CSI3120A Fall 2023 Lecture 10-1 PDF

Summary

This document provides a lecture on abstract data types (ADTs) and encapsulation concepts, focusing on their importance in programming languages. The content discusses the essential features and principles of ADTs, illustrating them with examples in C++. The topics covered in the lecture notes encompass the concept of abstraction, introduction to data abstraction, and design issues for Abstract Data Types along with other related topics.

Full Transcript

Chapter 11 Abstract Data Types and Encapsulation Concepts ISBN 0-321-49362-1 Chapter 11 Topics • • • • • • • The Concept of Abstraction Introduction to Data Abstraction Design Issues for Abstract Data Types Language Examples Parameterized Abstract Data Types Encapsulation Constructs Naming Enca...

Chapter 11 Abstract Data Types and Encapsulation Concepts ISBN 0-321-49362-1 Chapter 11 Topics • • • • • • • The Concept of Abstraction Introduction to Data Abstraction Design Issues for Abstract Data Types Language Examples Parameterized Abstract Data Types Encapsulation Constructs Naming Encapsulations Copyright © 2018 Pearson. All rights reserved. 1-2 The Concept of Abstraction • An abstraction is a view or representation of an entity that includes only the most significant attributes • The concept of abstraction is fundamental in programming (and computer science) • Nearly all programming languages support process abstraction with subprograms • Nearly all programming languages designed since 1980 support data abstraction Copyright © 2018 Pearson. All rights reserved. 1-3 Introduction to Data Abstraction • An abstract data type is a user-defined data type that satisfies the following two conditions: – The representation of objects of the type is hidden from the program units that use these objects, so the only operations possible are those provided in the type's definition – The declarations of the type and the protocols of the operations on objects of the type are contained in a single syntactic unit. Other program units are allowed to create variables of the defined type. Copyright © 2018 Pearson. All rights reserved. 1-4 Advantages of Data Abstraction • Advantages the first condition – Reliability--by hiding the data representations, user code cannot directly access objects of the type or depend on the representation, allowing the representation to be changed without affecting user code – Reduces the range of code and variables of which the programmer must be aware – Name conflicts are less likely • Advantages of the second condition – Provides a method of program organization – Aids modifiability (everything associated with a data structure is together) – Separate compilation Copyright © 2018 Pearson. All rights reserved. 1-5 Language Requirements for ADTs • A syntactic unit in which to encapsulate the type definition • A method of making type names and subprogram headers visible to clients, while hiding actual definitions • Some primitive operations must be built into the language processor Copyright © 2018 Pearson. All rights reserved. 1-6 Design Issues • Can abstract types be parameterized? • What access controls are provided? • Is the specification of the type physically separate from its implementation? Copyright © 2018 Pearson. All rights reserved. 1-7 Language Examples: C++ • Based on C struct type and Simula 67 classes • The class is the encapsulation device • A class is a type • All of the class instances of a class share a single copy of the member functions • Each instance of a class has its own copy of the class data members • Instances can be static, stack dynamic, or heap dynamic Copyright © 2018 Pearson. All rights reserved. 1-8 Language Examples: C++ (continued) • Information Hiding – Private clause for hidden entities – Public clause for interface entities – Protected clause for inheritance (Chapter 12) Copyright © 2018 Pearson. All rights reserved. 1-9 Language Examples: C++ (continued) • Constructors: – Functions to initialize the data members of instances (they do not create the objects) – May also allocate storage if part of the object is heap-dynamic – Can include parameters to provide parameterization of the objects – Implicitly called when an instance is created – Can be explicitly called – Name is the same as the class name Copyright © 2018 Pearson. All rights reserved. 1-10 Language Examples: C++ (continued) • Destructors – Functions to cleanup after an instance is destroyed; usually just to reclaim heap storage – Implicitly called when the object’s lifetime ends – Can be explicitly called – Name is the class name, preceded by a tilde (~) Copyright © 2018 Pearson. All rights reserved. 1-11 An Example in C++ class Stack { private: int *stackPtr, maxLen, topPtr; public: Stack() { // a constructor stackPtr = new int [100]; maxLen = 99; topPtr = -1; }; ~Stack () {delete [] stackPtr;}; void push (int number) { if (topSub == maxLen) cerr << ″Error in push - stack is full\n″; else stackPtr[++topSub] = number; }; void pop () {…}; int top () {…}; int empty () {…}; } Copyright © 2018 Pearson. All rights reserved. 