Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Today I was tracking down why my program was getting some unexpected checksum-mismatch errors, in some code that I wrote that serializes and deserializes IEEE-754 floating-point values, in a format that includes a 32-bit checksum value (which is computed by running a CRC-type algorithm over the bytes of the floating-point array).

After a bit of head-scratching, I realized the problem was the 0.0f and -0.0f have different bit-patterns (0x00000000 vs 0x00000080 (little-endian), respectively), but they are considered equivalent by the C++ equality-operator. So, the checksum-mismatch errors happened because my checksum-calculating algorithm picked up the difference between those two bit-patterns, while certain other parts of my codebase (that use floating point equality testing, rather than looking at the values byte-by-byte) did not make that distinction.

Okay, fair enough -- I should probably have known better than to do floating-point equality testing anyway.

But this got me thinking, are there other IEEE-754 floating point values that are considered equal (according to the C == operator) but have different bit-patterns? Or, to put it another way, how exactly does the == operator decide whether two floating-point values are equal? Newbie me though it was doing something like memcmp() on their bit-patterns, but clearly it's more nuanced than that.

Here's a code example of what I mean, in case I wasn't clear above.

#include <stdio.h>

static void PrintFloatBytes(const char * title, float f)
{
   printf("Byte-representation of [%s] is: ", title);
   const unsigned char * p = (const unsigned char *) &f;
   for (int i=0; i<sizeof(f); i++) printf("%02x ", p[i]);
   printf("\n");
}

int main(int argc, char ** argv)
{
   const float pzero = -0.0f;
   const float nzero = +0.0f;
   PrintFloatBytes("pzero", pzero);
   PrintFloatBytes("nzero", nzero);
   printf("Is pzero equal to nzero?  %s\n", (pzero==nzero)?"Yes":"No");
   return 0;
}
share|improve this question
    
how-to.wikia.com/wiki/… FYI, using an epsilon is the way forward for float comparisons. Not on-topic, but useful to know. –  darvids0n Jun 7 '11 at 1:10
    
NaNs could go either way (possibly depending on the compiler). They also can be different in memory since there are a large number of possible NaNs (2^24-1 for single precision). –  ughoavgfhw Jun 7 '11 at 1:19

3 Answers 3

up vote 11 down vote accepted

It uses the IEEE-754 equality rules.

  • -0 == +0
  • NaN != NaN
share|improve this answer
1  
+1 NaN. Note that this is a case where the bit patterns would be the same, but == would return false. –  Ernest Friedman-Hill Jun 7 '11 at 1:06
    
+1 NaN. Also note that you can have different bit patterns representing the two NaNs. –  trutheality Jun 7 '11 at 1:16
    
Indeed, +0.0 and -0.0 are the only two distinct bit patterns that can compare equal. –  R.. Jun 7 '11 at 2:28
3  
@Ernest: minor nitpick: NaN has a lot of bit patterns. For 32-bit floats, it would be 2^23 - 1 different bit-patterns. –  Alok Singhal Jun 7 '11 at 5:59
    
Didn't know that! –  Ernest Friedman-Hill Jun 7 '11 at 10:42

For Windows platforms, this link has:

  • Divide by 0 produces +/- INF, except 0/0 which results in NaN.
  • log of (+/-) 0 produces -INF. log of a negative value (other than -0) produces NaN.
  • Reciprocal square root (rsq) or square root (sqrt) of a negative number produces NaN. The exception is -0; sqrt(-0) produces -0, and rsq(-0) produces -INF.
  • INF - INF = NaN
  • (+/-)INF / (+/-)INF = NaN
  • (+/-)INF * 0 = NaN
  • NaN (any OP) any-value = NaN
  • The comparisons EQ, GT, GE, LT, and LE, when either or both operands is NaN returns FALSE.
  • Comparisons ignore the sign of 0 (so +0 equals -0).
  • The comparison NE, when either or both operands is NaN returns TRUE.
  • Comparisons of any non-NaN value against +/- INF return the correct result.
share|improve this answer

exact comparison. That's why it's best to avoid == as a test on floats. It can lead to unexpected and subtle bugs.

A standard example is this code:

 float f = 0.1f;

 if((f*f) == 0.01f)
     printf("0.1 squared is 0.01\n");
 else
     printf("Surprise!\n");

because 0.1 can't be represented precisely in binary (it's a repeating whatever the hell you call a fractional binary) 0.1*0.1 won't be exactly 0.01 -- and thus the equality test won't work.

Numerical analysts worry about this at length, but for a first approximation it's useful to define a value -- APL called it FUZZ -- which is how closely two floats need to come to be considered equal. So you might, for example, #define FUZZ 0.00001f and test

 float f = 0.1f;

 if(abs((f*f)-0.01f) < FUZZ)
     printf("0.1 squared is 0.01\n");
 else
     printf("Surprise!\n");
share|improve this answer
6  
Clearly it's not exact comparison on the bit-by-bit level though, or it wouldn't indicate that (-0.0f == 0.0f) because those two values have different bit-patterns. –  Jeremy Friesner Jun 7 '11 at 1:02
    
A reasonable point that would be more apposite had I written "exact bit by bit comparison". –  Charlie Martin Jun 7 '11 at 1:11

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.