I too find incorrect results distasteful.
On common hardware, you can rely on +
, -
, *
, /
, and sqrt
working and delivering the correctly-rounded result. That is, they deliver the floating-point number closest to the sum, difference, product, quotient, or square root of their argument or arguments.
Some library functions, notably log2
and log10
and exp2
and exp10
, traditionally have terrible implementations that are not even faithfully-rounded. Faithfully-rounded means that a function delivers one of the two floating-point numbers bracketing the exact result. Most modern pow
implementations have similar issues. Lots of these functions will even blow exact cases like log10(10000)
and pow(7, 2)
. Thus equality comparisons involving these functions, even in exact cases, are asking for trouble.
sin
, cos
, tan
, atan
, exp
, and log
have faithfully-rounded implementations on every platform I've recently encountered. In the bad old days, on processors using the x87 FPU to evaluate sin
, cos
, and tan
, you would get horribly wrong outputs for largish inputs and you'd get the input back for larger inputs. CRlibm has correctly-rounded implementations; these are not mainstream because, I'm told, they've got rather nastier worst cases than the traditional faithfully-rounded implementations.
Things like copysign
and nextafter
and isfinite
all work correctly. ceil
and floor
and rint
and friends always deliver the exact result. fmod
and friends do too. frexp
and friends work. fmin
and fmax
work.
Someone thought it would be a brilliant idea to make fma(x,y,z)
compute x*y+z
by computing x*y
rounded to a double
, then adding z
and rounding the result to a double
. You can find this behaviour on modern platforms. It's stupid and I hate it.
I have no experience with the hyperbolic trig, gamma, or Bessel functions in my C library.
I should also mention that popular compilers targeting 32-bit x86 play by a different, broken, set of rules. Since the x87 is the only supported floating-point instruction set and all x87 arithmetic is done with an extended exponent, computations that would induce an underflow or overflow in double precision may fail to underflow or overflow. Furthermore, since the x87 also by default uses an extended significand, you may not get the results you're looking for. Worse still, compilers will sometimes spill intermediate results to variables of lower precision, so you can't even rely on your calculations with double
s being done in extended precision. (Java has a trick for doing 64-bit math with 80-bit registers, but it is quite expensive.)
I would recommend sticking to arithmetic on long double
s if you're targeting 32-bit x86. Compilers are supposed to set FLT_EVAL_METHOD
to an appropriate value, but I do not know if this is done universally.