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Welcome to OBJECT ORIENTED PROGRAMMING

Welcome to OBJECT ORIENTED PROGRAMMING. Prepared By : Nishant Tiwari PGT(CS) JNV,Padmi,Mandla. INTRODUCTION. Structured programming was most common way to organize a program.

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Welcome to OBJECT ORIENTED PROGRAMMING

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  1. Welcome to OBJECT ORIENTED PROGRAMMING Prepared By : NishantTiwari PGT(CS) JNV,Padmi,Mandla

  2. INTRODUCTION • Structured programming was most common way to organize a program. • A programming paradigm defines the methodology of designing and implementing program using the key features and building blocks of a programming language

  3. PROCEDURAL PROGRAMMING • Lays more emphasis on procedure than data • Separates the function and data manipulated by them • Whenever the definition of a type changes, the functions referring to this type must also be changed to reflect the change

  4. PROCEDURAL PROGRAMMING • The change in the design must also be modified to copy with the change in structure that shows procedural programming is susceptible to design changes • As design changes lead to many modification in the code this lead to increased time and cost overheads at times

  5. OBJECT BASED PROGRAMMING • In object based programming data and its associated meaningful function are enclosed in one single entity a class • Class are allowed to access its interface (how the uses views) but cannot access its implementation details (how the process is actually taking place)

  6. OBJECT BASED PROGRAMMING • Whenever any change in the definition of type user’s interface remains unaffected generally • The user cannot access the data of the class directly which is possible in procedural programming the change is localized to the definition of the change function

  7. OBJECT BASED PROGRAMMING • Subset of object oriented programming • Implement some feature of OOP like information hiding, abstraction, classes, function overloading but not implement inheritance and polymorphism

  8. OBJECT BASED PROGRAMMING • Advantages : • overcome most shortcoming of procedural programming • it localizes the changes and hide implementation details from user • It support user defined types • Implement information hiding and abstraction

  9. OBJECT BASED PROGRAMMING • Limitation • One major limitation is ability to represent real world relationships that exist among object for example both car and truck are vehicles this cannot be represented in OBP as it not support inheritance

  10. OBJECT ORIENTED PROGRAMMING • Superset of OBP • All the features of OBP and overcome its limitation by implementing inheritance so that real world relation among object can be represented programmatically

  11. OBJECT ORIENTED PROGRAMMING • OOP Concepts are data abstraction, data hiding, data encapsulation, classes, objects, inheritance and polymorphism. • Implementing OOP Concepts in C++ • Approach for writing software in which data and behavior are packed together • An abstraction is a named collection of attributes and behavior relevant to modeling a given entity

  12. OBJECT ORIENTED PROGRAMMING • A class is a named software representation for an abstraction • An object is a distinct instance of a class • Software code in OOPs is written to define classes, objects and manipulate these object

  13. Implementing objects • Real World objects have physical characteristics (state) and behavior e.g., motorbike Characteristics – current gear, two wheel etc Behavior – braking, accelerating etc Their state is maintained through variables or data items Their behaviour is implemented through function generally called methods

  14. Mapping an Abstraction into software attributes entity behaviour

  15. Implementing Data hiding, Data Abstraction and Encapsulation • Encapsulation is wrapping up of characteristics and behaviour into one unit • A class bind together data and its associated functions under one unit thereby enforcing encapsulation • Abstraction means representation of essential features without including the background details or explanation

  16. Implementing Encapsulation • Anything that an object does not know or cannot do is excluded from the object • Encapsulation is used to hide unimportant implementation details from the objects • Packing an object’s variables within the protective custody of its methods is encapsulation and this task is accomplished through classes

  17. General structure of a class {data,data,….} {method,method,…} Private Protected Public

  18. A Class is define as Class <class name> { private: // hidden members/methods protected: //unimportant implementation details public : // exposed important details };

  19. Implementing Inheritance • Inheritance is implement in C++ specifying the name of the (base) class from which the class being defined (the derived class) has to inherit from it. Class <derived class name>:<base class name> { derived class own features }

  20. Abstract class and Concrete class • Which defines an interface but does not provide implementation for all its member function • An abstract class is meant to be used as the base class from which other classes are derived • The derived class is expected to provide implementations for the member functions that are not implemented in the base class • A derived class that implements all the missing functionality is called a concrete class • A concrete class drives from abstract class

  21. Abstract class and Concrete class Example Concrete class Circle class Abstract class Shape Concrete class Recantagle class Concrete class Triangle class

