Consider, for entertainment purposes only:
Only 2 floating point values compare equal to
0f: zero and negative zero, and they differ only at 1 bit. So circuitry/software emulation that tests whether the 31 non-sign bits are clear will do it.
>0f is slightly more complicated, since negative numbers and 0 result in false, positive numbers result in true, but NaNs (of both signs) also result in false, so it's slightly more than just checking the sign bit.
Depending on the floating point mode, either operation could cause a super-precise result in a floating point register to be rounded to 32 bit before comparison, so the score's even there.
If there was a difference at all, I'd sort of expect
!= to be faster, but I wouldn't really expect there to be a difference and I wouldn't be very surprised to be wrong on some particular implementation.
I assume that your proof that the value cannot be negative is not subject to floating point errors. For example, calculations along the lines of
1/2.0 - 1/3.0 - 1/6.0 or
0.4 - 0.2 - 0.2 can result in either positive or negative values if the errors happen to accumulate rather than cancelling, so presumably nothing like that is going on. About only real use of a floating-point test for equality with 0, is to test whether you have assigned a literal
0 to it. Or the result of some other calculation guaranteed to have result
float, but that can be tricksy.