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int main()
{
    float a = 0.7;
    float b = 0.5;
    if (a < 0.7)
    {
       if (b < 0.5) printf("2 are right");
       else         printf("1 is right");
    }
    else printf("0 are right");
}

I would have expected the output of this code to be 0 are right. But to my dismay the output is 1 is right why?

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20  
5  
0.7 isnt a float but a double. That might be a reason for that behavior –  Paranaix Aug 10 '11 at 13:05
2  
One reason is that a is a float and .7 is a double. –  Bo Persson Aug 10 '11 at 13:05
3  
Mitch, if 0.7 == 0.7 the answer would be 0 are right –  Emil Vikström Aug 10 '11 at 13:06
1  
good point. It's late. I should stop now!..... –  Mitch Wheat Aug 10 '11 at 13:07
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6 Answers

up vote 89 down vote accepted
int main()
{
    float a = 0.7, b = 0.5; // These are FLOATS
    if(a < .7)              // This is a DOUBLE
    {
      if(b < .5)            // This is a DOUBLE
        printf("2 are right");
      else
        printf("1 is right");
    }
    else
      printf("0 are right");
}

Floats get promoted to doubles during comparison, and since floats are less precise than doubles, 0.7 as float is not the same as 0.7 as double. In this case, 0.7 as float becomes inferior to 0.7 as double when it gets promoted. And as Christian said, 0.5 being a power of 2 is always represented exactly, so the test works as expected: 0.5 < 0.5 is false.

So either change float to double or .7 and .5 to .7f and .5f and you will get the expected behavior.

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4  
+1 Answers question. –  user195488 Aug 10 '11 at 13:08
3  
+1 For the only answer that didn't call out "never compare floats" when seeing the question and actually thought about what is really going on here. –  Christian Rau Aug 10 '11 at 13:13
33  
The behavior is 100% predictable assuming IEEE 754 floating point. 0.7 becomes the nearest double (0.6999999999999999555910790149937383830547332763671875) and converting that to float rounds to the nearest float value (0.699999988079071044921875). –  R.. Aug 10 '11 at 14:28
3  
@sasidhar: 0.7 represented as float is stored as 0.699999988079071044921875 and stored as a double is 0.699999999999999955591079014994 So there is a difference of 0.000000011920928910669204014994 which is lost during the assignment to a That information can not be re-created when a is converted to a double. –  Loki Astari Aug 10 '11 at 16:10
3  
@sasidhar: You should assume that all floating point numbers will not be stored precisely and their will be some loss of information. (thus comparison of floating point values should not be done precisely but to a margin of error). Note if the variables get optimized out and all the values remain in registers for the duration of the program then you may get a different result. Try compiling in release mode with the optimizer turned to its highest level and see if the results change. –  Loki Astari Aug 10 '11 at 16:15
show 9 more comments

The issue is that the constants you are comparing to are double not float. Also, changing your constants to something that is representable easily such as a factor of 5 will make it say 0 is right. For example,

main()
{
    float a=0.25,b=0.5; 
    if(a<.25) 
       {
       if(b<.5) 
               printf("2 are right");
       else
               printf("1 is right");
       }
else
printf("0 are right");
}

Output:

0 are right

This SO question on Most Effective Way for float and double comparison covers this topic.

Also, this article at cygnus on floating point number comparison gives us some tips:

The IEEE float and double formats were designed so that the numbers are “lexicographically ordered”, which – in the words of IEEE architect William Kahan means “if two floating-point numbers in the same format are ordered ( say x < y ), then they are ordered the same way when their bits are reinterpreted as Sign-Magnitude integers.”

This means that if we take two floats in memory, interpret their bit pattern as integers, and compare them, we can tell which is larger, without doing a floating point comparison. In the C/C++ language this comparison looks like this:

if (*(int*)&f1 < *(int*)&f2)

This charming syntax means take the address of f1, treat it as an integer pointer, and dereference it. All those pointer operations look expensive, but they basically all cancel out and just mean ‘treat f1 as an integer’. Since we apply the same syntax to f2 the whole line means ‘compare f1 and f2, using their in-memory representations interpreted as integers instead of floats’.

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5  
The integer comparison assumes sizeof(int) == sizeof(float). An even worse assumption when dealing with double. –  Zan Lynx Aug 10 '11 at 16:10
1  
It also violates Strict Aliasing Rule. –  osgx Aug 11 '11 at 5:09
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It's due to rounding issues while converting from float to double

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Generally comparing equality with floats is a dangerous business (which is effectively what you're doing as you're comparing right on the boundary of > ), remember that in decimal certain fractions (like 1/3) cannot be expressed exactly, the same can be said of binary,

0.5= 0.1, will be the same in float or double.

0.7=0.10110011001100 etc forever, 0.7 cannot be exactly represented in binary, you get rounding errors and may be (very very slightly) different between float and double

Note that going between floats and doubles you cut off a different number of decimal places, hence your inconsistant results.

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Also, btw, you have an error in your logic of 0 are right. You don't check b when you output 0 are right. But the whole thing is a little mysterious in what you are really trying to accomplish. Floating point comparisons between floats and doubles will have variations, minute, so you should compare with a delta 'acceptable' variation for your situation. I've always done this via inline functions that just perform the work (did it once with a macro, but thats too messy). Anyhow, yah, rounding issues abound with this type of example. Read the floating point stuff, and know that .7 is different than .7f and assigning .7 to a float will cast a double into a float, thus changing the exact nature of the value. But, the programming assumption about b being wrong since you checked a blared out to me, and I had to note that :)

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Read this link : http://www.cygnus-software.com/papers/comparingfloats/Comparing%20floating%20point%20numbers.htm

It explains very well (sorry, it's a bit long) why there's an error delta comparing two float numbers... I didn't read throu it completely, just a bit here and there... Try and let me know if it's good :)

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2  
yeah, worst answer of all. doesn't seem like that, but ok, i get it. –  Samuele Mattiuzzo Aug 10 '11 at 14:14
2  
-1 for link dumping without having read the article –  walkingTarget Aug 10 '11 at 16:14
    
i read it, not the whole, but i read bits, and there's explained why the loss in precision for floats. –  Samuele Mattiuzzo Aug 11 '11 at 7:41
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