I have some files with floating point values in them that I'm having problems figuring out their exact encoding. I've tried several ways to convert to a standard double value, but haven't had much luck. I know what the values are supposed to convert to, but need a method to extract directly from the files.

These are HP-1000 (HP21xx) series floating point values. Similar to 48 bit Pascal, but not the same.

Other than some old, unreliable documentation (couldn't get a conversion using what it claimed was the format), and a list of formats from quadibloc.com I have found nothing else. Format from quadibloc gives the following:

```
(Note, big-endian order)
MSb: mantissa sign (says it's 2s complement)
39 bits: mantissa
7 bits: exponent
1 bit: exponent sign
```

The other documentation isn't clear, but seems to say it's all 2s complement. I've tried the Pascal conversion code I found, but it doesn't even come close. (after moving the exponent sign to high bit of the byte).

Examples, converted using a PPC that emulates an HP-1000:

```
A7EB851EB90A -22.02
A870A3D70A0A -21.89
A8AE147AE20A -21.83
A8E147AE140A -21.78
A9666666670A -21.65
AC70A3D70A0A -20.89
ACC28F5C290A -20.81
ACCCCCCCCC0A -20.8
AE70A3D70B0A -20.39
AEB851EB850A -20.32
```

This was from only one file. I have at least 100 of these files to extract from.

Any ideas? Sure would be appreciated.

Edit: I guess I should have said what language I am working in. In this case, it's C#. As for additional data, I have a ton of it. More examples here, these include negative exponents, at least when converted to decimal.

```
400000000002 1
43851EB85204 2.11
451EB851EB04 2.16
4C7AE147AE04 2.39
4EC4EC4EC5F3 4.8076923077E-03
519999999A04 2.55
5838B6BE9BF3 5.3846153846E-03
5B851EB85202 1.43
5BD70A3D7108 11.48
5C7AE147AE08 11.56
5E51EB851E08 11.79
5FD70A3D7108 11.98
62E147AE1508 12.36
64A3D70A3E08 12.58
666666666702 1.6
67AE147AE202 1.62
6B204B9E54F3 6.5384615385E-03
733333333302 1.8
762762762AF3 7.2115384616E-03
794DFB4619F3 7.4038461538E-03
7C74941627F3 7.5961538465E-03
7E07E07E14F3 7.6923076925E-03
```

Should have included positive numbers before.

Tried the suggestions, but in C#. Wildly different results. I even split out the bits of the calculations, but I get very high numbers compared to the numbers given in the suggestions. Here's the code with the bits expanded.

```
Int64[] test_data = new Int64[] {
0xA7EB851EB90A, 0xA870A3D70A0A, 0xA8AE147AE20A, 0xA8E147AE140A,
0xA9666666670A, 0xAC70A3D70A0A, 0xACC28F5C290A, 0xACCCCCCCCC0A,
0xAE70A3D70B0A, 0xAEB851EB850A, 0x400000000002, 0x43851EB85204,
0x451EB851EB04, 0x4C7AE147AE04, 0x4EC4EC4EC5F3, 0x519999999A04,
0x5838B6BE9BF3, 0x5B851EB85202, 0x5BD70A3D7108, 0x5C7AE147AE08,
0x5E51EB851E08, 0x5FD70A3D7108, 0x62E147AE1508, 0x64A3D70A3E08,
0x666666666702, 0x67AE147AE202, 0x6B204B9E54F3, 0x733333333302,
0x762762762AF3, 0x794DFB4619F3, 0x7C74941627F3, 0x7E07E07E14F3
};
private void Checkit()
{
Byte[] td = new Byte[6]; // 6 byte array for reversed data
Byte[] ld = new Byte[8]; // 8 byte conversion array
for (Int32 i = 0; i < test_data.Length; i++) // Loop through data
{
ld = BitConverter.GetBytes(test_data[i]); // Get value as byte array
for (Int32 j = 0; j < 6; j++) // Copy the bytes in reverse
td[5 - j] = ld[j];
// Go test them
Console.WriteLine("{0:X6} --> {1:E}", test_data[i], Real48ToDouble(ref td));
}
}
Double Real48ToDouble(ref Byte[] realValue)
{
// Values are using input value of A7EB851EB90A and 7E07E07E14F3
if (realValue[0] == 0)
return 0.0; // Null exponent = 0
Byte[] b = new Byte[8] { 0, 0, 0, 0, 0, 0, 0, 0 }; // 64 bit byte array
for (Int32 i = 0; i < 5; i++) // Copy over the 48 bit info
b[4 - i] = realValue[i];
Int64 mant = BitConverter.ToInt64(b, 0); // 0x000000A7EB851EB9 - Get mantissa with sign
// 0x0000007E07E07E14
Int32 expo = realValue[5]; // 0x0000000A - Grab the exponent
// 0x000000F3
Int32 mant_sign = (Int32)(mant >> 39); // 0x00000001
// 0x00000000
// sign extend mantissa from 40 to 64 bits, then take absolute value
mant = (Int64)((mant ^ (1L << 39)) - (1L << 39)); // 0xFFFFFFA7EB851EB9 - First calc
// 0x0000007E07E07E14
mant = Math.Abs(mant); // 0x00000058147AE147 - Make absolute
// 0x0000007E07E07E14
// convert mantissa to floating-point
Double fmant = mant * Math.Pow(2, -39.0); // 0.68812499999876309 - Second calc
// 0.98461538463743636
// rotate exponent field right by 1 bit
expo = (expo >> 1) | ((expo & 1) << 7); // 0x00000005
// 0x000000F9
// sign extend exponent from 8 to 32 bits
expo = ((expo ^ (1 << 7)) - (1 << 7)); // 0x00000005
// 0xFFFFFFF9
// compute scale factor from exponent field
Double scale = Math.Pow(2, expo); // 32.0 - Scale
// 0.0078125
// scale mantissa, and apply sign bit for final result
Double num = fmant * scale; // 22.019999999960419 - Make the final abs number
// 0.0076923076924799716
return (mant_sign != 0) ? (-num) : num; // -22.019999999960419 - Return with sign
// 0.0076923076924799716
}
```

Changed code above The code above is now working correctly.

A floating-point number began with a two's complement mantissa, and then ended with seven bits of exponent, followed by the sign of the exponent, neither of which was complemented when the number was negative. Floating-point numbers could occupy either two or three 16-bit words, depending on whether they were single or double precision.`ACCCC...`

as a two's complement number. The problem I have is figuring out how the last byte`0A`

maps to the exponent. Do you have additional example values from a different binade? That would presumably clarify the exponent encoding.fivebytes" represent the two's complement mantissa. So the value is (`0xACCCCCCCCC`

/ 2^39) * 2^expo.`0A`

corresponds to exponent of`0x0A`

/2 = 10/2 = 5. Altogether: (0xacccccccc / 2^40) * 2^5 = -0.65 * 2^5 = -20.8. Sorry, I can't provide Pascal code, I am no longer fluent (it's been decades since I last used it). But I think the decoding is clear now.12more comments