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When you read MSDN on System.Single:

Single complies with the IEC 60559:1989 (IEEE 754) standard for binary floating-point arithmetic.

and the C# Language Specification:

The float and double types are represented using the 32-bit single-precision and 64-bit double-precision IEEE 754 formats [...]

and later:

The product is computed according to the rules of IEEE 754 arithmetic.

you easily get the impression that the float type and its multiplication comply with IEEE 754.

It is a part of IEEE 754 that multiplcation is well-defined. By that I mean that when you have two float instances, there exists one and only one float which is their "correct" product. It is not permissible that the product depends on some "state" or "set-up" of the system calculating it.

Now, consider the following simple program:

using System;

static class Program
{
  static void Main()
  {
    Console.WriteLine("Environment");
    Console.WriteLine(Environment.Is64BitOperatingSystem);
    Console.WriteLine(Environment.Is64BitProcess);
    bool isDebug = false;
#if DEBUG
    isDebug = true;
#endif
    Console.WriteLine(isDebug);
    Console.WriteLine();

    float a, b, product, whole;

    Console.WriteLine("case .58");
    a = 0.58f;
    b = 100f;
    product = a * b;
    whole = 58f;
    Console.WriteLine(whole == product);
    Console.WriteLine((a * b) == product);
    Console.WriteLine((float)(a * b) == product);
    Console.WriteLine((int)(a * b));
  }
}

Appart from writing some info on the environment and compile configuration, the program just considers two floats (namely a and b) and their product. The last four write-lines are the interesting ones. Here's the output of running this on a 64-bit machine after compiling with Debug x86 (left), Release x86 (middle), and x64 (right):

Debug x86 (left), Release x86 (middle), and x64 (right)

We conclude that the result of simple float operations depends on the build configuration.

The first line after "case .58" is a simple check of equality of two floats. We expect it to be independent of build mode, but it's not. The next two lines we expect to be identical because it does not change anything to cast a float to a float. But they are not. We also expect them to read "True↩ True" because we're comparing the product a*b to itself. The last line of the output we expect to be independent of build configuration, but it's not.

To figure out what the correct product is, we calculate manually. The binary representation of 0.58 (a) is:

0 . 1(001 0100 0111 1010 1110 0)(001 0100 0111 1010 1110 0)...

where the block in parentheses is the period which repeats forever. The single-precision representation of this number needs to be rounded to:

0 . 1(001 0100 0111 1010 1110 0)(001      (*)

where we have rounded (in this case round down) to the nearest representable Single. Now, the number "one hundred" (b) is:

110 0100 .       (**)

in binary. Computing the full product of the numbers (*) and (**) gives:

 11 1001 . 1111 1111 1111 1111 1110 0100

which rounded (in this case rounding up) to single-precision gives

 11 1010 . 0000 0000 0000 0000 00

where we rounded up because the next bit was 1, not 0 (round to nearest). So we conclude that the result is 58f according to IEEE. This was not in any way given a priori, for example 0.59f * 100f is less than 59f, and 0.60f * 100f is greater than 60f, according to IEEE.

So it looks like the x64 version of the code got it right (right-most output window in the picture above).

Note: If any of the readers of this question have an old 32-bit CPU, it would be interesting to hear what the output of the above program is on their architecture.

And now for the question:

  1. Is the above a bug?
  2. If this is not a bug, where in the C# Specifcation does it say that the runtime may choose to perform a float multiplication with extra precision and then "forget" to get rid of that precision again?
  3. How can casting a float expression to the type float change anything?
  4. Isn't it a problem that seemingly innocent operations like splitting an expression into two expressions by e.g. pulling out an (a*b) to a temprary local variable, changes behavior, when they ought to be mathematically (as per IEEE) equivalent? How can the programmer know in advance if the runtime chooses to hold the float with "artificial" extra (64-bit) precision or not?
  5. Why are "optimizations" from compiling in Release mode allowed to change arithmetics?

(This was done in the 4.0 version of the .NET Framework.)

share|improve this question
1  
And this is why we should never check for floating point equality ;p –  leppie Sep 28 '12 at 17:41
    
@leppie Well, checking for "less than" or "greater than" (even after adding or subtracting some epsilon) also produces unpredictable results, in an entirely similar way. So when ever your program uses a floating-point variable somewhere, you can never know if the program does the same, consistently, because floating-point operations in the CLR are unpredictable? –  Jeppe Stig Nielsen Sep 28 '12 at 17:51
    
I was being slightly sarcastic. :) –  leppie Sep 28 '12 at 18:41

1 Answer 1

up vote 7 down vote accepted

I haven't checked your arithmetic, but I've certainly seen similar results before. As well as debug mode making a difference, assigning to a local variable vs an instance variable can make a difference too. This is legitimate as per section 4.1.6 of the C# 4 specification:

Floating point operations may be performed with higher precision than the result type of the operation. For example, some hardware architectures support an "extended" or "long double" floating point type with greater range and precision than the double type, and implicitly perform all floating point operations using this higher precision type. Only at excessive cost in performance can such hardware architectures be made to perform floating point operations with less precision. Rather than require an implementation to forfeit performance and precision, C# allows a higher precision type to be used for all floating point operations. Other than delivering more precise results, this rarely has any measurable effects. [...]

I can't say for sure whether that's what's going on here, but I wouldn't be surprised.

share|improve this answer
1  
That's exactly what's going on here. Since it conforms to the language specification, it's not a bug, though it is somewhat unfortunate (one could try to argue that it's a bug in the language specification). –  Stephen Canon Sep 28 '12 at 17:58
    
@StephenCanon I agree. The above quote (thanks, Jon, it was exactly what I asked for, item 2.) kind of says: "OK, we're not IEEE compliant after all; we use the precision of the hardware. We know it's not equivalent to IEEE, but we still do it." –  Jeppe Stig Nielsen Sep 28 '12 at 18:43
    
Jon, do you happen to also know the answer to "How can casting a float expression to the type float change anything?" Most programmers (and development tools) would think that cast was a no-op and remove it. Also, one could think that the compiler disregarded it. But it looks like this is some "secret" feature. Or is this also part of the C# Language Specification? –  Jeppe Stig Nielsen Sep 28 '12 at 18:47
    
@JeppeStigNielsen: Sorry, only just seen this. No idea about the casting bit. I think I could do with an example which just shows that to investigate further. –  Jon Skeet Oct 8 '12 at 21:19
    
It would be very nice if you would investigate this some more. But I have myself found some references for it. In the accepted answer of this SO question, Eric Lippert seems to confirm that casting a float to type float will change something. And in an old version of a text by you(!), it says in a parenthesis "Casting g to float [...] has the same effect, even though it looks like a no-op". The formulation is changed in later versions of your text, however. –  Jeppe Stig Nielsen Oct 8 '12 at 21:53

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