EDIT: Got it to work now, while normalizing the mantiss it is important to first set the implicit bit, when decoding the implicit bit then does not have to be added. I left the marked answer as correct, as the information there really helped.

I'm currently implementing an encoding (Distinguished encoding rules) and have a slight problem encoding double values.

So, I can get out the sign, exponent and mantissa from a double in c# by using:

```
// get parts
double value = 10.0;
long bits = BitConverter.DoubleToInt64Bits(value);
// Note that the shift is sign-extended, hence the test against -1 not 1
bool negative = (bits < 0);
int exponent = (int)((bits >> 52) & 0x7ffL);
long mantissa = bits & 0xfffffffffffffL;
```

(using code from here). These values can be encoded and a simple reversal of the process will get me back the original double.

However, the DER encoding rules specify that the mantissa should be normalized:

In the Canonical Encoding Rules and the Distinguished Encoding Rules normalization is specified and the mantissa (unless it is 0) needs to be repeatedly shifted until the least significant bit is a 1.

(see here in section 8.5.6.5).

Doing this by hand using:

```
while ((mantissa & 1) == 0)
{
mantissa >>= 1;
exponent++;
}
```

will not work, and gives me strange values. (Even when using the whole function Jon Skeet posted in the aforementioned link).

I seem to be missing something here, it would be easiest if I first could normalize the mantiassa of the double and the get the "bits". However, I also can't really see why the normalization by hand won't work correctly.

Thanks for any help,

Danny

EDIT: Actual working problem showing my issue with mantiss normalization:

```
static void Main(string[] args)
{
Console.WriteLine(CalculateDouble(GetBits(55.5, false)));
Console.WriteLine(CalculateDouble(GetBits(55.5, true)));
Console.ReadLine();
}
private static double CalculateDouble(Tuple<bool, int, long> bits)
{
double result = 0;
bool isNegative = bits.Item1;
int exponent = bits.Item2;
long significand = bits.Item3;
if (exponent == 2047 && significand != 0)
{
// special case
}
else if (exponent == 2047 && significand == 0)
{
result = isNegative ? double.NegativeInfinity : double.PositiveInfinity;
}
else if (exponent == 0)
{
// special case, subnormal numbers
}
else
{
/* old code, wont work double actualSignificand = significand*Math.Pow(2,
-52) + 1; */
double actualSignificand = significand*Math.Pow(2, -52);
int actualExponent = exponent - 1023;
if (isNegative)
{
result = actualSignificand*Math.Pow(2, actualExponent);
}
else
{
result = -actualSignificand*Math.Pow(2, actualExponent);**strong text**
}
}
return result;
}
private static Tuple<bool, int, long> GetBits(double d, bool normalizeSignificand)
{
// Translate the double into sign, exponent and mantissa.
long bits = BitConverter.DoubleToInt64Bits(d);
// Note that the shift is sign-extended, hence the test against -1 not 1
bool negative = (bits < 0);
int exponent = (int)((bits >> 52) & 0x7ffL);
long significand = bits & 0xfffffffffffffL;
if (significand == 0)
{
return Tuple.Create<bool, int, long>(false, 0, 0);
}
// fix: add implicit bit before normalization
if (exponent != 0)
{
significand = significand | (1L << 52);
}
if (normalizeSignificand)
{
//* Normalize */
while ((significand & 1) == 0)
{
/* i.e., Mantissa is even */
significand >>= 1;
exponent++;
}
}
return Tuple.Create(negative, exponent, significand);
}
Output:
55.5
2.25179981368527E+15
```