1 / 35

Name lookup (name control)

Name lookup (name control). Variables Variable names are searched for in the below order. 1. Locally 2. Class-scope 3. File scope (global). Name lookup (name control). void fun(int x) { { int x = 5; cout << x << endl; } cout << x << endl; }.

natalie-lara
Download Presentation

Name lookup (name control)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Name lookup (name control) • Variables • Variable names are searched for in the below order. 1. Locally 2. Class-scope 3. File scope (global)

  2. Name lookup (name control) void fun(int x) { { int x = 5; cout << x << endl; } cout << x << endl; }

  3. Name lookup (name control) • Functions • Name to match a function is searched for in the below order. 1. Class-scope (if invoked from an operation belonging to a class) 2. File-scope

  4. Name lookup (name control) • Example class-scope void X::fun() { f(); } class X { //. . . void f(); // name match }; • The scope operator :: makes it possible to access the desired scope

  5. Name lookup (name control) • The search for a name match is always done before the access control. void f(){. . .} //global function class X : public B {. . .}; class B { //. . . private: void f(); // name match }; void X::fun(){ f(); }

  6. Class scope (name control) • Enumerations, shared data, and functions class Date { public: enum Weekday { MON, TUE, WED, THU, FRI, SAT, SUN }; static int days_per_month[12]; //shared data static bool is_leap(int); //shared function //. . . }

  7. Class scope (name control) • Declaration of an array with constant size in a class class Stack { //. . . private: static const int SIZE = 20; // new proposed feature, still an ERROR with most compilers static const int SIZE; // OK, but this still does not help array initialization enum { SIZE = 20 }; // This is the trick int array[SIZE]; } const int Stack :: SIZE = 20; //implementation //initialization

  8. Namespaces (name control) //Declarations namespace Vendor_A_Containers { template<class T> class List { . . . }; template<class T> class Queue { . . . }; . . . } //Implementation namespace Vendor_A_Containers { template<class T> T Queue<T>::remove() { . . . }; template<class T> int Queue<T>::length() const { . . . }; . . . }

  9. Namespaces (name control) • Using namespaces //Method 1 //exhaustive Vendor_A_Containers::Queue<Employee> q; //The programmer defines an alias. namespace Cont = Vendor_A_Containers; Cont::Queue<Employee> q; //BETTER!

  10. Namespaces (name control) Method nr 2 class Bank { using Vendor_A_Containers :: Queue; // . . . private: Queue<Customer> waitingQueue; . . . }; • A using declaration can be put into any scope

  11. Namespaces (name control) #include <stdlib.h> //deprecated • To provide backward compatibility with the C standard library, the <xxx.h> naming is still supported, although it is deprecated. • Use the newer <cxxx>, or <xxx> instead. #include <cstdlib> //OK • The <cxxx> is used for the old c-headers and the <xxx> is used for the c++-headers.

  12. An example //Namespace.h #ifndef _RS_NAMESPACE_ #define _RS_NAMESPACE_ namespace RS_namespace { template <class T> class List { template <class T> class Nod; public: typedef Nod<T> nod; typedef Nod* nod_ptr; List(); ~List(); void ListInsert(T); //. . . private: template <class T> class Nod { public: T data; Nod<T>* next; }; nod_ptr head; int size; }; } //end RS_namespace #endif

  13. //List.cpp #include "RS_namespace.h" namespace RS_namespace { //pre: none //post:a list object is created and initiated template <class T> List<T>::List() { size=0; //sätter storlek på listan till 0 head=NULL; } //pre: none //post:The list object is removed, and memory is returned template <class T> List<T>::~List() { while (!ListIsEmpty()) ListDelete(1); } //pre: none //post:An element is inserted as the first element of the list template <class T> void List<T>::ListInsert(T newdata) { size++; nod_ptr newptr=new Nod; newptr->data=newdata; newptr->next=head; //sätt alltid in först i listan head=newptr; } } //end namespace

  14. //main.cpp #include "RS_namespace.h" void main() { //using just List from RS_namespace using RS_namespace::List; //Induce the whole namespace ”RS_namespace” using namespace RS_namespace; List<int> myList; }

  15. Access control (name control) • Declarations and definitions • Example definitions int x; Employee lars("Lars"); int square(int x){ return x*x; } • Example declarations extern int x; extern Employee lars; int square(); class Date; enum Color;

  16. Access control (name control) • Public, private and protected • public • Access is allowed from all clients. • protected • Access is allowed from the class itself, subclasses and friends. • Private • Access is allowed from the class itself and friends.

