20. 1. Write a program in C to display the
first 10 natural numbers.
21. 2. Write a C program to find the sum
of first 10 natural numbers
22. 3. Write a program in C to display the cube
of the number up to given an integer
23. 4. Write a program in C to display the
multiplication table of a given integer.
24. 5. Write a C program to calculate the
factorial of a given number
25. 6. Display the sum of the series [ 9 +
99 + 999 + 9999 ...]
26. 7. Write a program in C to display the n terms of
square natural number and their sum.
27.
28. 8. Write a c program to check whether a
given number is a perfect number or not.
29. • Write a program in C to display the n terms of
odd natural number and their sum.
• Write a program in C to display the n terms of
even natural number and their sum.
• Write a C program to determine whether a
given number is prime or not.
• To find sum of numbers from m to n.
30. • To count number of digits in a number.
• To find whether a number is Armstrong number
or not.
• To find reverse of a number.
• To find whether a number is palindrome or not.
• To find decimal equivalent of a Binary number.
• To find Binary equivalent of a decimal number.
• To print various patterns.
32. • It defines the scope(visibility) and a lifetime of
variables and/or functions within a program.
1. Scope: where the value of the variable would
be available inside a program.
2. default initial value: if we do not explicitly
initialize that variable, what will be its default
initial value.
3. lifetime of that variable: for how long will
that variable exist.
33. • The following storage classes are most often
used in C programming:
1. Automatic variables
2. External variables
3. Static variables
4. Register variables
34. 1. Automatic variables: ”auto”
• Scope: Variable defined with auto storage class are
local to the function block inside which they are
defined.
• Default Initial Value: Any random value i.e garbage
value.
• Lifetime: Till the end of the function/method block
where the variable is defined.
• by default an automatic variable.
• Automatic variables can also be called local variables
because they are local to a function.
35.
36. 2. Register Storage Class: “register”
• Scope: Local to the function in which it is declared.
• Default initial value: garbage value
• Lifetime: Till the end of function block.
• Same as auto except, Store the variable in CPU
register instead of memory. We should
use register storage class only for those variables that
are used in our program very often. CPU registers are
limited and thus should be used carefully.
• Syntax : register int number;
37. 3. External or Global variable: “extern”
• Scope: Global (everywhere in the program).
• Default initial value: 0(zero).
• Lifetime: Till the program doesn't finish its execution,
you can access global variables.
• These variables are not bound by any function, they
are available everywhere.
• variables, which are not needed till the end of the
program, will still occupy the memory and thus,
memory will be wasted.
• The extern modifier is most commonly used when
there are two or more files sharing the same global
variables or functions.
38.
39.
40. 4. Static variables: “static”
• Scope: Local to the block in which the variable
is defined
• Default initial value: 0(Zero).
• Lifetime: Till the whole program doesn't finish
its execution.
• We should use static storage class only when
we want the value of the variable to remain
same every time we call it using different
function calls
41.
42.
43.
44. A function is a set of statements that take inputs, do
some specific computation and produces output.
• The idea is to put some commonly or repeatedly done
task together and make a function, so that instead of
writing the same code again and again for different
inputs, we can call the function.
• Each function perform some specific task.
45. • Every C program has at least one function
main(). Execution of a program starts from
main().
• A function can also be referred as a method or
sub-routine or procedure etc.
• A function divides complex problem into small
components, makes program easy to
understand and use.
46. Function Declaration
• Function declaration tells compiler about -
1. number of parameters function takes,
2. data-types of parameters and
3. return type of function.
• Putting parameter names in function declaration is
optional in function declaration, but it is necessary to
put them in definition.
47. Function Definition
• Actual code of the function, which does some
specific task.
• Function definition contains function header
and function body.
48. #include <stdio.h>
#include <conio.h>
int max(int x, int y) //function declaration with definition
{ if (x > y)
return x;
else
return y;
}
int main() // main function with “int” return type
{ int m, a = 10, b = 20;
// Calling above function to find max of 'a' and 'b'
m = max(a, b);
printf("m is %d", m);
return 0;
49. #include <stdio.h>
#include <conio.h>
int max(int , int ); //function declaration
int main() // main function with “int” return type
{ int m, a = 10, b = 20;
// Calling above function to find max of 'a' and 'b'
m = max(a, b);
printf("m is %d", m);
return 0;
}
int max(int x , int y) //function definition
{ if (x > y)
return x;
else
return y;
}
50. Return Statement
• It terminates the execution of a function and
returns a value to the calling function.
• Program control is transferred to the calling
function after return statement.
51. • It is always recommended to declare a function before
it is used.
• In C, we can do both declaration and definition at same
place, like done in the previous example program.
• C also allows to declare and define functions separately,
this is specially needed in case of library functions.
• The library functions are declared in header files and
defined in library files.
52.
53.
54.
55. return_type function_name( Parameter_list ); //function declaration
return_type main() // main function
{
Body of main function
function_name ( Actual Arguments); // Calling above function
}
return_type function_name( Formal Arguments or parameters ) //function
definition
{
Body of user defined function
}
57. 1.No arguments and No return Value:
#include <stdio.h>
void add(void ); //function declaration
void main() // main function with “int” return type
{ clrscr();
add();
getch();
}
Void add(void) //function definition
{ int x,y,z;
printf(“Enter numbers”);
Scanf(“%dn%d”,&x,&y);
z=x+y;
printf(“%d”,z);
}
58. 2.Function with arguments and
no return Value:
#include <stdio.h>
void add(int,int); //function declaration
void main() // main function with “int” return type
{
int a, b;
clrscr();
printf(“Enter two numbers”);
Scanf(“%dn%d”,&a,&b);
add(a,b);
getch();
}
Void add(int x, int y) //function definition
{ int z;
z=x+y;
printf(“%d”,z);
}
59. 3.Function with no arguments and
with return Value:
#include <stdio.h>
void add(void); //function declaration
void main() // main function with “int” return type
{
int c;
clrscr();
c= add();
printf(“%d”,c);
getch();
}
Void add() //function definition
{ int x,y,z;
printf(“Enter two numbers”);
Scanf(“%dn%d”,&x,&y);
z=x+y;
return z;
}
60. 4.Function with arguments and
Return Value:
#include <stdio.h>
void add(int,int); //function declaration
void main() // main function with “int” return type
{
int a, b,c;
clrscr();
printf(“Enter two numbers”);
Scanf(“%dn%d”,&a,&b);
c= add(a,b);
printf(“%d”,c);
getch();
}
Void add(int x, int y) //function definition
{ int z;
z=x+y;
return z;
}
66. • In this, values of actual parameters are copied
to function’s formal parameters.
• Two types of parameters are stored in
different memory locations.
• So any changes made inside functions are not
reflected in actual parameters of caller.
67.
68.
69. • Both actual and formal parameters refer to
same locations, so any changes made inside
the function are actually reflected in actual
parameters of caller.