  22. Implementing polymorphism • Polymorphism is the attribute that allows one interface to be used with different situation • C++ implement polymorphism through virtual functions, overloaded functions and overloaded operators. • A virtual function is used to specify the interface in abstract class but its implementation details are made available in concrete class (es) • Overloading means a name having two or more distinct meaning

  23. Function Overloading • A function with same name having several definitions that are differentiable by the number or types of their arguments is known as overloaded function and this process is known as function overloading • Example float sum (int a, int b); float sum (float x,float y);

  24. Function Overloading • Function overloading not only implement polymorphism but also reduce number of comparison in a program Pop(int) Push(int) Push(float) Pop(float)

  25. Declaration and Definition • A function argument list is known as function’s signature Example void squar (int a, float b); //function 1 Void squar (int x, float y);// same signature as function 1

  26. Declaration and Definition • Different signatures void prnsqr ( int i); void prnsqr ( char c); void prnsqr ( float f); void prnsqr ( double d);

  27. Declaration and Definition • When a function name is declare more than once in a program the compiler will interpret the second (and subsequent) declaration (s) as follows : 1) If the signatures of subsequent functions match the previous function’s then the second is treated as a re-declaration of the first 2) If the signature of the two functions match exactly but the return type differ,the second declaration is treated as an erroneous re-declaration of the first and is flagged at compile ttime as an error for example; flaot square (float f); double square (float x); // error

  28. Declaration and Definition • Function with same name and same signature but different return type are not allowed in C++ • You can have different return types, but only if the signature are also different: float square (float f);// different signature double square (double d); // allowed • If the signature of the function differ in either the number or type of their arguments, the two function are considered to be overloaded

  29. Questions OOP • Q1 write briefly about different programming paradigms ? • Q2 Discuss major OOP concepts briefly? • Q3 what is the signifance of private, protected public specifiers in a class? • Q4 Discuss the relation between abstract and concrete classes ? • Q5 How polymorphism implemented in c++ ? • Q6 How does the complier interpret more than one definitions having same name ? What steps does it follow to distinguish these ?

  30. Questions OOP • Q7 what will be the output of following program? #include<iostream.h> Int area (int s) { Return (s*s); } Float area (int b,int h) { Return (o.5 * b* h); } Int main ( ) { Cout <<area(5)<<endl; Cout<<area(4,3)<<endl; Cout<<area(6,area(3))<<endl; Return 0; }

  31. 0rganization of data and functions in OOP object object data data function function data function

  32. Structural of procedural programming Main function Function Function Function Function function Function Function Function

  33. Restrictions on Overloaded Functions • Any two functions in a set of overloaded functions must have different argument list • Overloading functions with argument lists of the same types, based on return type alone is an error • Member function cannot be overloaded soley on the basis of one being static and other non static • Typedef declarations do not define new types: they introduce synonyms for existing types,they do not affect the overloading mechanism

  34. Restrictions on Overloaded Functions • Example typedef char * PSTR void Print(char *szToPrint); void Print(PSTR szToPrint); The preceding two function have identical lists. PSTR is synonym for char*.

  35. Calling overloaded functions • A function call first matches the prototypes available with number and type of arguments provided with the function call and then call the appropriate function for execution

  36. Step involved in Finding the best match • A match: A match is found for the function call • No match: No match is found for a function call • Ambiguous match: More than one defined match for the function call

  37. Step involved in Finding the best match • Search for exact match :if the type of the actual argument exactly matches the type of one defined instance • A match through promotion : if no exact match is found an attempt is made to achieve a match through of the actual argument • A match through application of standard C++ conversion rules : if no match or through a promotion is found an attempt is made to achieve a match through a standard conversion of the actual argument

  38. Step involved in Finding the best match • A match through application of a user-defined conversion: if all the above mentioned step fail, then the compiler will try the user-defined conversions in combination with integral promotions and built-in conversion to find a unique match

  39. Advantages of OOP Re-use of code : linking of code to objects and explicit specification of relations between objects allows related objects to share code Ease of comprehension: the classes can be set up to closely represent the generic application concepts and process Ease of fabrication and maintenance : the concepts such as encapsulation, data abstraction allow for very clear designs when an object is going into disallowed states, which are not permitted only its methods needs to investigated Easy redesign and extension : the same concepts facilitate easy redesign and extension

  40. Thank You !!!

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