If we execute the following C# code on a console application, we will get a message as The sums are Not equal.

If we execute it after uncommenting the line System.Console.WriteLine(), we will get a message as The sums are equal.

    static void Main(string[] args)
        float f = Sum(0.1f, 0.2f);
        float g = Sum(0.1f, 0.2f);

        //System.Console.WriteLine("f = " + f + " and g = " + g);

        if (f == g)
            System.Console.WriteLine("The sums are equal");
            System.Console.WriteLine("The sums are Not equal");

    static float Sum(float a, float b)
        System.Console.WriteLine(a + b);
        return a + b;

What is the actual reason for this behavior?

  • 4
    I have an inkling about this in general, but I don't understand why uncommenting that line would have that effect, as it's doing the same thing to both variables. It may well vary by processor type too, btw.
    – Jon Skeet
    Jun 20 '14 at 6:34
  • 5
    I've reproduced the problem on my machine - building and running from the command line with csc /o+ /debug- /platform:x86 Test.cs. It may well still vary by subtle things like CLR version etc though.
    – Jon Skeet
    Jun 20 '14 at 6:40
  • 7
    That's why doubles should always be compared with Math.Abs(a - b) < epsilon, where epsilon is required precision. True then a equal b, with reqired precision.
    – Atomosk
    Jun 20 '14 at 6:50
  • 10
    @RudyVelthuis: Your statement that the results should be the same when given the same arguments is a moral statement. Yes, that it how the world should be. That is not the world that Intel gave us. The CLR jitter can choose entirely at its whim whether to keep intermediate results in high-precision registers vs low-precision stack or heap locations, and doing so can and does change the results of equalities like this one. If you think that's morally wrong, complain to Intel for giving us a chipset where precision differs based on storage location. Jun 20 '14 at 17:00
  • 13
    @AK_: This is not a bug. This is documented, specified behaviour that is the unfortunate consequence of decisions made by the chip designers. The C# and CLR specifications both call out that this behaviour is possible, so it is not a bug. Don't complain to Microsoft; there's nothing Microsoft can do about it without wrecking performance of all floating point operations. The company to complain to is Intel. Jun 20 '14 at 17:03

It's not related to scope. It's the combination of the stack dynamics and floating point handling. Some knowledge of compilers will help make this counterintuitive behavior clear.

When the Console.WriteLine is commented, the values f and g are on the evaluation stack and stay there until after you've passed the equality test in your Main method.

When Console.Writeline is not commented, the values f and g are moved from the evaluation stack to the call stack at the moment of the invocation, to be restored to the evaluation stack when Console.WriteLine returns. And your comparison if (f == g) is done afterwards. Some rounding can occur during this storing of values to the call stack and some information can be lost.

In the scenario where you do invoke Console.WriteLine, the f and the g in the comparison test are not the same values. They've been copied and restored to a format that has different rules on precision and rounding, by the virtual machine.

In your particular code, when the invocation of Console.WriteLine is commented, the evaluation stack is never stored to the call stack and no rounding occurs. Because it is permitted for implementations of the platform to provide improved precision on the evaluation stack, this discrepancy can arise.

EDIT What we're hitting in this case is allowed by the CLI specification. In section I.12.1.3 it reads:

Storage locations for floating-point numbers (statics, array elements, and fields of classes) are of fixed size. The supported storage sizes are float32 and float64. Everywhere else (on the evaluation stack, as arguments, as return types, and as local variables) floating-point numbers are represented using an internal floating-point type. In each such instance, the nominal type of the variable or expression is either float32or float64, but its value can be represented internally with additional range and/or precision. The size of the internal floating-point representation is implementation-dependent, can vary, and shall have precision at least as great as that of the variable or expression being represented.

The keywords from this quote are "implementation-dependent" and "can vary". In the OP's case, we see his implementation does indeed vary.

Non-strictfp floating point arithmetic in the Java platform also has a related issue, for more info check also my answer to Will floating point operations on the JVM give the same results on all platforms?

