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I have been going crazy trying to read a binary file that was written using a Java program (I am porting a Java library to C# and want to maintain compatibility with the Java version).

Java Library

The author of the component chose to use a float along with multiplication to determine the start/end offsets of a piece of data. Unfortunately, there are differences in the way it works in .NET than from Java. In Java, the library uses Float.intBitsToFloat(someInt) where the value of someInt is 1080001175.

int someInt = 1080001175;
float result = Float.intBitsToFloat(someInt);
// result (as viewed in Eclipse): 3.4923456

Later, this number is multiplied by a value to determine start and end position. In this case, the problem occurs when the index value is 2025.

int idx = 2025;
long result2 = (long)(idx * result);
// result2: 7072

According to my calculator, the result of this calculation should be 7071.99984. But in Java it is exactly 7072 before it is cast to a long, in which case it is still 7072. In order for the factor to be exactly 7072, the value of the float would have to be 3.492345679012346.

Is it safe to assume the value of the float is actually 3.492345679012346 instead of 3.4923456 (the value shown in Eclipse)?

.NET Equivalent

Now, I am searching for a way to get the exact same result in .NET. But so far, I have only been able to read this one file using a hack, and I am not entirely certain the hack will work for any file that is generated by the library in Java.

According to intBitsToFloat method in Java VS C#?, the equivalent functionality is using:

int someInt = 1080001175;
int result = BitConverter.ToSingle(BitConverter.GetBytes(someInt), 0);
// result: 3.49234557

This makes the calculation:

int idx = 2025;
long result2 = (long)(idx * result);
// result2: 7071

The result before casting to long is 7071.99977925, which is shy of the 7072 value that Java yields.

What I Tried

From there, I assumed that there must be some difference in the math between Float.intBitsToFloat(someInt) and BitConverter.ToSingle(BitConverter.GetBytes(value), 0) to receive such different results. So, I consulted the javadocs for intBitsToFloat(int) to see if I can reproduce the Java results in .NET. I ended up with:

public static float Int32BitsToSingle(int value)
{
    if (value == 0x7f800000)
    {
        return float.PositiveInfinity;
    }
    else if ((uint)value == 0xff800000)
    {
        return float.NegativeInfinity;
    }
    else if ((value >= 0x7f800001 && value <= 0x7fffffff) || ((uint)value >= 0xff800001 && (uint)value <= 0xffffffff))
    {
        return float.NaN;
    }

    int bits = value;
    int s = ((bits >> 31) == 0) ? 1 : -1;
    int e = ((bits >> 23) & 0xff);
    int m = (e == 0) ? (bits & 0x7fffff) >> 1 : (bits & 0x7fffff) | 0x800000;
    
    //double r = (s * m * Math.Pow(2, e - 150));
    // value of r: 3.4923455715179443
    
    float result = (float)(s * m * Math.Pow(2, e - 150));
    // value of result: 3.49234557
    
    return result;
}

As you can see, the result is exactly the same as when using BitConverter, and before casting to a float the number is quite a bit lower (3.4923455715179443) than the presumed Java value of (3.492345679012346) that is needed for the result to be exactly 7072.

I tried this solution, but the resultant value is exactly the same, 3.49234557.

I also tried rounding and truncating, but of course that makes all of the other values that are not very close to the whole number wrong.

I was able to hack through this by changing the calculation when the float value is within a certain range of a whole number, but as there could be other places where the calculation is very close to the whole number, this solution probably won't work universally.

float avg = (idx * averages[block]);
avgValue = (long)avg; // yields 7071
if ((avgValue + 1) - avg < 0.0001)
{
    avgValue = Convert.ToInt64(avg); // yields 7072
}

Note that the Convert.ToInt64 function doesn't work in most cases either, but it has the effect of rounding in this particular case.

Question

How can I make a function in .NET that returns exactly the same result as Float.intBitsToFloat(int) in Java? Or, how can I otherwise normalize the differences in float calculation so this result is 7072 (not 7071) given the values 1080001175 and 2025?

Note: It should work the same as Java for all other possible integer values as well. The above case is just one of potentially many places where the calculation is different in .NET.

I am using .NET Framework 4.5.1 and .NET Standard 1.5 and it should produce the same results in both x86 and x64 environments.

8
  • intBitsToFloat is a native method which calls Java_java_lang_Float_intBitsToFloat method in C, see Float.c contents. It converts jint to long and returns jfloat, which jfloat itself may use different rounding mechanism compared with System.Single. More strange, resulted float in C# rounded down during conversion to long using same code as Java implementation. – Tetsuya Yamamoto May 16 '17 at 6:37
  • I had problems rounding down, also. However, I was able to work around using (long)BigInteger.Divide(BigInteger.Multiply(new BigInteger(idx), new BigInteger(10000000 * averages[block])), new BigInteger(10000000)). If there is some way to call the native C function in .NET, that might go a long way toward solving this. – NightOwl888 May 16 '17 at 6:49
  • Would Math.Ceiling or Math.Floor help in this case as it would always yield the next higher / lower Integer respectively. (long)Math.Ceiling(7071.1) yields 7072 always – Mrinal Kamboj May 16 '17 at 6:51
  • 1
    Just do this instead in .NET: long result2 = (long)(float)(idx * result); It adds a conv.r4 opcode in the generated IL and so forces a float realization somewhere in the computation stack (even Visual Studio reports this as an "unnecessary cast"...). I suppose it's a jit optimization. Maybe a bug? I doesn't happen if you compile for .NET 2.0... – Simon Mourier May 16 '17 at 7:08
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    @SimonMourier - I tried the cast (long)(float)(idx * result); and it appears to solve this. I need to do some more testing to verify it works across x86 and x64 in .NET 4.5.1 and .NET Standard 1.5, but this looks promising. Please add your comment as an answer so I can accept if this solution works. – NightOwl888 May 16 '17 at 7:39
5

The definition of 4-byte floating point number in C# and Java (and any other decent programming platform) is based on IEEE standards, so the binary format is the same.

So, it should work. And in fact it does work, but only for X64 targets (my earlier comments about .NET 2 and 4 may be wrong or right, I can't really test old platform binaries).

If you want it to work for all targets, you'll have to define it like this:

long result2 = (long)(float)(idx * result);

If you look at the generated IL, it adds a supplemental conv.r4 opcode after the multiplication. I guess this forces a float number realization in the compiled x86 code. I suppose it's a jit optimization issue.

I don't know enough about jit optimization to determine if it's a bug or not. The funny thing is the Visual Studio 2017 IDE even grays the cast (float) text and reports that cast as "redundant" or "unnecessary", so it doesn't smell good.

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-1

FYI - Now added directly in .net.

int myFloat = BitConverter.Int32BitsToSingle( myInt );

So... (as in the question)

int someInt = 1080001175;
float result = BitConverter.Int32BitsToSingle(someInt);

Returns 3.49234557 (almost the same as Eclipse)

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