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---
language: c++
filename: learncpp.cpp
contributors:
- ["Steven Basart", "http://github.com/xksteven"]
lang: en
---
I am writing this to highlight the differences and
additions that C++ has with respect to C. My
suggestion would be to follow the C tutorial first
then look here for the additions and differences.
```c++
///////////////////////////////////////
// C++ differences
///////////////////////////////////////
//In C++
//cannot use void main()
int main() { //or int main(int argc, char **argv)
//cannot end with return;
return 0;
//Can also end without return statement
}
//In C++
/*
//This could lead to compiler errors and is discouraged
//#if 0 #endif pairs are encouraged instead
*/
//In C++
sizeof(10) //Typically 4
sizeof('c') == 1
//In C
sizeof('c') == sizeof(10) //true chars are passed as ints
//In C++ strict prototyping
void func(); //function which accepts no arguments
//In C
void func(); //function which may accept arguments
//In C++
for(int i = 0; i < 10; i++) {;}
//In C must int i must be declared before
//C++ Supports Function overloading
//Provided each function takes different
//parameters
void printing(char const *myString)
{printf("String %s\n",myString);} //Hello
void printing(int myInt)
{printf("My int is %d",myInt);} //15
int main ()
{
printing("Hello");
printing(15);
}
//C++ Default Function Arguments
void two_ints(int a = 1, int b = 4);
int main()
{
two_ints(); // arguments: 1, 4
two_ints(20); // arguments: 20, 4
two_ints(20, 5); // arguments: 20, 5
}
//C++ added the nullptr which is different from 0
int *ip = nullptr; // OK
int value = nullptr; // error: value is no pointer
///////////////////////////////////////
// C++ Additions ontop of C
///////////////////////////////////////
///////////////////////////////////////
// C++ Namespace
///////////////////////////////////////
//Namespaces allow you to define your own
//functions and variables for use
// Use '::' to change variable (or function) scope
// Putting '::' before a function or variable will
// reference a global scope
// This allows you to make normal c library calls
// std is for standard library
using namespace std;
#include <stdio.h>
int counter = 50; // global variable
int main()
{
for (int counter = 1; // this refers to the
counter < 2; // local variable
counter++)
{
printf("Global var %d local var %d\n",
::counter, // global variable
counter); // local variable
// => Global var 50 local var 1
}
}
// Namespaces can be nested
namespace myFirstNameSpace
{
namespace myInnerSoul
{
cos(int x)
{
printf("My inner soul was made to program.");
}
}
}
namespace anotherNameSpace
{
cos(int x) {;} //does nothing
}
int main()
{
//Specify the full path because main is outside of both namespaces.
//Will print out My inner soul was made to program.
myFirstNameSpace::myInnerSoul::cos(60);
}
///////////////////////////////////////
// C++ Strings
///////////////////////////////////////
//Strings in C++ are Objects and have many functions
myString = "Hello";
myOtherString = " World";
myString + myOtherString; // => "Hello World"
myString + ' You'; // => "Hello You"
myString != myOtherString; //True
//An example of a string method
myString.append(" Dog"); // => "Hello Dog"
///////////////////////////////////////
// C++ Input Output
///////////////////////////////////////
//C++ input and output streams
//cin, cout, cerr, << is insertion and >> is extraction operator
#include <iostream>
using namespace std;
int main()
{
int myInt;
//Prints to stdout (or terminal/screen)
cout << "Enter your fav number:\n";
//Takes in input
cin >> myInt;
//cout can also be formatted
cout << "Your fav number is " << myInt << "\n";
//Your fav number is ##
cerr << "Used for error messages";
}
///////////////////////////////////////
// C++ Classes
///////////////////////////////////////
//First example of classes
#include <iostream>
//define a class
class Doggie
{
std::string name;
int weight;
// These are only the declarations
//Can also have private and protected
public:
//The public methods (can also include variables)
// Default constructor
Doggie();
void setName(std::string dogsName);
void setWeight(int dogsWeight);
void printDog();
//Can define functions within class declaration too
void dogBark() {std::cout << "Bark Bark\n"}
//Destructors are methods that free the allocated space
~doggieDestructor();
//if no destructor compiler defines the trivial destructor
//Classes are similar to structs and must close the } with ;
};
// This is the implementation of the class methods
// Also called the definition
void Doggie::Doggie () {
std::cout << "A doggie is born. Woof!\n";
}
void Doggie::setName (std::string doggie_name) {
name = doggie_name;
}
void Doggie::setWeight (int doggie_weight) {
weight = doggie_weight;
}
void Doggie::printDog () {
std::cout << "Dog is " << name << " weighs" << weight << "\n";
}
void Doggie::~doggieDestructor () {
delete[] name;
delete weight;
}
int main () {
Doggie deedee; // prints out a doggie is born. Woof!
deedee.setName ("Barkley");
deedee.setWeight(1000000);
deedee.printDog;
//prints => Dog is Barkley weighs 1000000
return 0;
}
//C++ Class inheritance
class German_Sheperd : public Doggie
{
//This class now inherits everything public and protected from Doggie class
//Good practice to put d_ in front of datatypes in classes
std::string d_type;
public:
void dogType() {d_type = "German Sheperd";}
};
///////////////////////////////////////
// C++ Exception Handling
///////////////////////////////////////
try {
throw 12.25; // throws a double no handler declared
} catch (int errorNum)
{
std::cout << "I caught an int " << errorNum << "\n";
//default catcher
} catch (...)
{
std::cout << "I got an error. Not sure what but I can pass it up.";
throw;
}
///////////////////////////////////////
// C++ Operator Overloading
///////////////////////////////////////
// In C++ you can overload operators such as +, -, new, etc.
#include <iostream>
using namespace std;
class Vector {
public:
double x,y;
Vector () {};
Vector (double a, double b) : x(a), y(b) {}
Vector operator + (const CVector&);
Vector operator += (const CVector&);
};
Vector Vector::operator+ (const Vector& rhs)
{
Vector temp;
temp.x = x + rhs.x;
temp.y = y + rhs.y;
return temp;
}
Vector Vector::operator+= (const Vector& rhs)
{
x += rhs.x;
y += rhs.y;
return *this;
}
int main () {
Vector up (0,1);
Vector right (1,0);
Vector result;
// This calls the Vector + operator
// Vector up calls the + (function) with right as its paramater
result = up + right;
// prints out => Result is upright (1,1)
cout << "Result is upright (" << result.x << ',' << result.y << ")\n";
return 0;
}
```
Futher Reading
for more resources see: http://www.icce.rug.nl/documents/cplusplus/
for other reference material: http://www.cplusplus.com/doc/tutorial/
|