C – Math Functions




Math Functions in C



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C Math Functions

C language provides various functions to perform mathematical operations on numbers such as finding trigonometric ratios, calculating log and exponentials, rounding the numbers, etc.. To use these math functions in a C program, you need to include math.h header file.

We have categorized math functions into the following categories −


Trigonometric Functions

The math.h library defines the function sin(), cos(), and tan() – that return the respective trigonometric ratios, sine, cosine and tangent of an angle.

These functions return the respective ratio for a given double type representing the angle expressed in radians. All the functions return a double value.


double sin(double x)
double cos(double x)
double tan(double x)

For all the above functions, the argument “x” is the angle in radians.

Example

The following example shows how you can use trigonometric functions in C −


#include <stdio.h>
#include <math.h>

#define PI 3.14159265

int main() {

   double x, sn, cs, tn, val;

   x = 45.0;
   val = PI / 180;

   sn = sin(x*val);
   cs = cos(x*val);
   tn = tan(x*val);

   printf("sin(%f) : %fn", x, sn);
   printf("cos(%f) : %fn", x, cs);
   printf("tan(%f) : %fn", x, tn);

   return(0);
}

Output

When you run this code, it will produce the following output −


sin(45.000000) : 0.707107
cos(45.000000) : 0.707107
tan(45.000000) : 1.000000

Inverse Trigonometric Functions

The math.h library also includes inverse trigonometric functions, also known as arcus functions or anti-trigonometric functions. They are the inverse functions of basic trigonometric functions. For example, asin(x) is equivalent to $&bsol;mathrm{sin^{-1}(x)}$. The other inverse functions are acos(), atan() and atan2().

The following asin() function returns the arc sine of “x” in the interval [-pi/2, +pi/2] radians −


double asin(double x)

The following acos() function returns principal arc cosine of “x” in the interval [0, pi] radians −


double acos(double x)

The following atan() function returns the principal arc tangent of “x” in the interval [-pi/2, +pi/2] radians.


double atan(double x)

Example 1

The following example demonstrates how you can use inverse trigonometric functions in a C program −


#include <stdio.h>
#include <math.h>

#define PI 3.14159265

int main() {

   double x, asn, acs, atn, val;

   x = 0.9;
   val = 180/PI;

   asn = asin(x);
   acs = acos(x);
   atn = atan(x);

   printf("asin(%f) : %f in radiansn", x, asn);
   printf("acos(%f) : %f in radiansn", x, acs);
   printf("atan(%f) : %f in radiansn", x, atn);

   asn = (asn * 180) / PI;
   acs = (acs * 180) / PI;
   atn = (atn * 180) / PI;

   printf("asin(%f) : %f in degreesn", x, asn);
   printf("acos(%f) : %f in degreesn", x, acs);
   printf("atan(%f) : %f in degreesn", x, atn);

   return(0);
}

Output

When you run this code, it will produce the following output −


asin(0.900000) : 1.119770 in radians
acos(0.900000) : 0.451027 in radians
atan(0.900000) : 0.732815 in radians
asin(0.900000) : 64.158067 in degrees
acos(0.900000) : 25.841933 in degrees
atan(0.900000) : 41.987213 in degrees

The atan2() function returns the arc tangent in radians of “y/x” based on the signs of both values to determine the correct quadrant.

double atan2(double y, double x)

This function returns the principal arc tangent of “y / x” in the interval [-pi, +pi] radians.

Example 2

Take a look at the following example −


#include <stdio.h>
#include <math.h>

#define PI 3.14159265

int main() {

   double x, y, ret, val;

   x = -7.0;
   y = 7.0;
   val = 180.0 / PI;

   ret = atan2 (y,x) * val;
   printf("The arc tangent of x = %lf, y = %lf ", x, y);
   printf("is %lf degreesn", ret);

   return(0);
}

Output

Run the code and check its output −


The arc tangent of x = -7.000000, y = 7.000000 is 135.000000 degrees

Hyperbolic Functions

In Mathematics, hyperbolic functions are similar to trigonometric functions but are defined using the hyperbola rather than the circle. The math.h header file provides sinh(), cosh(), and tanh() functions.


double sinh(double x)

This function returns hyperbolic sine of x.


double cosh(double x)

This function returns hyperbolic cosine of x.


double tanh(double x)

This function returns hyperbolic tangent of x.