1-12 A Stack class header file // Stack.h - the header file for the Stack class #include <iostream.h> class Stack { private: //** These members are visible only to other //** members and friends (see Section 11.6.4) int *stackPtr; int maxLen; int topPtr; public: //** These members are visible to clients Stack(); //** A constructor ~Stack(); //** A destructor void push(int); void pop(); int top(); int empty(); } Copyright © 2018 Pearson. All rights reserved. 1-13 The code file for Stack // Stack.cpp - the implementation file for the Stack class #include <iostream.h> #include "Stack.h" using std::cout; Stack::Stack() { //** A constructor stackPtr = new int [100]; maxLen = 99; topPtr = -1; } Stack::~Stack() {delete [] stackPtr;}; //** A destructor void Stack::push(int number) { if (topPtr == maxLen) cerr << "Error in push--stack is full\n"; else stackPtr[++topPtr] = number; } ... Copyright © 2018 Pearson. All rights reserved. 1-14 Language Examples: C++ (continued) • Friend functions or classes - to provide access to private members to some unrelated units or functions – Necessary in C++ Copyright © 2018 Pearson. All rights reserved. 1-15 Language Examples: Java • Similar to C++, except: – All user-defined types are classes – All objects are allocated from the heap and accessed through reference variables – Individual entities in classes have access control modifiers (private or public), rather than clauses - Implicit garbage collection of all objects – Java has a second scoping mechanism, package scope, which can be used in place of friends • All entities in all classes in a package that do not have access control modifiers are visible throughout the package Copyright © 2018 Pearson. All rights reserved. 1-16 An Example in Java class StackClass { private: private int [] *stackRef; private int [] maxLen, topIndex; public StackClass() { // a constructor stackRef = new int [100]; maxLen = 99; topPtr = -1; }; public void push (int num) {…}; public void pop () {…}; public int top () {…}; public boolean empty () {…}; } Copyright © 2018 Pearson. All rights reserved. 1-17 Language Examples: C# • Based on C++ and Java • Adds two access modifiers, internal and protected internal • All class instances are heap dynamic • Default constructors are available for all classes • Garbage collection is used for most heap objects, so destructors are rarely used • structs are lightweight classes that do not support inheritance Copyright © 2018 Pearson. All rights reserved. 1-18 Language Examples: C# (continued) • Common solution to need for access to data members: accessor methods (getter and setter) • C# provides properties as a way of implementing getters and setters without requiring explicit method calls Copyright © 2018 Pearson. All rights reserved. 1-19 C# Property Example public class Weather { public int DegreeDays { //** DegreeDays is a property get {return degreeDays;} set { if (value < 0 || value > 30) Console.WriteLine( "Value is out of range: {0}", value); else degreeDays = value;} } private int degreeDays; ... } ... Weather w = new Weather(); int degreeDaysToday, oldDegreeDays; ... w.DegreeDays = degreeDaysToday; ... oldDegreeDays = w.DegreeDays; Copyright © 2018 Pearson. All rights reserved. 1-20 Abstract Data Types in Ruby • • • • • Encapsulation construct is the class Local variables have “normal” names Instance variable names begin with “at” signs (@) Class variable names begin with two “at” signs (@@) Instance methods have the syntax of Ruby functions (def … end) • Constructors are named initialize (only one per class)—implicitly called when new is called – If more constructors are needed, they must have different names and they must explicitly call new • Class members can be marked private or public, with public being the default • Classes are dynamic Copyright © 2018 Pearson. All rights reserved. 1-21 Abstract Data Types in Ruby (continued) class StackClass { def initialize @stackRef = Array.new @maxLen = 100 @topIndex = -1 end def push(number) if @topIndex == @maxLen puts " Error in push – stack is full" else @topIndex = @topIndex + 1 @stackRef[@topIndex] = number end end def pop … end def top … end def empty … end end Copyright © 2018 Pearson. All rights reserved. 1-22 Parameterized Abstract Data Types • Parameterized ADTs allow designing an ADT that can store any type elements – only an issue for static typed languages • Also known as generic classes • C++, Java 5.0, and C# 2005 provide support for parameterized ADTs Copyright © 2018 Pearson. All rights reserved. 1-23 Parameterized ADTs in C++ • Classes can be somewhat generic by writing parameterized constructor functions Stack (int size) { stk_ptr = new int [size]; max_len = size - 1; top = -1; }; A declaration of a stack object: Stack stk(150); Copyright © 2018 Pearson. All rights reserved. 1-24 Parameterized ADTs in C++ (continued) • The stack element type can be parameterized by making the class a templated class template <class Type> class Stack { private: Type *stackPtr; const int maxLen; int topPtr; public: Stack() { // Constructor for 100 elements stackPtr = new Type[100]; maxLen = 99; topPtr = -1; } Stack(int size) { // Constructor for a given number stackPtr = new Type[size]; maxLen = size – 1; topSub = -1; } ... } - Instantiation: Stack<int> myIntStack; Copyright © 2018 Pearson. All rights reserved. 