You can write
assert(x*x >= 0.f) as a compile-time promise instead of a runtime check as follows in GNU C:
float test1 (float x)
float tmp = x*x;
if (!(tmp >= 0.0f))
(related: What optimizations does __builtin_unreachable facilitate? You could also wrap
if(!x)__builtin_unreachable() in a macro and call it
promise() or something.)
But gcc doesn't know how to take advantage of that promise that
tmp is non-NaN and non-negative. We still get (Godbolt) the same canned asm sequence that checks for
x>=0 and otherwise calls
sqrtf to set
errno. Presumably that expansion into a compare-and-branch happens after other optimization passes, so it doesn't help for the compiler to know more.
This is a missed-optimization in the logic that speculatively inlines
-fmath-errno is enabled (on by default unfortunately).
What you want instead is
-fno-math-errno, which is safe globally
This is 100% safe if you don't rely on math functions ever setting
errno. Nobody wants that, that's what NaN propagation and/or sticky flags that record masked FP exceptions are for. e.g. C99/C++11
fenv access via
#pragma STDC FENV_ACCESS ON and then functions like
fetestexcept(). See the example in
feclearexcept which shows using it to detect division by zero.
The FP environment is part of thread context while
errno is global.
Support for this obsolete misfeature is not free; you should just turn it off unless you have old code that was written to use it. Don't use it in new code: use
fenv. Ideally support for
-fmath-errno would be as cheap as possible but the rarity of anyone actually using
__builtin_unreachable() or other things to rule out a NaN input presumably made it not worth developer's time to implement the optimization. Still, you could report a missed-optimization bug if you wanted.
Real-world FPU hardware does in fact have these sticky flags that stay set until cleared, e.g. x86's
mxcsr status/control register for SSE/AVX math, or hardware FPUs in other ISAs. On hardware where the FPU can detect exceptions, a quality C++ implementation will support stuff like
fetestexcept(). And if not, then math-
errno probably doesn't work either.
errno for math was an old obsolete design that C / C++ is still stuck with by default, and is now widely considered a bad idea. It makes it harder for compilers to inline math functions efficiently. Or maybe we're not as stuck with it as I thought: Why errno is not set to EDOM even sqrt takes out of domain arguement? explains that setting errno in math functions is optional in ISO C11, and an implementation can indicate whether they do it or not. Presumably in C++ as well.
It's a big mistake to lump
-fno-math-errno in with value-changing optimizations like
-ffinite-math-only. You should strongly consider enabling it globally, or at least for the whole file containing this function.
float test2 (float x)
# g++ -fno-math-errno -std=gnu++17 -O3
test2(float): # and test1 is the same
mulss xmm0, xmm0
sqrtss xmm0, xmm0
You might as well use
-fno-trapping-math as well, if you aren't ever going to unmask any FP exceptions with
feenableexcept(). (Although that option isn't required for this optimization, it's only the
errno-setting crap that's a problem here.).
-fno-trapping-math doesn't assume no-NaN or anything, it only assumes that FP exceptions like Invalid or Inexact won't ever actually invoke a signal handler instead of producing NaN or a rounded result.
-ftrapping-math is the default but it's broken and "never worked" according to GCC dev Marc Glisse. (Even with it on, GCC does some optimizations which can change the number of exceptions that would be raised from zero to non-zero or vice versa. And it blocks some safe optimizations). But unfortunately, https://gcc.gnu.org/bugzilla/show_bug.cgi?id=54192 (make it off by default) is still open.
If you actually ever did unmask exceptions, it might be better to have
-ftrapping-math, but again it's very rare that you'd ever want that instead of just checking flags after some math operations, or checking for NaN. And it doesn't actually preserve exact exception semantics anyway.
See SIMD for float threshold operation for a case where
-fno-trapping-math incorrectly blocks a safe optimization. (Even after hoisting a potentially-trapping operation so the C does it unconditionally, gcc makes non-vectorized asm that does it conditionally! So not only does it block vectorization, it changes the exception semantics vs. the C abstract machine.)