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 x2 = x_radians * x_radians;
double sum = 0.0;
double term = x_radians;
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.

`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.`o1=a*o2*((x*x)/(i*(i+1)));`

is too dense for me.3more comments