書充滿了各種專案,讓學生真正掌握解決問題的能力;並且採用了「螺旋式教學法」,在書的早期以簡單的情境介紹一個主題,然後在書的後期重新討論以加深理解。書附帶一張光碟,其中包含JDK、BlueJ、BlueJ教程以及所有專案的程式碼。網站上還提供了所有範例的樣式指南、講師用的PowerPoints以及解答手冊。
目錄:
前言
給教師的前言
本書詳細討論的專案列表
致謝
第一部分 物件導向的基礎
第一章 物件和類別
1.1 物件和類別
1.2 創建物件
1.3 呼叫方法
1.4 參數
1.5 資料型別
1.6 多個實例
1.7 狀態
1.8 物件的內容
1.9 物件互動
1.10 原始碼
1.11 另一個範例
1.12 回傳值
1.13 物件作為參數
1.14 總結
第二章 理解類別定義
2.1 售票機
2.1.1 探索一個單純的售票機的行為
2.2 檢視類別定義
2.3 欄位、建構子和方法
2.3.1 欄位
2.3.2 建構子
2.4 透過參數傳遞資料
2.5 指派
2.6 存取方法
2.7 修改方法
2.8 從方法中列印
2.9 單純的售票機總結
2.10 反思售票機的設計
2.11 做出選擇:條件陳述式
2.12 進一步的條件陳述式範例
2.13 區域變數
2.14 欄位、參數和區域變數
2.15 更好的售票機總結
2.16 自我檢討練習
2.17 回顧一個熟悉的範例
2.18 總結
第三章 物件互動
3.1 時鐘範例
3.2 抽象和模組化
3.3 軟體中的抽象
3.4 時鐘範例中的模組化
3.5 實作時鐘顯示
3.6 類別圖與物件圖
3.7 原始型別和物件型別
3.8 時鐘顯示的原始碼
3.8.1 類別NumberDisplay
3.8.2 字串串接
3.8.3 取餘數運算子
3.8.4 類別ClockDisplay
3.9 物件創建物件
3.10 多個建構子
3.11 方法呼叫
3.11.1 內部方法呼叫
3.11.2 外部方法呼叫
3.11.3 時鐘顯示總結