I understand gcc's --ffast-math flag can greatly increase speed for float ops, and goes outside of IEEE standards, but I can't seem to find information on what is really happening when it's on. Can anyone please explain some of the details and maybe give a clear example of how something would change if the flag was on or off?

I did try digging through S.O. for similar questions but couldn't find anything explaining the workings of ffast-math.

2 Answers 2


-ffast-math does a lot more than just break strict IEEE compliance.

First of all, of course, it does break strict IEEE compliance, allowing e.g. the reordering of instructions to something which is mathematically the same (ideally) but not exactly the same in floating point.

Second, it disables setting errno after single-instruction math functions, which means avoiding a write to a thread-local variable (this can make a 100% difference for those functions on some architectures).

Third, it makes the assumption that all math is finite, which means that no checks for NaN (or zero) are made in place where they would have detrimental effects. It is simply assumed that this isn't going to happen.

Fourth, it enables reciprocal approximations for division and reciprocal square root.

Further, it disables signed zero (code assumes signed zero does not exist, even if the target supports it) and rounding math, which enables among other things constant folding at compile-time.

Last, it generates code that assumes that no hardware interrupts can happen due to signalling/trapping math (that is, if these cannot be disabled on the target architecture and consequently do happen, they will not be handled).

  • 22
    Damon, thanks! Can you add some references? Like gcc.gnu.org/onlinedocs/gcc/Optimize-Options.html "-ffast-math Sets -fno-math-errno, -funsafe-math-optimizations, -ffinite-math-only, -fno-rounding-math, -fno-signaling-nans and -fcx-limited-range. This option causes the preprocessor macro FAST_MATH to be defined." and something from glibc, like (math.h near math_errhandling) "By default all functions support both errno and exception handling. In gcc's fast math mode and if inline functions are defined this might not be true."
    – osgx
    Mar 3, 2014 at 0:39
  • 6
    @javapowered: Whether it is "dangerous" depends on what guarantees you need. -ffast-math allows the compiler to cut some corners and break some promises (as explained), which in general is not dangerous as such and not a problem for most people. For most people, it's the same, only faster. However, if your code assumes and relies on these promises, then your code may behave differently than you expect. Usually, this means that the program will seem to work fine, mostly, but some outcomes may be "unexpected" (say, in a physics simulation, two objects might not collide properly).
    – Damon
    Nov 14, 2014 at 12:06
  • 5
    @Royi: The two should be independent of each other. -O2 generally enables "every" legal optimization, except those that trade size for speed. -O3 also enables optimizations that trade size for speed. It still maintains 100% correctness. -ffast-math attempts to make mathematical operations faster by allowing "slightly incorrect" behavior which is usually not harmful, but would be considered incorrect by the wording of the standard. If your code is indeed much different in speed on two compilers (not just 1-2%) then check that your code is strictly standards compliant and ...
    – Damon
    Aug 5, 2017 at 10:11
  • 3
    ... produces zero warnings. Also, make sure you do not get in the way of aliasing rules and things like auto-vectorization. In principle, GCC should perform at least as good (usually better in my experience) as MSVC. When that isn't the case, you've probably made a subtle mistake which MSVC just ignores but which causes GCC to disable an optimization. You should give both options if you want them both, yes.
    – Damon
    Aug 5, 2017 at 10:15
  • 1
    @Royi: That code does not look like really small and simple to me, not something one could analyse in depth in a few mins (or even hours). Among other things, it involves a seemingly harmless #pragma omp parallel for, and within the loop body you are both reading from and writing to addresses pointed to by function arguments, and do a non-trivial amount of branching. As an uneducated guess, you might be thrashing caches from within your implementation-defined invokation of threads, and MSVC may incorrectly avoid intermediate stores which aliasing rules would mandate. Impossible to tell.
    – Damon
    Aug 5, 2017 at 10:34

As you mentioned, it allows optimizations that do not preserve strict IEEE compliance.

An example is this:

x = x*x*x*x*x*x*x*x;


x *= x;
x *= x;
x *= x;

Because floating-point arithmetic is not associative, the ordering and factoring of the operations will affect results due to round-off. Therefore, this optimization is not done under strict FP behavior.

I haven't actually checked to see if GCC actually does this particular optimization. But the idea is the same.

  • 33
    @Andrey: For this example, you go from 7 multiplies down to 3.
    – Mysticial
    Sep 14, 2011 at 17:55
  • 4
    @Andrey: Mathematically, it will be correct. But the result may differ slightly in the last few bits due to the different rounding.
    – Mysticial
    Sep 14, 2011 at 17:58
  • 2
    In most cases, this slight difference won't matter (relatively on the order of 10^-16 for double, but varies depending on the application). One thing to note is that ffast-math optimizations don't necessarily add "more" round-off. The only reason why it's not IEEE compliant is because the answer is different (albeit slightly) from what is written.
    – Mysticial
    Sep 14, 2011 at 18:03
  • 1
    @user: The magnitude of the error depends on the input data. It should be small relative to the result. For example, if x is smaller than 10, the error in Mystical's example will be down around 10^-10. But if x = 10e20, the error is likely to be many millions.
    – Ben Voigt
    Sep 14, 2011 at 18:05
  • 5
    @stefanct it's actually about -fassociative-math which is included in -funsafe-math-optimizations which in turn is enabled with -ffast-math Why doesn't GCC optimize a*a*a*a*a*a to (a*a*a)*(a*a*a)?
    – phuclv
    Aug 29, 2018 at 7:55

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.