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====C++==== In the 1970s, [[software engineers]] needed language support to break large projects down into [[Modular programming|modules]].<ref name="cpl_3rd-ch2-38">{{cite book | last = Wilson | first = Leslie B. | title = Comparative Programming Languages, Third Edition | publisher = Addison-Wesley | year = 2001 | page = 38 | isbn = 0-201-71012-9 }}</ref> One obvious feature was to decompose large projects ''physically'' into separate [[computer file|files]]. A less obvious feature was to decompose large projects ''logically'' into [[abstract data type]]s.<ref name="cpl_3rd-ch2-38"/> At the time, languages supported [[Type system|concrete (scalar)]] datatypes like [[integer]] numbers, [[floating-point]] numbers, and [[String (computer science)|strings]] of [[Character (computing)|characters]]. Abstract datatypes are [[Record (computer science)|structures]] of concrete datatypes, with a new name assigned. For example, a [[List (abstract data type)|list]] of integers could be called <code>integer_list</code>. In object-oriented jargon, abstract datatypes are called [[Class (computer programming)|classes]]. However, a ''class'' is only a definition; no memory is allocated. When memory is allocated to a class and [[Name binding|bound]] to an [[identifier]], it is called an [[Object (computer science)|object]].<ref name="cpl_3rd-ch8-193">{{cite book | last = Wilson | first = Leslie B. | title = Comparative Programming Languages, Third Edition | publisher = Addison-Wesley | year = 2001 | page = 193 | isbn = 0-201-71012-9 }}</ref> [[Object-oriented programming|Object-oriented imperative languages]] developed by combining the need for classes and the need for safe [[functional programming]].<ref name="cpl_3rd-ch2-39">{{cite book | last = Wilson | first = Leslie B. | title = Comparative Programming Languages, Third Edition | publisher = Addison-Wesley | year = 2001 | page = 39 | isbn = 0-201-71012-9 }}</ref> A function, in an object-oriented language, is assigned to a class. An assigned function is then referred to as a [[Method (computer programming)|method]], [[member function]], or [[Operation (mathematics)|operation]]. ''Object-oriented programming'' is executing ''operations'' on ''objects''.<ref name="cpl_3rd-ch2-35">{{cite book | last = Wilson | first = Leslie B. | title = Comparative Programming Languages, Third Edition | publisher = Addison-Wesley | year = 2001 | page = 35 | isbn = 0-201-71012-9 }}</ref> ''Object-oriented languages'' support a syntax to model [[subset|subset/superset]] relationships. In [[set theory]], an [[Element (mathematics)|element]] of a subset inherits all the attributes contained in the superset. For example, a student is a person. Therefore, the set of students is a subset of the set of persons. As a result, students inherit all the attributes common to all persons. Additionally, students have unique attributes that other people do not have. ''Object-oriented languages'' model ''subset/superset'' relationships using [[Inheritance (object-oriented programming)|inheritance]].<ref name="cpl_3rd-ch8-192">{{cite book | last = Wilson | first = Leslie B. | title = Comparative Programming Languages, Third Edition | publisher = Addison-Wesley | year = 2001 | page = 192 | isbn = 0-201-71012-9 }}</ref> ''Object-oriented programming'' became the dominant language paradigm by the late 1990s.<ref name="cpl_3rd-ch2-38"/> [[C++]] (1985) was originally called "C with Classes".<ref name="stroustrup-notes-22">{{cite book | last = Stroustrup | first = Bjarne | title = The C++ Programming Language, Fourth Edition | publisher = Addison-Wesley | year = 2013 | page = 22 | isbn = 978-0-321-56384-2 }}</ref> It was designed to expand [[C (programming language)|C's]] capabilities by adding the object-oriented facilities of the language [[Simula]].