# Trying to write a code for finding the machine epsilon

I am trying to find out the precision level for various floating point formats in C (i.e. float, double and long double). Here is the code I'm using at the moment:

``````#include <stdio.h>
#define N 100000

int main(void)
{
float max = 1.0, min = 0.0, test;
int i;                              /* Counter for the conditional loop */

for (i = 0; i < N; i++) {
test = (max + min) / 2.0;
if( (1.0 + test) != 1.0)         /* If too high, set max to test and try again */
max = test;
if( (1.0 + test) == 1.0)     /* If too low, set min to test and try again */
min = test;
}
printf("The epsilon machine is %.50lf\n", max);
return 0;
}
``````

This gives the value of roughly ~2^-64 as expected. However when I change the decelerations to doubles or 'long doubles' I get the same answer I should get a smaller value but I don't. Anybody got any ideas?

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Doesn't float have a 23-bit mantissa? Why would you expect 2^-64? –  Rup Aug 13 '10 at 16:19

A guess why you're getting the same answer:

``````if( (1.0 + test) != 1.0)
``````

Here 1.0 is a double constant, so it's promoting your float to a double and performing the addition as a double. You probably want to declare a temporary float here to perform the addition, or make those float numeric constants (`1.0f` IIRC).

You might also be falling into the excess-precision-in-temporary-floats problem and might need to force it to store the intermediates in memory to reduce to the correct precision.

Here's a quick go at redoing your range search method but computing the test in the correct type. I get an answer that's slightly too large, though.

``````#include <stdio.h>
#define N 100000
#define TYPE float

int main(void)
{
TYPE max = 1.0, min = 0.0, test;
int i;

for (i = 0; i < N; i++)
{
TYPE one_plus_test;

test = (max + min) / ((TYPE)2.0);
one_plus_test = ((TYPE)1.0) + test;
if (one_plus_test == ((TYPE)1.0))
{
min = test;
}
else
{
max = test;
}
}
printf("The epsilon machine is %.50lf\n", max);
return 0;
}
``````
-
I think casting `(1.0 + test)` to `float` might fix it, but I'm not sure.. –  R.. Aug 13 '10 at 16:37
How do I 'cast' it as a float? I'll give it a go and see what happens –  JMzance Aug 13 '10 at 16:50
Yeah I tried that but its still giving me and epsilon value of 2^-64 –  JMzance Aug 13 '10 at 18:01
OK, try storing it to, then reading it from, a `volatile float` variable. That is: `volatile float tmp = 1.0 + test; if (tmp == 1.0) ...` –  R.. Aug 13 '10 at 18:29

It depends upon what you mean by "precision level".

Floating-point numbers have "regular" (normal) values, but there are special, sub-normal numbers as well. If you want to find out different limits, the C standard has predefined constants:

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

int main(void)
{
printf("%30s: %g\n", "FLT_EPSILON", FLT_EPSILON);
printf("%30s: %g\n", "FLT_MIN", FLT_MIN);
printf("%30s: %g\n", "nextafterf(0.0, 1.0)", nextafterf(0.0, 1.0));
printf("%30s: %g\n", "nextafterf(1.0, 2.0)-1", (nextafterf(1.0, 2.0) - 1.0f));
puts("");
printf("%30s: %g\n", "DBL_EPSILON", DBL_EPSILON);
printf("%30s: %g\n", "DBL_MIN", DBL_MIN);
printf("%30s: %g\n", "nextafter(0.0, 1.0)", nextafter(0.0, 1.0));
printf("%30s: %g\n", "nextafter(1.0, 2.0)-1", (nextafter(1.0, 2.0) - 1.0));
puts("");
printf("%30s: %Lg\n", "LDBL_EPSILON", LDBL_EPSILON);
printf("%30s: %Lg\n", "LDBL_MIN", LDBL_MIN);
printf("%30s: %Lg\n", "nextafterl(0.0, 1.0)", nextafterl(0.0, 1.0));
printf("%30s: %Lg\n", "nextafterl(1.0, 2.0)-1", (nextafterl(1.0, 2.0) - 1.0));
return 0;
}
``````

The above program prints 4 values for each type:

• the difference between 1 and the least value greater than 1 in that type (TYPE`_EPSILON`),
• the minimum positive normalized value in a given type (TYPE`_MIN`). This does not include subnormal numbers,
• the minimum positive value in a given type (`nextafter`*`(0`...`)`). This includes subnormal numbers,
• the minimum number greater than 1. This is the same as TYPE`_EPSILON`, but calculated in a different way.

Depending upon what you mean by "precision", any or none of the above can be useful to you.

Here is the output of the above program on my computer:

``````               FLT_EPSILON: 1.19209e-07
FLT_MIN: 1.17549e-38
nextafterf(0.0, 1.0): 1.4013e-45
nextafterf(1.0, 2.0)-1: 1.19209e-07

DBL_EPSILON: 2.22045e-16
DBL_MIN: 2.22507e-308
nextafter(0.0, 1.0): 4.94066e-324
nextafter(1.0, 2.0)-1: 2.22045e-16

LDBL_EPSILON: 1.0842e-19
LDBL_MIN: 3.3621e-4932
nextafterl(0.0, 1.0): 3.6452e-4951
nextafterl(1.0, 2.0)-1: 1.0842e-19
``````
-
Cheers, im glad C has in built thing for this. However my task is to write a code to find the smallest value greater than one that can be represented by a floating number. The first number there: 1.19209e-07 is the one i expected but for some reason my code doesnt give me that. MAny Thanks –  JMzance Aug 14 '10 at 11:11
@Jack: OK. Then you should make sure that all the floating point numbers used in your calculation are `float` values. So instead of doing `1.0 + test != 1.0`, I would do: `float try = 1.0 + test; if (try != 1.0)`, etc. –  Alok Singhal Aug 14 '10 at 19:55
Cheers guys, its starting to give sensible answers now –  JMzance Aug 14 '10 at 21:02

I'm not sure how your algorithm is supposed to work. This one (C++) gives the correct answers:

``````#include <iostream>

template<typename T>
int epsilon() {
int pow = 0;
T eps = 1;
while (eps + 1 != 1) {
eps /= 2;
--pow;
}
return pow + 1;
}

int main() {
std::cout << "Epsilon for float: 2^" << epsilon<float>() << '\n';
std::cout << "Epsilon for double: 2^" << epsilon<double>() << '\n';
}
``````

This computes the smallest value such that, when added to 1, is still distinguishable from 1.

Output:

``````Epsilon for float: 2^-23
Epsilon for double: 2^-52
``````
-
I dont know any C++ Im afraid –  JMzance Aug 13 '10 at 17:33
It shouldn't be too hard to kunderstand if you know C. The template just lets me write `T` and substitute either `float` or `double` for that. And the printing works differently, but don't worry about that. –  Thomas Aug 13 '10 at 17:39

A problem with such code is that the compiler will load the floating point variables into floating point registers of the microprocessor. And if your microprocessor only has double precision floating point registers, the precision will be the same for `float` and `double`.

You'll need to find a way to force the compiler to store the floating point value back to the memory between each two calculations (into a variable of the correct type). That way it has to throw away the additional precision of the registers. But today's compilers are clever in optimizing your code. So this can be difficult to achieve.

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Hmmm interesting, I could try using a crap compiler! lol –  JMzance Aug 14 '10 at 11:13
Why not just compile in debug mode or similar, that doesn't perform optimizations? –  PeMa Apr 8 at 12:32