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Storage Classes in C

Storage Classes in C

Last Updated : 11 Oct, 2024
 
 
 
 
 
 

C Storage Classes are used to describe the features of a variable/function. These features basically include the scope, visibility, and lifetime which help us to trace the existence of a particular variable during the runtime of a program.

C language uses 4 storage classes, namely:

storage classes in c

Storage classes in C define the scope and lifetime of variables. To better understand how storage classes interact with data structures, the C Programming Course Online with Data Structures provides practical examples of memory management and variable lifetimes.

1. auto

This is the default storage class for all the variables declared inside a function or a block. Hence, the keyword auto is rarely used while writing programs in C language. Auto variables can be only accessed within the block/function they have been declared and not outside them (which defines their scope). Of course, these can be accessed within nested blocks within the parent block/function in which the auto variable was declared.
However, accessing auto variables outside their scope using pointers to their exact memory location is unsafe and results in undefined behavior. Auto variables are also assigned a garbage value by default when they are declared.
Likewise, auto keyword is not used in front of functions as functions are not limited to block scope.

2. extern

Extern storage class simply tells us that the variable is defined elsewhere and not within the same block where it is used. Basically, the value is assigned to it in a different block and this can be overwritten/changed in a different block as well. So an extern variable is nothing but a global variable initialized with a legal value where it is declared in order to be used elsewhere. It can be accessed within any function/block.
Also, a normal global variable can be made extern as well by placing the ‘extern’ keyword before its declaration/definition in any function/block. This basically signifies that we are not initializing a new variable but instead, we are using/accessing the global variable only. The main purpose of using extern variables is that they can be accessed between two different files which are part of a large program.

3. static

This storage class is used to declare static variables which are popularly used while writing programs in C language. Static variables have the property of preserving their value even after they are out of their scope! Hence, static variables preserve the value of their last use in their scope. So we can say that they are initialized only once and exist till the termination of the program. Thus, no new memory is allocated because they are not re-declared.
Their scope is local to the function to which they were defined. Global static variables can be accessed anywhere in the program. By default, they are assigned the value 0 by the compiler. 

4. register

This storage class declares register variables that have the same functionality as that of the auto variables. The only difference is that the compiler tries to store these variables in the register of the microprocessor if a free register is available. This makes the use of register variables to be much faster than that of the variables stored in the memory during the runtime of the program.
If a free registration is not available, these are then stored in the memory only. Usually, a few variables which are to be accessed very frequently in a program are declared with the register keyword which improves the running time of the program. An important and interesting point to be noted here is that we cannot obtain the address of a register variable using pointers. 

Syntax

To specify the storage class for a variable, the following syntax is to be followed:

storage_class var_data_type var_name;

Example

Functions follow the same syntax as given above for variables. Have a look at the following C example for further clarification:

C
 // A C program to demonstrate different storage
// classes
#include <stdio.h>

// declaring the variable which is to be made extern
// an initial value can also be initialized to x
int x;

void autoStorageClass()
{

    printf("\nDemonstrating auto class\n\n");

    // declaring an auto variable (simply
    // writing "int a=32;" works as well)
    auto int a = 32;

    // printing the auto variable 'a'
    printf("Value of the variable 'a'"
           " declared as auto: %d\n",
           a);

    printf("--------------------------------");
}

void registerStorageClass()
{

    printf("\nDemonstrating register class\n\n");

    // declaring a register variable
    register char b = 'G';

    // printing the register variable 'b'
    printf("Value of the variable 'b'"
           " declared as register: %d\n",
           b);

    printf("--------------------------------");
}

void externStorageClass()
{

    printf("\nDemonstrating extern class\n\n");

    // telling the compiler that the variable
    // x is an extern variable and has been
    // defined elsewhere (above the main
    // function)
    extern int x;

    // printing the extern variables 'x'
    printf("Value of the variable 'x'"
           " declared as extern: %d\n",
           x);

    // value of extern variable x modified
    x = 2;

    // printing the modified values of
    // extern variables 'x'
    printf("Modified value of the variable 'x'"
           " declared as extern: %d\n",
           x);

    printf("--------------------------------");
}

void staticStorageClass()
{
    int i = 0;

    printf("\nDemonstrating static class\n\n");

    // using a static variable 'y'
    printf("Declaring 'y' as static inside the loop.\n"
           "But this declaration will occur only"
           " once as 'y' is static.\n"
           "If not, then every time the value of 'y' "
           "will be the declared value 5"
           " as in the case of variable 'p'\n");

    printf("\nLoop started:\n");

    for (i = 1; i < 5; i++) {

        // Declaring the static variable 'y'
        static int y = 5;

        // Declare a non-static variable 'p'
        int p = 10;

        // Incrementing the value of y and p by 1
        y++;
        p++;

        // printing value of y at each iteration
        printf("\nThe value of 'y', "
               "declared as static, in %d "
               "iteration is %d\n",
               i, y);

        // printing value of p at each iteration
        printf("The value of non-static variable 'p', "
               "in %d iteration is %d\n",
               i, p);
    }

    printf("\nLoop ended:\n");

    printf("--------------------------------");
}

int main()
{

    printf("A program to demonstrate"
           " Storage Classes in C\n\n");

    // To demonstrate auto Storage Class
    autoStorageClass();

    // To demonstrate register Storage Class
    registerStorageClass();

    // To demonstrate extern Storage Class
    externStorageClass();

    // To demonstrate static Storage Class
    staticStorageClass();

    // exiting
    printf("\n\nStorage Classes demonstrated");

    return 0;
}

// This code is improved by RishabhPrabhu


Output

A program to demonstrate Storage Classes in C


Demonstrating auto class

Value of the variable 'a' declared as auto: 32
--------------------------------
Demonstrating register class

Value of the variable 'b' declared as register: 71
--------------------------------
Demonstrating extern class

Value of the variable 'x' declared as extern: 0
Modified value of the variable 'x' declared as extern: 2
--------------------------------
Demonstrating static class

Declaring 'y' as static inside the loop.
But this declaration will occur only once as 'y' is static.
If not, then every time the value of 'y' will be the declared value 5 as in the case of variable 'p'

Loop started:

The value of 'y', declared as static, in 1 iteration is 6
The value of non-static variable 'p', in 1 iteration is 11

The value of 'y', declared as static, in 2 iteration is 7
The value of non-static variable 'p', in 2 iteration is 11

The value of 'y', declared as static, in 3 iteration is 8
The value of non-static variable 'p', in 3 iteration is 11

The value of 'y', declared as static, in 4 iteration is 9
The value of non-static variable 'p', in 4 iteration is 11

Loop ended:
--------------------------------

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