For example:

assert(atof("1.2") == 1.2);

regardless of what float is used?

I understand that the floating point precision isn't exact, but it is precisely inexact so does the rounding to binary produce the exact same double?

  • Example: ideone.com/SwFcQG – Peter Hansen Apr 2 '18 at 16:42
  • Yeah, tested several non-trivial numbers and it is surprisingly working. Yet not guaranteed by the standard. – Eugene Sh. Apr 2 '18 at 16:49
  • 3
    It's not guaranteed that the compiler's parsing of such strings is the same as the runtime library (and when you're cross-compiling, you're necessarily using a different implementation). – Toby Speight Apr 2 '18 at 17:48

This is not guaranteed by the C standard. The semantics of converting a floating-point literal in the source code are specified in C 2011 [draft N1570] This says the recommended, but not required, practice is that the translation-time conversion of floating-point constants should match the execution-time conversion of character strings by library functions, such as strtod.

More than that, the standard does not even require that two different literals with the same mathematical value, such as 1.23 and 1.230, convert to the same value. These examples come from footnote 75 in the standard, which is a footnote to a paragraph stating that all floating-point constants of the same source form shall convert to the same value. Thus, 1.23 always converts to the same value wherever it appears in the source, but 1.230 does not necessarily convert to the same value as 1.23 or 123e-2. Even 123e-2 and 123e-02 may be different.

atof(p) is specified in to be equivalent to strtod(p, (char **) NULL) except for how they behave with errors. strtod is specified in That clause has some recommended practices for accuracy but is silent about matching the translation-time conversion of literals.

  • 4
    @PeterHansen you should never trust floating point equality anyway. – Weather Vane Apr 2 '18 at 16:46
  • 2
    @PeterHansen: Yes, or check its documentation (or source code) or ask its implementor or vendor. – Eric Postpischil Apr 2 '18 at 16:46
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    @WeatherVane: That is bad advice; please do not spread it. Using floating-point properly requires expertise, but it is possible. – Eric Postpischil Apr 2 '18 at 16:47
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    I get you, but your argument is Straw Man. I never suggested comparing with a tolerance. Don't use floating point comparisons until you have read Eric Postpischil's thesis. Don't use floating point at all, unless you have MSc at the least. – Weather Vane Apr 2 '18 at 20:43
  • 5
    @WeatherVane: You are right, I lost the thread, and comparing with a tolerance is a diversion. The issue was using floating-point equality. My points on that stand. Doing the job right is not simple. If it requires study and thought, it requires study and thought. There are numerous textbooks, courses, and papers on using floating-point. Mockery is not a rebuttal. – Eric Postpischil Apr 2 '18 at 20:57

This check will inevitably be implementation-dependent, so I've written the following little test script:

#include <stdio.h>
#include <stdlib.h>

int main()
  double d1 = 1.2;
  double d2 = atof("1.2");
  char *p;
  double d3 = strtod("1.2", &p);

  printf("d1 = %40.40f\n", d1);
  printf("d2 = %40.40f\n", d2);
  printf("d3 = %40.40f\n", d3);

  if(d1 != d2)
    printf("d1 != d2\n");

  if(d2 != d3)
    printf("d2 != d3\n");

In the case of the HP C/C++ compiler, version A.06.25.02, this outputs

d1 = 1.1999999999999999555910790149937383800000
d2 = 1.1999999999999999555910790149937383800000
d3 = 1.1999999999999999555910790149937383800000

which demonstrates that the conversion (of 1.2, at least) which is performed by the compiler matches the conversions performed by atof and strtod.


From Military engineering we always account for this issue by placing a tolerance band say +/- 0.000001 around the true float comparison value. This way you know what you are truly comparing and help prevent polluting what the algorithm is designed to do. One is always working with fuzzy numbers when working with floating point numbers where one can't or should not do a hard comparison on.

  • 3
    This advice is harmful and will break algorithms working with huge or tiny numbers. Imagine adding 0.000001 when your numbers are 1.234*10^-30 or 1.234*10^30. – pipe Apr 3 '18 at 0:32
  • 1
    Fist, the original problem was 1.2 not 1.234*10^30, – ChristineDD Apr 3 '18 at 0:51
  • 1
    The question explicitly states "regardless of what float is used". – pipe Apr 3 '18 at 1:01

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