C++ Data Types


While writing program in any language, you need to use various variables to store various information. Variables are nothing but reserved memory locations to store values. This means that when you create a variable you reserve some space in memory.

You may like to store information of various data types like character, wide character, integer, floating point, double floating point, boolean etc. Based on the data type of a variable, the operating system allocates memory and decides what can be stored in the reserved memory.

Primitive Built-in Types

C++ offers the programmer a rich assortment of built-in as well as user defined data types. Following table lists down seven basic C++ data types −

Type Keyword
Boolean bool
Character char
Integer int
Floating point float
Double floating point double
Valueless void
Wide character wchar_t

Several of the basic types can be modified using one or more of these type modifiers −

  • signed
  • unsigned
  • short
  • long

The following table shows the variable type, how much memory it takes to store the value in memory, and what is maximum and minimum value which can be stored in such type of variables.

Type Typical Bit Width Typical Range
char 1byte -127 to 127 or 0 to 255
unsigned char 1byte 0 to 255
signed char 1byte -127 to 127
int 4bytes -2147483648 to 2147483647
unsigned int 4bytes 0 to 4294967295
signed int 4bytes -2147483648 to 2147483647
short int 2bytes -32768 to 32767
unsigned short int 2bytes 0 to 65,535
signed short int 2bytes -32768 to 32767
long int 8bytes -9223372036854775808 to 9223372036854775807
signed long int 8bytes same as long int
unsigned long int 8bytes 0 to 18446744073709551615
long long int 8bytes -(2^63) to (2^63)-1
unsigned long long int 8bytes 0 to 18,446,744,073,709,551,615
float 4bytes
double 8bytes
long double 12bytes
wchar_t 2 or 4 bytes 1 wide character

The size of variables might be different from those shown in the above table, depending on the compiler and the computer you are using.

Following is the example, which will produce correct size of various data types on your computer.

#include <iostream>
using namespace std;

int main() {
   cout << "Size of char : " << sizeof(char) << endl;
   cout << "Size of int : " << sizeof(int) << endl;
   cout << "Size of short int : " << sizeof(short int) << endl;
   cout << "Size of long int : " << sizeof(long int) << endl;
   cout << "Size of float : " << sizeof(float) << endl;
   cout << "Size of double : " << sizeof(double) << endl;
   cout << "Size of wchar_t : " << sizeof(wchar_t) << endl;
   
   return 0;
}

This example uses endl, which inserts a new-line character after every line and << operator is being used to pass multiple values out to the screen. We are also using sizeof() operator to get size of various data types.

When the above code is compiled and executed, it produces the following result which can vary from machine to machine −

Size of char : 1
Size of int : 4
Size of short int : 2
Size of long int : 4
Size of float : 4
Size of double : 8
Size of wchar_t : 4

Following is another example:

#include <iostream>
#include <limits>
using namespace std;

int main() {

    std::cout << "Int Min " << std::numeric_limits<int>::min() << endl;
    std::cout << "Int Max " << std::numeric_limits<int>::max() << endl;
    std::cout << "Unsigned Int  Min " << std::numeric_limits<unsigned int>::min() << endl;
    std::cout << "Unsigned Int Max " << std::numeric_limits<unsigned int>::max() << endl;
    std::cout << "Long Int Min " << std::numeric_limits<long int>::min() << endl;
    std::cout << "Long Int Max " << std::numeric_limits<long int>::max() << endl;

    std::cout << "Unsigned Long Int Min " << std::numeric_limits<unsigned  long int>::min() <<endl;
    std::cout << "Unsigned Long Int Max " << std::numeric_limits<unsigned  long int>::max() << endl;

}

typedef Declarations

You can create a new name for an existing type using typedef. Following is the simple syntax to define a new type using typedef −

typedef type newname; 

For example, the following tells the compiler that feet is another name for int −

typedef int feet;

Now, the following declaration is perfectly legal and creates an integer variable called distance −

feet distance;

Enumerated Types

An enumerated type declares an optional type name and a set of zero or more identifiers that can be used as values of the type. Each enumerator is a constant whose type is the enumeration.

Creating an enumeration requires the use of the keyword enum. The general form of an enumeration type is −

enum enum-name { list of names } var-list; 

Here, the enum-name is the enumeration's type name. The list of names is comma separated.

For example, the following code defines an enumeration of colors called colors and the variable c of type color. Finally, c is assigned the value "blue".

enum color { red, green, blue } c;
c = blue;

By default, the value of the first name is 0, the second name has the value 1, and the third has the value 2, and so on. But you can give a name, a specific value by adding an initializer. For example, in the following enumeration, green will have the value 5.

enum color { red, green = 5, blue };

Here, blue will have a value of 6 because each name will be one greater than the one that precedes it.

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