I am trying to convert an 80-bit extended precision floating point number (in a buffer) to double. The buffer basically contains the content of an x87 register.
This question helped me get started as I wasn't all that familiar with the IEEE standard. Anyway, I am struggling to find useful info on subnormal (or denormalized) numbers in the 80-bit format. What I know is that unlike float32 or float64 it doesn't have a hidden bit in the mantissa (no implied addition of 1.0), so one way to know if a number is normalized is to check if the highest bit in the mantissa is set. That leaves me with the following question:
From what wikipedia tells me, float32 and float64 indicate a subnormal number with a (biased) exponent of 0 and a non-zero mantissa.
- What does that tell me in an 80-bit float?
- Can 80-bit floats with a mantissa < 1.0 even have a non-zero exponent?
- Alternatively, can 80-bit floats with an exponent of 0 even have a mantissa >= 1.0?
EDIT: I guess the question boils down to:
Can I expect the FPU to sanitize exponent and highest mantissa bit in x87 registers?
If not, what kind of number should the conversion result in? Should I ignore the exponent altogether in that case? Or is it qNaN?
I read the FPU section in the Intel manual (Intel® 64 and IA-32 Architectures Software Developer’s Manual, Volume 1: Basic Architecture) which was less scary than I had feared. As it turns out the following values are not defined:
- exponent == 0 + mantissa with the highest bit set
- exponent != 0 + mantissa without the highest bit set
It doesn't mention if these values can appear in the wild, nor if they are internally converted. So I actually dusted off Ollydbg and manually set bits in the x87 registers. I crafted ST(0) to contain all bits set in the exponent and a mantissa of 0. Then I made it execute
FSTP QWORD [ESP] FLD QWORD [ESP]
The value stored at
[ESP] was converted to a signaling NaN.
ST(0) contained a quiet NaN.
I guess that answers my question. I accepted J-16 SDiZ's solution because it's the most straight forward solution (although it doesn't explicitly explain some of the finer details).
Anyway, case solved. Thanks, everybody.