1-25 Parameterized Classes in Java 5.0 • Generic parameters must be classes • Most common generic types are the collection types, such as LinkedList and ArrayList • Eliminate the need to cast objects that are removed • Eliminate the problem of having multiple types in a structure • Users can define generic classes • Generic collection classes cannot store primitives • Indexing is not supported • Example of the use of a predefined generic class: ArrayList <Integer> myArray = new ArrayList <Integer> (); myArray.add(0, 47); Copyright © 2018 Pearson. All rights reserved. // Put an element with subscript 0 in it 1-26 Parameterized Classes in Java 5.0 (continued) import java.util.*; public class Stack2<T> { private ArrayList<T> stackRef; private int maxLen; public Stack2)( { stackRef = new ArrayList<T> (); maxLen = 99; } public void push(T newValue) { if (stackRef.size() == maxLen) System.out.println(" Error in push – stack is full"); else stackRef.add(newValue); ... } - Instantiation: Stack2<string> myStack = new Stack2<string> (); Copyright © 2018 Pearson. All rights reserved. 1-27 Parameterized Classes in C# 2005 • Similar to those of Java 5.0, except no wildcard classes • Predefined for Array, List, Stack, Queue, and Dictionary • Elements of parameterized structures can be accessed through indexing Copyright © 2018 Pearson. All rights reserved. 1-28 Encapsulation Constructs • Large programs have two special needs: – Some means of organization, other than simply division into subprograms – Some means of partial compilation (compilation units that are smaller than the whole program) • Obvious solution: a grouping of subprograms that are logically related into a unit that can be separately compiled (compilation units) • Such collections are called encapsulation Copyright © 2018 Pearson. All rights reserved. 1-29 Nested Subprograms • Organizing programs by nesting subprogram definitions inside the logically larger subprograms that use them • Nested subprograms are supported in Python, JavaScript, and Ruby Copyright © 2018 Pearson. All rights reserved. 1-30 Encapsulation in C • Files containing one or more subprograms can be independently compiled • The interface is placed in a header file • Problem 1: the linker does not check types between a header and associated implementation • Problem 2: the inherent problems with pointers • #include preprocessor specification – used to include header files in applications Copyright © 2018 Pearson. All rights reserved. 1-31 Encapsulation in C++ • Can define header and code files, similar to those of C • Or, classes can be used for encapsulation – The class is used as the interface (prototypes) – The member definitions are defined in a separate file • Friends provide a way to grant access to private members of a class Copyright © 2018 Pearson. All rights reserved. 1-32 C# Assemblies • A collection of files that appears to application programs to be a single dynamic link library or executable • Each file contains a module that can be separately compiled • A DLL is a collection of classes and methods that are individually linked to an executing program • C# has an access modifier called internal; an internal member of a class is visible to all classes in the assembly in which it appears Copyright © 2018 Pearson. All rights reserved. 1-33 Naming Encapsulations • Large programs define many global names; need a way to divide into logical groupings • A naming encapsulation is used to create a new scope for names • C++ Namespaces – Can place each library in its own namespace and qualify names used outside with the namespace – C# also includes namespaces Copyright © 2018 Pearson. All rights reserved. 1-34 Naming Encapsulations (continued) • Java Packages – Packages can contain more than one class definition; classes in a package are partial friends – Clients of a package can use fully qualified name or use the import declaration Copyright © 2018 Pearson. All rights reserved. 1-35 Naming Encapsulations (continued) • Ruby Modules: - Ruby classes are name encapsulations, but Ruby also has modules - Typically encapsulate collections of constants and methods - Modules cannot be instantiated or subclassed, and they cannot define variables - Methods defined in a module must include the module’s name - Access to the contents of a module is requested with the require method Copyright © 2018 Pearson. All rights reserved. 1-36 Summary • The concept of ADTs and their use in program design was a milestone in the development of languages • Two primary features of ADTs are the packaging of data with their associated operations and information hiding • Ada provides packages that simulate ADTs • C++ data abstraction is provided by classes • Java’s data abstraction is similar to C++ • C++, Java 5.0, and C# 2005 support parameterized ADTs • C++, C#, Java, and Ruby provide naming encapsulations Copyright © 2018 Pearson. All rights reserved. 1-37

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