  17. Access control (name control) • Friends - (use with care) • A class can declare a function or another class as a friend. This gives the declared friend(s) total access to the class members. class Link { friend class List; friend class Queue; private: Link() : _next=0 {}; int _info; Link* _next; }; • When is this useful?

  18. Access control • Friends (cont...) • The friend keyword is not only telling you that this function is a friend it is also implicitly telling you that it is not a member. • The friend keyword can only be used within a class-definition.

  19. Design issues for name control • Don’t pollute the global namespace with global variables. • Eliminate them by making them shared data members of a class. • Eliminate global functions by making them shared class functions. • Use a nested class to define a class that are implementation specific to the class that use it • Think carefully before taking a decision about making a function or class a friend. • Do not use protected data!

  20. Objects • An object is characterized by its: • State • Operations • Identity • What is a class? • What is object oriented programming?

  21. Memory handling • A C++ program can allocate memory in three memory areas: • The run time stack (Automatic storage) • Static storage • The heap memory, also called free storage or dynamic memory.

  22. Constructors (memory handling) • Every class has four special member functions: • The default constructor • The copy-constructor • The destructor • The assignment operator

  23. Generation of default cons. class File { private: string path; int mode; public: File(const string& file_path, int open_mode); ~File(); }; //error, array requires default //constructorFile File folder1[10]; // error, f2[1] still requires // default constructor File folder2[2] = { File("f1", 1)}; //OK, fully nitialized array folder3[3] = { File("f1", 1), File("f2",2), File("f3",3) };

  24. Explicit constructors class string { public: string(); //constructors and implicit //conversion operators string(int size); string(const char *); ~string(); private: int size; int capacity; char *buff; };

  25. Explicit constructors • What happens in the program below? int main() { string s = "hello"; //OK, convert a //C-string into a string object int ns = 0; s = 1; // 1 oops, programmer //intended to write ns = 1 }

  26. Explicit constructors • Solution class string { public: //block implicit conversion explicit string(int size); //implicit conversion string(const char *); ~string(); };

  27. Explicit constructors • Solution (cont..) int main() { string s = "hello"; //OK, convert a //C-string into a string object int ns = 0; s = 1; // compile time error, this //time the compiler catches //the typo }

  28. Initializing class members • There are four different cases to consider when initializing class members in the constructor. • Initialization of const members. • Initialization of alias (reference) members. • Initialization of base class members through a subclass, by sending arguments to the base class constructor. • Initialization of member objects. • In the three first cases an initializer list is mandatory. The fourth case is optional.

  29. Copy constructors • Why have one? • To copy objects who differ only in identity. • To copy arguments and return values to and from functions, using call-by-value. • When do you absolutely need to define one? • All classes with a non trivial destructor need both a user defined copy-constructor and a user defined assignment operator.

  30. Destructors • Why have a destructor? • To free resources. • When do I have to define it explicitly? • Whenever there is dynamic memory allocation involved. • Why have a virtual destructor? • Whenever the class is a potential base class.

  31. The assignment operator • Why have one? • To be able to control what happens when assignment takes place. • When do I need to define one? • All classes with a non trivial destructor need a user defined assignment operator. • Generic form C& C::operator=(const C&);

  32. The assignment operator • The assigment operator and the destructor. // What happens? List a: a.insert(. . .); //. . . List b; b.insert(. . .); //. . . a = b; // b goes out of scope

  33. The assignment operator Two problems: The list a is not removed. The list b is removed twice!

  34. Common factors ... • … between the destructor, the copy constructor and the assignment operator void List::copy(const List& b) { //kod för att kopiera } void List::free() { //kod för att frigöra minnet } List::List(const List& b) { copy(b); }

  35. Common factors . . . List::~List() { free(); } const List& List::operator=( const List& b ) { if( this != &b) { free(); copy(b); } return *this; }

More Related