Example

The following example shows how you can use hyperbolic functions in a C program −


#include <stdio.h>
#include <math.h>

#define PI 3.14159265

int main() {

   double x,val, sh, ch, th;

   x = 45;
   val = PI/180.0 ;

   sh = sinh(x*val);
   ch = cosh(x*val);
   th = tanh(x*val);
   
   printf("The sinh(%f) = %lfn", x, sh);
   printf("The cosh(%f) = %lfn", x, ch);
   printf("The tanh(%f) = %lfn", x, th);

   return(0);
}

Output

Run the code and check its output −


The sinh(45.000000) = 0.868671
The cosh(45.000000) = 1.324609
The tanh(45.000000) = 0.655794

Exponentiation and Logarithmic Functions

The “math.h” library includes the following functions related to exponentiation and logarithms −

exp() Function: It returns the value of e raised to the xth power. (Value of e – Euler’s number – is 2.718 approx)


double exp(double x)

log() Function: It returns the natural logarithm (base-e logarithm) of “x”.


double log(double x)

Note that Logarithmic functions are equivalent to the exponential function’s inverse.

log10() Function: It returns the common logarithm (base-10 logarithm) of “x”.


double log10(double x)

Example

The following example shows how you can use exponentiation and logarithmic functions in a C program −


#include <stdio.h>
#include <math.h>

#define PI 3.14159265

int main () {

   double x = 2;
   double e, ln, ls;
   e = exp(2);
   ln = log(e);
   printf("exp(%f): %f log(%f): %fn",x, e, e, ln);

   ln = log(x);
   printf("log(%f): %fn",x,ln);
   ls = log10(x);
   printf("log10(%f): %fn",x,ls);

   return(0);
}

Output

When you run this code, it will produce the following output −


exp(2.000000): 7.389056 log(7.389056): 2.000000
log(2.000000): 0.693147
log10(2.000000): 0.301030

Floating-Point Functions

The frexp() and ldexp() functions are used for floating-point manipulation.

frexp() Function

The “math.h” header file also includes the frexp() function. It breaks a floating-point number into its significand and exponent.


double frexp(double x, int *exponent)

Here, “x” is the floating point value to be computed and “exponent” is the pointer to an int object where the value of the exponent is to be stored.

This function returns the normalized fraction.

Example

Take a look at the following example −


#include <stdio.h>
#include <math.h>

int main () {

   double x = 1024, fraction;
   int e;

   fraction = frexp(x, &e);
   printf("x = %.2lf = %.2lf * 2^%dn", x, fraction, e);

   return(0);
}

Output

Run the code and check its output −


x = 1024.00 = 0.50 * 2^11

ldexp() Function

The ldexp() function combines a significand and an exponent to form a floating-point number. Its syntax is as follows −


double ldexp(double x, int exponent)

Here, “x” is the floating point value representing the significand and “exponent” is the value of the exponent. This function returns (x * 2 exp)

Example

The following example shows how you can use this ldexp() function in a C program −


#include <stdio.h>
#include <math.h>

int main () {

   double x, ret;
   int n;

   x = 0.65;
   n = 3;
   ret = ldexp(x ,n);
   printf("%f * 2 %d = %fn", x, n, ret);

   return(0);
}

Output

Run the code and check its output −


0.650000 * 2^3 = 5.200000

Power and Square Root Functions

The pow() and sqrt() functions are used to calculate the power and square root of the given number.

