As others have explained, when you enter that number directly in your source code, not all the fraction digits will be used, as you only get 15/16 decimal places for precision. In fact, they get converted to the nearest double value in binary (anything beyond the fixed limit of digits is dropped).

To make things worse, and according to @R, IEEE 754 tolerates error in the last bit when using the cosine function. I actually ran into this when using different compilers.

To illustrate, I tested with the following MEX file, once compiled with the default LCC compiler, and then using VS2010 (I am on WinXP 32-bit).

In one function we directly call the C functions (`mexPrintf`

is simply a macro `#define`

as `printf`

). In the other, we call `mexEvalString`

to evaulate stuff in the MATLAB engine (equivalent to using the command prompt in MATLAB).

### prec.c

```
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include "mex.h"
void c_test()
{
double a = 2.89308776595231886830L;
double b = cos(a);
mexPrintf("[C] a = %.25Lf (%16Lx)\n", a, a);
mexPrintf("[C] b = %.25Lf (%16Lx)\n", b, b);
}
void matlab_test()
{
mexEvalString("a = 2.89308776595231886830;");
mexEvalString("b = cos(a);");
mexEvalString("fprintf('[M] a = %.25f (%bx)\\n', a, a)");
mexEvalString("fprintf('[M] b = %.25f (%bx)\\n', b, b)");
}
void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[])
{
matlab_test();
c_test();
}
```

### copmiled with LCC

```
>> prec
[M] a = 2.8930877659523189000000000 (4007250b32d9c886)
[M] b = -0.9692812353565483100000000 (bfef045a14cf738a)
[C] a = 2.8930877659523189000000000 ( 32d9c886)
[C] b = -0.9692812353565484200000000 ( 14cf738b) <---
```

### compiled with VS2010

```
>> prec
[M] a = 2.8930877659523189000000000 (4007250b32d9c886)
[M] b = -0.9692812353565483100000000 (bfef045a14cf738a)
[C] a = 2.8930877659523189000000000 ( 32d9c886)
[C] b = -0.9692812353565483100000000 ( 14cf738a) <---
```

I compile the above using: `mex -v -largeArrayDims prec.c`

, and switch between the backend compilers using: `mex -setup`

Note that I also tried to print the hexadecimal representation of the numbers. I only managed to show the lower half of binary double numbers in C (perhaps you can get the other half using some sort of bit manipulations, but I'm not sure how!)

Finally, if you need more precision in you calculations, consider using a library for variable precision arithmetic. In MATLAB, if you have access to the *Symbolic Math Toolbox*, try:

```
>> a = sym('2.89308776595231886830');
>> b = cos(a);
>> vpa(b,25)
ans =
-0.9692812353565483652970737
```

So you can see that the actual value is somewhere between the two different approximations I got above, and in fact they are all equal **up to** the 15th decimal place:

```
-0.96928123535654831.. # 0xbfef045a14cf738a
-0.96928123535654836.. # <--- actual value (cannot be represented in 64-bit)
-0.96928123535654842.. # 0xbfef045a14cf738b
^
15th digit --/
```

## UPDATE:

If you want to correctly display the hexadecimal representation of floating point numbers in C, use this helper function instead (similar to NUM2HEX function in MATLAB):

```
/* you need to adjust for double/float datatypes, big/little endianness */
void num2hex(double x)
{
unsigned char *p = (unsigned char *) &x;
int i;
for(i=sizeof(double)-1; i>=0; i--) {
printf("%02x", p[i]);
}
}
```

`abs(x - y) < epsilon`

? – delnan Oct 1 '11 at 18:10`cos`

or other trig functions. So they are implemented in software more often than not now. – Mysticial Oct 1 '11 at 18:15what?! The SSE et al hacks are a way to use thefloating point registers(i.e., the registers used to do, see,floating point) to futz around with short vectors of integers (whch is useful for multimedia). The point is that even if your operating system comes from the '80s (and knows nothing of such newfangled stuff) it will save and restore said registers. But for exactly that same reason, the functions are still implemented in silicon. In any case, it isn't like the CPUs are getting smaller... – vonbrand Jan 23 '13 at 0:43