  • 3
    But even so, even if they are stored and stored back, and even if rouding takes place when that happens, since they are exactly the same values, the rounded values should still be the same, right? Or is there a random element in rounding in C#? Jun 20 '14 at 14:59
  • 1
    I now see that, due to how the compiler and runtime work, only one value might lose information, and the other doesn't (see Jon Skeet's answer). That could explain the difference. If both are moved around and rounded, they should be rounded exactly the same way, so even after the loss of precision, their values should still be the same. But if only one is treated that way and not the other, a difference can result. I still don't think that a compiler/runtime, no matter which, should do this. Jun 20 '14 at 15:14
  • 2
    @Rudy Basically x86 uses an 80-bit internal format (which is a good thing^TM) which consequently mean it'd be actually rather expensive and bad for accuracy to force you to keep all intermediate results in IEEE format. And that for something that's basically broken anyhow (don't compare floats for equivalence and you're good to go). Floating point arithmetic is counterintuitive in even the best situations one more or less really doesn't make a difference.
    – Voo
    Jun 20 '14 at 18:43
  • 1
    @Voo: There are numerous downsides. Suppose you are writing a game engine which uses floats. You have the initial state of the game. Sixty times a second the engine consumes the latest user input and the current game state to produce the next game state. Since we have no guarantee that a decision like "did the bullet hit the target?" is ever computed the same way twice, this means that you cannot "play back" the sequence of inputs against the engine and get the same result in the game. Jun 20 '14 at 20:31
  • 1
    @Voo: The downside is that many algorithms like Kahan summation work by computing the difference between the amount by which a variable changed when something was added to it, and the size of the thing added. If computing newTotal = delta+oldTotal+nextItem; delta += nextItem-(newTotal-oldTotal), it is absolutely imperative that (newTotal - oldTotal) reflect the amount by which newTotal actually changed. Having (newTotal-oldTotal) reflect the amount by which it should have changed is disastrous.
    – supercat
    Jun 20 '14 at 20:32

What is the actual reason for this behaviour?

I can't provide details for exactly what's going on in this specific case, but I understand the general problem, and why using Console.WriteLine can change things.

As we saw in your previous post, sometimes operations are performed on floating point types at a higher precision than the one specified in the variable type. For local variables, that can include how the value is stored in memory during the execution of a method.

I suspect that in your case:

  • the Sum method is being inlined (but see later)
  • the sum itself is being performed with greater precision than the 32-bit float you'd expect
  • the value of one of the variables (f say) is being stored in a high-precision register
    • for this variable, the "more precise" result is being stored directly
  • the value of the other variable (g) is being stored on the stack as a 32-bit value
    • for this variable, the "more precise" result is being reduced to 32 bits
  • when the comparison is performed, the variable on the stack is being promoted to a higher-precision value and compared with the other higher-precision value, and the difference is due to one of them having previously lost information and the other not

When you uncomment the Console.WriteLine statement, I'm guessing that (for whatever reason) forces both variables to be stored in their "proper" 32-bit precision, so they're both being treated the same way.

This hypothesis is all somewhat messed up by the fact that adding


... does not change the result as far as I can see. I may be doing something else wrong along those lines though.

Really, we should look at the assembly code which is executing - I don't have the time to do that now, unfortunately.

  • This looks like JIT bug. Both results have the same bit pattern, but the issue can only be reproduced if at most one of f and g are referenced.
    – leppie
    Jun 20 '14 at 7:13
  • Changing Sum to return a double also 'fixes' the issue.
    – leppie
    Jun 20 '14 at 7:22
  • 2
    David Monniaux wrote an article about why this and more insidious behaviors happen. It is in the context of C, and reflects the state of standard-compliance of C compilers at the time (the situation has improved since), but I think it is still a good read in the context of this question: arxiv.org/abs/cs/0701192 Jun 20 '14 at 7:24
  • @PascalCuoq: Thanks. I'll read up on it when I get a chance :)
    – Jon Skeet
    Jun 20 '14 at 8:17
  • Is this behavior specific to C#, or can this type of promoting also happen in a language like C, C++, Java? Jun 20 '14 at 14:02

(Not a real answer but hopefully some supporting documentation)

Configuration: Core i7, Windows 8.1, Visual Studio 2013

Platform x86:

Version      Optimized Code?        Debugger Enabled?          Outcome
4.5.1        Yes                    No                         Not equal
4.5.1        Yes                    Yes                        Equal
4.5.1        No                     No                         Equal
4.5.1        No                     Yes                        Equal
2.0          Yes                    No                         Not Equal
2.0          Yes                    Yes                        Equal
2.0          No                     No                         Equal
2.0          No                     Yes                        Equal

Platform x64:

Version      Optimized Code?        Debugger Enabled?          Outcome
4.5.1        Yes                    No                         Equal
4.5.1        Yes                    Yes                        Equal
4.5.1        No                     No                         Equal
4.5.1        No                     Yes                        Equal
2.0          Yes                    No                         Equal
2.0          Yes                    Yes                        Equal
2.0          No                     No                         Equal
2.0          No                     Yes                        Equal

The situation only seems to occur with optimized code on x86 configurations.

  • I confirm on a similar platform (i5, Win8.1, VS2013) that the only conditions I can get Not Equal is with Release builds without debugger. This happens in AnyCPU configuration when "Prefer 32bit" is checked or in x86, but not in x64 or when unchecked. Jun 20 '14 at 6:52

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