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.

I have been trying to solve a bug that was caused by floating point arithmetic and I reduced it to a simple piece of code that is causing the behavior I don't understand:

float one = 1;
float three = 3;

float result = one / three;
Console.WriteLine(result); // prints 0.33333

double back = three * result;

if (back > 1.0)
    Console.WriteLine("larger than one");
else if (back < 1.0)
    Console.WriteLine("less than one");
else
    Console.WriteLine("exactly one");

As result rounded to 0.33333, I would expect back to be less that 1, however the output is "larger than one".

Can someone explain what is going on here?

share|improve this question
    
Rounding. Presumably to get that result, the 1/3 in FP is more like 0.333...34, where the 4 is outside the printed range –  Marc Gravell Feb 15 '14 at 8:40
    
possible duplicate of Comparing double values in C# –  Athari Feb 15 '14 at 8:41
    
But why would 0.33333... round to 0.33334? Shouldn't it round to 0.3333 as 3 is less than 5? –  korhner Feb 15 '14 at 8:41
2  
@korhner FP rounding is to the nearest representable value. It is not like decimal rounding. –  Marc Gravell Feb 15 '14 at 9:13

2 Answers 2

up vote 4 down vote accepted

Using IEEE 754 rounding, let's see what's going on.

In IEEE 754 single-precision floating point, the value of a finite number is dictated by the following:

-1sign × 2exponent × (1 + mantissa × 2-23)

Where

  • sign is 0 if positive, otherwise 1;
  • exponent is a value between -126 and 127 (-127 and 128 are special); and
  • mantissa is a value between 0 and 8388607 (because it's a 23 bit integer).

If we substitute sign with 0 and exponent with -2, then we're guaranteed a value between 0.25 and 0.5. Why?

1 × 2-2

is ¼. The value of

1 + mantissa × 2-23

is guaranteed to be between 1 and 2, so that's our sign and exponent sorted.


Moving on, we can work out fairly quickly that there are two values which can be used as the mantissa value: 2796202 and 2796203.

Substituting each in, we get the following two values (one lower, one higher):

  • 0.333333313465118408203125 (for mantissa = 2796202)
  • 0.3333333432674407958984375 (for mantissa = 2796203)

The binary representation of the exact value (up to 22 digits) is:

1010101010101010101010...

As the next digit would be 1, that would mean the value rounds up, not down. For this reason, the higher one has a less significant error than the lower one:

  • 0.333333313465118408203125 - ⅓ ≑ -1.987 × 10-8
  • 0.3333333432674407958984375 - ⅓ ≑ 9.934 × 10-9

And since it's larger than the exact value, when multiplied back it will be more than 1. That's why it uses a value that appears off initially -- binary rounding sometimes goes in the opposite direction of decimal rounding.

share|improve this answer
    
Great explanation, thank you –  korhner Feb 15 '14 at 9:43
1  
Note that if you change "double back = three * result;" to "float back = three * result;" the answer is "exactly one". That would mask the fact that the float version of 1/3 is greater than 1/3. –  Rick Regan Feb 15 '14 at 14:56

When I tried above code I found that

float result = one / three;

statement evaluate the value of result as 0.333333343 not the 0.33333 but console prints it as 0.33333 and then I executed the following statement

double back = three * result;

it evaluates the back as 1.0000000298023224 which is obviously greater than 1 that's why you are getting "larger than one".

share|improve this answer
1  
@korhner float and double do indeed use base 2, and decimal does use base 10, but all three of those are floating point types. They're called "floating point" because (roughly) 1.23m is stored as 123, plus the position of the .. 12.3m is also stored as 123, plus a different position of the .. The fact that the position of the . can vary makes the type a floating point type, hence the name. This is different from fixed-point types, where (for example) some languages' Currency type always stores exactly four decimals. –  hvd Feb 15 '14 at 9:40

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.