Refreshing on floating points (also PDF), IEEE-754 and taking part in this discussion on floating point rounding when converting to strings, brought me to tinker: how can I get the maximum and minimum value for a given floating point number whose binary representations are equal.

**Disclaimer**: for this discussion, I like to stick to 32 bit and 64 bit floating point as described by IEEE-754. I'm not interested in extended floating point (80-bits) or quads (128 bits IEEE-754-2008) or any other standard (IEEE-854).

**Background**: Computers are bad at representing `0.1`

in binary representation. In C#, a float represents this as `3DCCCCCD`

internally (C# uses round-to-nearest) and a double as `3FB999999999999A`

. The same bit patterns are used for decimal `0.100000005`

(float) and `0.1000000000000000124`

(double), but not for `0.1000000000000000144`

(double).

For convenience, the following C# code gives these internal representations:

```
string GetHex(float f)
{
return BitConverter.ToUInt32(BitConverter.GetBytes(f), 0).ToString("X");
}
string GetHex(double d)
{
return BitConverter.ToUInt64(BitConverter.GetBytes(d), 0).ToString("X");
}
// float
Console.WriteLine(GetHex(0.1F));
// double
Console.WriteLine(GetHex(0.1));
```

In the case of `0.1`

, there is no lower decimal number that is represented with the same bit pattern, any `0.99...99`

will yield a different bit representation (i.e., float for `0.999999937`

yields `3F7FFFFF`

internally).

**My question** is simple: how can I find the lowest and highest decimal value for a given float (or double) that is internally stored in the same binary representation.

**Why**: (I know you'll ask) to find the error in rounding in .NET when it converts to a string and when it converts from a string, to find the internal exact value and to understand my own rounding errors better.

My guess is something like: take the mantissa, remove the rest, get its exact value, get one (mantissa-bit) higher, and calculate the mean: anything below that will yield the same bit pattern. My main problem is: how to get the fractional part as integer (bit manipulation it not my strongest asset). Jon Skeet's DoubleConverter class may be helpful.