<ref name="stroustrup-notes-21">{{cite book | last = Stroustrup | first = Bjarne | title = The C++ Programming Language, Fourth Edition | publisher = Addison-Wesley | year = 2013 | page = 21 | isbn = 978-0-321-56384-2 }}</ref> An object-oriented module is composed of two files. The definitions file is called the [[header file]]. Here is a C++ ''header file'' for the ''GRADE class'' in a simple school application: <syntaxhighlight lang="cpp"> // grade.h // ------- // Used to allow multiple source files to include // this header file without duplication errors. // ---------------------------------------------- #ifndef GRADE_H #define GRADE_H class GRADE { public: // This is the constructor operation. // ---------------------------------- GRADE ( const char letter ); // This is a class variable. // ------------------------- char letter; // This is a member operation. // --------------------------- int grade_numeric( const char letter ); // This is a class variable. // ------------------------- int numeric; }; #endif </syntaxhighlight> A [[Constructor (object-oriented programming)|constructor]] operation is a function with the same name as the class name.<ref name="stroustrup-ch2-49">{{cite book | last = Stroustrup | first = Bjarne | title = The C++ Programming Language, Fourth Edition | publisher = Addison-Wesley | year = 2013 | page = 49 | isbn = 978-0-321-56384-2 }}</ref> It is executed when the calling operation executes the <code>[[new and delete (C++)|new]]</code> statement. A module's other file is the [[source file]]. Here is a C++ source file for the ''GRADE class'' in a simple school application: <syntaxhighlight lang="cpp"> // grade.cpp // --------- #include "grade.h" GRADE::GRADE( const char letter ) { // Reference the object using the keyword 'this'. // ---------------------------------------------- this->letter = letter; // This is Temporal Cohesion // ------------------------- this->numeric = grade_numeric( letter ); } int GRADE::grade_numeric( const char letter ) { if ( ( letter == 'A' || letter == 'a' ) ) return 4; else if ( ( letter == 'B' || letter == 'b' ) ) return 3; else if ( ( letter == 'C' || letter == 'c' ) ) return 2; else if ( ( letter == 'D' || letter == 'd' ) ) return 1; else if ( ( letter == 'F' || letter == 'f' ) ) return 0; else return -1; } </syntaxhighlight> Here is a C++ ''header file'' for the ''PERSON class'' in a simple school application: <syntaxhighlight lang="cpp"> // person.h // -------- #ifndef PERSON_H #define PERSON_H class PERSON { public: PERSON ( const char *name ); const char *name; }; #endif </syntaxhighlight> Here is a C++ ''source file'' for the ''PERSON class'' in a simple school application: <syntaxhighlight lang="cpp"> // person.cpp // ---------- #include "person.h" PERSON::PERSON ( const char *name ) { this->name = name; } </syntaxhighlight> Here is a C++ ''header file'' for the ''STUDENT class'' in a simple school application: <syntaxhighlight lang="cpp"> // student.h // --------- #ifndef STUDENT_H #define STUDENT_H #include "person.h" #include "grade.h" // A STUDENT is a subset of PERSON. // -------------------------------- class STUDENT : public PERSON{ public: STUDENT ( const char *name ); GRADE *grade; }; #endif </syntaxhighlight> Here is a C++ ''source file'' for the ''STUDENT class'' in a simple school application: <syntaxhighlight lang="cpp"> // student.cpp // ----------- #include "student.h" #include "person.h" STUDENT::STUDENT ( const char *name ): // Execute the constructor of the PERSON superclass. // ------------------------------------------------- PERSON( name ) { // Nothing else to do. // ------------------- } </syntaxhighlight> Here is a driver program for demonstration: <syntaxhighlight lang="cpp"> // student_dvr.cpp // --------------- #include <iostream> #include "student.h" int main( void ) { STUDENT *student = new STUDENT( "The Student" ); student->grade = new GRADE( 'a' ); std::cout // Notice student inherits PERSON's name << student->name << ": Numeric grade = " << student->grade->numeric << "\n"; return 0; } </syntaxhighlight> Here is a [[makefile]] to compile everything: <syntaxhighlight lang="make"> # makefile # -------- all: student_dvr clean: rm student_dvr *.o student_dvr: student_dvr.cpp grade.o student.o person.o c++ student_dvr.cpp grade.o student.o person.o -o student_dvr grade.o: grade.cpp grade.h c++ -c grade.cpp student.o: student.cpp student.h c++ -c student.cpp person.o: person.cpp person.h c++ -c person.cpp </syntaxhighlight>
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