pow() Function

This function returns x raised to the power of y i.e. xy.


double pow(double x, double y)

sqrt() Function

returns the square root of x.


double sqrt(double x)

The sqrt(x) function returns a value which is same as pow(x, 0.5)

Example

The following example shows how you can use the pow() and sqrt() functions in a C program −


#include <stdio.h>
#include <math.h>

int main() {

   double x = 9, y=2;

   printf("Square root of %lf is %lfn", x, sqrt(x));
   printf("Square root of %lf is %lfn", x, pow(x, 0.5) );
   printf("%lf raised to power %lfn", x, pow(x, y));

   return(0);
}

Output

When you run this code, it will produce the following output −


Square root of 9.000000 is 3.000000
Square root of 9.000000 is 3.000000
9.000000 raised to power 81.000000

Rounding Functions

The math.h library includes ceil(), floor(), and round() functions that round off the given floating point number.

ceil() Function

This returns the smallest integer value greater than or equal to x.


double ceil(double x)

This function returns the smallest integral value not less than x.

floor() Function

This function returns the largest integer value less than or equal to x.


double floor(double x)

Parameter x : This is the floating point value. This function returns the largest integral value not greater than x.

round() Function

This function is used to round off the double, float or long double value passed to it as a parameter to the nearest integral value.


double round( double x )

The value returned is the nearest integer represented as floating point

Example

The following example demonstrates how you can use the rounding functions in a C program −


#include <stdio.h>
#include <math.h>

int main() {

   float val1, val2, val3, val4;

   val1 = 1.2;
   val2 = 1.6;
   val3 = 2.8;
   val4 = -2.3;

   printf ("ceil(%lf) = %.1lfn", val1, ceil(val1));
   printf ("floor(%lf) = %.1lfn", val2, floor(val2));
   printf ("ceil(%lf) = %.1lfn", val3, ceil(val3));
   printf ("floor(%lf) = %.1lfn", val4, floor(val4));

   printf("round(%lf) = %.1lfn", val1, round(val1));
   printf("round(%lf) = %.1lf", val4, round(val4));

   return(0);
}

Output

When you run this code, it will produce the following output −


ceil(1.200000) = 2.0
floor(1.600000) = 1.0
ceil(2.800000) = 3.0
floor(-2.300000) = -3.0
round(1.200000) = 1.0
round(-2.300000) = -2.0

Modulus Functions

The “math.h” library includes the following functions in this category:

modf() Function

The modf() function returns the fraction component (part after the decimal), and sets integer to the integer component.


double modf(double x, double *integer)

Here, “x” is the floating point value and “integer” is the pointer to an object where the integral part is to be stored.

This function returns the fractional part of “x” with the same sign.

Example

Take a look at the following example −


#include <stdio.h>
#include <math.h>

int main () {

   double x, fractpart, intpart;

   x = 8.123456;
   fractpart = modf(x, &intpart);

   printf("Integral part = %lfn", intpart);
   printf("Fraction Part = %lf n", fractpart);

   return(0);
}

Output

When you run this code, it will produce the following output −


Integral part = 8.000000
Fraction Part = 0.123456

fmod() Function

The fmod() function returns the remainder of x divided by y.


double fmod(double x, double y)

Here, “x” is the numerator and “y” is the denominator. The function returns remainder of “x / y“.

Example

Take a look at the following example −


#include <stdio.h>
#include <math.h>

int main () {

   float a, b;
   int c;
   a = 9.2;
   b = 3.7;
   c = 2;
   
   printf("Remainder of %f / %d is %lfn", a, c, fmod(a,c));
   printf("Remainder of %f / %f is %lfn", a, b, fmod(a,b));

   return(0);
}

Output

When you run this code, it will produce the following output −


Remainder of 9.200000 / 2 is 1.200000
Remainder of 9.200000 / 3.700000 is 1.800000

Note that the modulus operator (%) works only with integer operands.

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