# Custom Sine function using Taylor's Series in C (maybe C++ too) [closed]

Here is a lil program i made for calculating sine with Tayilo's serires for a school assignment i had. Does anyone have a better idea? I mean it works but it can be better

#include <stdio.h>
#include <math.h>
int main(int argc, int **argv){
system ("chcp 1253");
int deg, i, a=(-1), flag=0;
double pi=3.14159265359, x, sinx, o1, o2; //pi is rounded up to the last digit

printf("Δώσε γωνία σε μοίρες από 0-2π (0-360):"); //translate: give angle in degrees
scanf("%d",&deg);
x=(pi/180)*deg; //apo moires se rad (metavlith x)
o2=((x*x*x)/6)*a;
sinx=x+o2;

for(i=4; flag!=1; i+=2){
o1=a*o2*((x*x)/(i*(i+1)));
if (fabs(o2-o1)<=0.000001){
flag=1;
};
sinx=sinx+o1;
o2=o1;
};

printf("\nΤο ημίτονο του %d είναι: %f", deg, sinx); //the sine of %d is ...
return 0;
};

There is nothing wrong with the code as my rookie eyes see, but im definetly sure it can be improved.

• Search the internet for "C++ Sine taylor series optimal". Always search the internet before posting to StackOverflow. Dec 7, 2023 at 21:10
• Welcome to Stack Overflow! If the code works and you're looking for advice on improving it, Code Review is the appropriate place. But see codereview.meta.stackexchange.com/questions/5777/… first. Dec 7, 2023 at 21:11
• You should make a constant temporary variable: const double x_squared = x * x; In your loop, replace x * x with x_squared. No need to repeat the x * x calculation when the x variable doesn't change in the loop. Dec 7, 2023 at 21:13
• @ThomasMatthews You can do that in C too. Dec 7, 2023 at 21:54
• It's a personal preference but you might try adding whitespace around operators for readability. o1=a*o2*((x*x)/(i*(i+1))); is too dense for me. Dec 7, 2023 at 22:44

Does anyone have a better idea? I mean it works but it can be better

Fails for 333°

Expected "-0.453990", Received "-0.453991". A simple loop of integer values [0-360] would have detected this. IOWs, even simple test code better than "nothing wrong with the code as my rookie eyes" and pointed the need for smaller epsilon.

Only handles integer values

Took me a while to see this code does not report any input problem with non-integer input like 1.234, Code needs better input validation. As is, it give wrong results (e. g. the result of sine(1))

Fails for large values

"There is nothing wrong with the code as my rookie eyes" --> Try 3600 degrees. If that is outside the range of acceptable input, report that range error.

Very course

Little reason for such a low precision result from a double function.

Approximate π

"pi is rounded up to the last digit" mis-states the last digit. There is no advantage in using such a rounded value. double typically has 53-bits of precision. Use at least 17 significant decimal digits for machine π. Your system will use what it can.

// double pi=3.14159265359
double pi=3.1415926535897932384626433832795

Its floating point

double is encoded as floating point, not fixed point. fabs(o2-o1)<=0.000001 is a useful compare for fixed point algorithm. Instead the terminating condition should approach the series ending from a floating point of view.

// fabs(o2-o1)<=0.000001
#define MY_EPSILON 0.000001
fabs(o2-o1)<= fabs(o1)*MY_EPSILON

I'd use a finer epsilon, maybe 1.0e-15 and avoid naked magic numbers.

Likewise "%f" reports with fixed number of places after the decimal point. This reports 0.000000 for all tiny angles when the sine Taylor's series algorithm works very well for small angles. Use "%g" or perhaps "%.15g" for more detail. The printf() precision used here is related to the epsilon used above.

Large values

When the range is far from [-90...+90] degrees, the Taylor series converges slowly. Use trig identifies to bring the angle into [-45...+45] degree range. Also code a cosine() routine.

Range reduction as radians is tricky as π is an irrational number. Therefore reduce the angle, in degrees first. With fmod(), this is usually exact.

deg = fmod(deg, 360.0);

Pedantic bug: -0.0

For input -0.0, I'd expect an output of -0.000000 as sine() is a odd function instead of OP's 0.000000.

Sample alternative (untested, and still lacks range reduction other than [-360... +360] - something yet to do):

#include <math.h>
double sine(double x_degrees) {
static const double d2r = 3.1415926535897932384626433832795 / 180.0;
// Bring x into the primary range
x_degrees = fmod(x_degrees, 360.0);
// To do: reduce to -45... 45 range.
double x_radians = x_degrees * d2r;
double sum = 0.0;
for (unsigned i = 1; ; i++);
double new_sum = sum + term;
// If additional terms fail to change the sum, quit.
if (new_sum == sum) {
break;
}
sum = new_sum;
term *= -x2 / ((2 * i) * (2 * i + 1));
}
return sum;
}

Once you get a better sine(), along with test code, post on Code Review for a deeper review.

• Is it possible that for (unsigned i = 1; ; i++); loops round for a 16 bit unsigned on some values of x_degrees and you end up with division by zero? I'd be tempted to use for (unsigned i = 1; i; ++i);. My adjustment to ++i is an old habit. Dec 8, 2023 at 15:00
• @Bathsheba With 16-bit or any bit width unsigned, I do not see division by zero happening once |x_radians| <= pi/4 after all range reductions (not all shown to leave some work for OP), as term becomes vanishingly small sooner. Note problems occurs once i > 127 or so, yet term should hit 0 long beforehand. Dec 8, 2023 at 15:24
• I'd love to spend time analysing this for all allowable floating point schemes for double, but alas no time. Dec 8, 2023 at 15:41
• And you have a point on i > 127 - indeed the demoninator could overflow. x2 / (2 * i) / (2 * i + 1); is a subtle fix for that. Dec 8, 2023 at 15:42
• @Bathsheba True about x2 / (2 * i) / (2 * i + 1), yet that I assert is not needed and adds another rounding - which I try to avoid to maintain accuracy. At i == 33, sum + term should make no difference even with 128-bit FP. Dec 8, 2023 at 15:49