# Why is the standard "abs" function faster than mine?

I wanted to try making my own absolute value function. I figured that the fastest way to calculate absolute value would be to simply mask out the sign bit (the last bit in IEEE 754). I wanted to compare it's speed to the standard `abs` function. Here is my implementation:

``````// Union used for type punning
union float_uint_u
{
float f_val;
unsigned int ui_val;
};

// 'MASK' has all bits == 1 except the last one
constexpr unsigned int MASK = ~(1 << (sizeof(int) * 8 - 1));

float abs_bitwise(float value)
{
float_uint_u ret;
ret.f_val = value;

return ret.f_val;
}
``````

For the record, I know that this sort of type punning is not standard C++. However, this is just for educational purposes, and according to the docs, this is supported in GCC.

I figured this should be the fastest way to calculate absolute value, so it should at the very least be as fast as the standard implementation. However, timing 100000000 iterations of random values, I got the following results:

``````Bitwise time: 5.47385 | STL time: 5.15662
Ratio: 1.06152
``````

My `abs` function is about 6% slower.

## Assembly output

I compiled with `-O2` optimization and the `-S` option (assembly output) to help determine what was going on. I have extracted the relevant portions:

``````; 16(%rsp) is a value obtained from standard input
movss   16(%rsp), %xmm0
andps   .LC5(%rip), %xmm0 ; .LC5 == 2147483647
movq    %rbp, %rdi
cvtss2sd    %xmm0, %xmm0

movl    16(%rsp), %eax
movq    %rbp, %rdi
andl    \$2147483647, %eax
movd    %eax, %xmm0
cvtss2sd    %xmm0, %xmm0
``````

### Observations

I'm not great at assembly, but the main thing I noticed is that the standard function operates directly on the `xmm0` register. But with mine, it first moves the value to `eax` (for some reason), performs the `and`, and then moves it into `xmm0`. I'm assuming the extra `mov` is where the slow down happens. I also noticed that, for the standard, it stores the bit mask elsewhere in the program vs an immediate. I'm guessing that's not significant, however. The two versions also use different instructions (e.g. `movl` vs `movss`).

### System info

This was compiled with g++ on Debian Linux (unstable branch). `g++ --version` output:

``````g++ (Debian 10.2.1-6) 10.2.1 20210110
``````

If these two versions of the code both calculate absolute value the same way (via an `and`), why doesn't the optimizer generate the same code? Specifically, why does it feel the need to include an extra `mov` when it optimizes my implementation?

• Not sure why but in MSVC, your implementation is way faster in debug but equal in the release. Commented Feb 3, 2021 at 8:20
• @D-RAJ doing performance comparisons in debug is meaningless. They might have some checkings active in debug mode that are not present in the release build. Commented Feb 3, 2021 at 8:23
• Have you tried inlining the function? Commented Feb 3, 2021 at 8:25
• @WolfgangLorenz if you mean the `inline` keyword, then you should do some research about what `inline` means nowadays. `inline` is important if you define a function in the header, and use that header in multiple compilations units. But for modern compilers the `inline` keyword alone does not change the probability whether it will inline a function or not. Commented Feb 3, 2021 at 8:30
• What OS are you compiling for? The ABI is strange. Commented Feb 3, 2021 at 8:41

I got a bit different assembly. According to the x86_64 Linux ABI, a `float` argument is passed via `xmm0`. With standard `fabs`, the bitwise `AND` operation is performed directly on this register (Intel syntax):

``````andps xmm0, XMMWORD PTR .LC0[rip] # .LC0 contains 0x7FFFFFFF
ret
``````

However, in your case, the bitwise `AND` is performed on objects of type `unsigned int`. Therefore, GCC does the same which requires to move `xmm0` to `eax` first:

``````movd eax, xmm0
and  eax, 2147483647
movd xmm0, eax
ret
``````

Live demo: https://godbolt.org/z/xj8MMo

I haven't found any way how to force the GCC optimizer to perform `AND` directly on `xmm0` with only pure C/C++ source code. It seems that efficient implementations need to be built upon assembler code or Intel intrinsic.

Relevant question: How to perform a bitwise operation on floating point numbers. All the proposed solutions basically result in the same outcome.

I also tried to use the `copysign` function, but the result was even worse. The generated machine code then conatiend x87 instructions.

Anyway, it is quite interesting that the Clang optimizer was clever enough to make the assembly in all 3 cases equivalent: https://godbolt.org/z/b6Khv5.

• How did you manage to get x87 instructions with copysign? Gcc recognizes `copysignf(x,1.)` as `fabsf(x)`. Commented Feb 3, 2021 at 21:14
• @MarcGlisse No, it does not, at least in my case: godbolt.org/z/KcsGx8. You need to distinguish between `fabs` function and x87 `fabs` instruction. Commented Feb 4, 2021 at 4:25
• It helps if you use copysignf (or std::copysign) instead of plain copysign. Using gcc trunk also helps. Still, weird that there can be x87 instructions with copysign... And I cannot reproduce it locally, maybe godbolt has a strange setup. Commented Feb 4, 2021 at 8:13
• @MarcGlisse This question is not about `copysign` and the discussion about it is off-topic here. However, it might be a good topic for a separate question instead. Commented Feb 4, 2021 at 8:42

Why is the standard “abs” function faster than mine?

Because with most optimizing compilers (in particular GCC or Clang), it would use a specialized machine instruction known by the compiler

The GCC compiler has even a builtin for `abs`

Be sure to compile with `gcc -O3` and perhaps `-ffast-math`.

You could study the assembler code: compile your `example.c` as `gcc -Wall -O3 -ffast-math -fverbose-asm example.c` and look inside the emitted `example.s` assembler file.

On Linux systems (e.g. Debian), you could study the source code of GNU libc and look inside the `math.h` standard header (and use `g++ -O3 -C -E` to get the preprocessed form)