Do different x86 CPUs (with build-in FPUs and reasonably recent, say launched this millenium) produce *exactly* the same result for their Floating Point primitives, assuming the same instruction is available on the CPUs being compared, same input and same operating parameters such as rounding mode? I'm not interested in differences in timing, nor in the Pentium FDIV bug (which does not qualify only because that incident is ancient).

I guess the answer is yes for addition, subtraction, negation, and round-to-integer, since these have precise definitions, and I can hardly imagine what a divergence in implementations could be (short perhaps of a bug in the detection of overflow/underflow, but that would be a disaster in some applications, so I imagine this would have been caught and fixed long ago).

Multiplication seems more likely to have diverging implementations: determining the (say) nearest representable Double-Precision Float-Point Number (64 bits, including 52+1 of mantissa) of the product of two DPFPN sometime requires computing the product of their mantissa to (about) 104-bit accuracy, which, for the few LSBits, is arguably a waste of effort. I wonder if this is even attempted, and done correctly. Or perhaps IEEE-754, or some de-facto standard, prescribes something?

Division seems even more delicate.

And, short of a common design, I doubt all implementations of the much more complex things (trig functions, logs..) could be exactly in sync, given the variety of mathematical methods that can be used.

I'm asking that out of a combination of pure nosiness; willingness to improve that answer of mine; and desire for a method to (sometime) allow a program running in a VM to detect a mismatch between the CPU that pretends to be running, and the real one.

verydifficult to optimize for in a consistent way. Big reason compilers have been moving to SSE2. – Hans Passant Oct 27 '12 at 18:00