I assume that
fabs are behaving different when using
math.h. But when I use just
std::abs, do I have to use
fabs? Or isn't this defined?
It's still okay to use
float arguments. I prefer this because it ensures that if I accidentally strip the
std:: off the
abs, that the behavior remains the same for floating point inputs.
I just spent 10 minutes debugging this very problem, due to my own mistake of using
abs instead of
std::abs. I assumed that the
using namespace std;would infer
std::abs but it did not, and instead was using the C version.
Anyway, I believe it's good to use
fabs instead of
abs for floating-point inputs as a way of documenting your intention clearly.
"abs" and "fabs" are only identical for C++ float types, when they can be translated without ambiguous overload messages.
I'm using g++ (g++-7).
Together with template usage and especially when using mpreal there are cases with hard "ambiguous overload" messages -
abs(static_cast<T>(x)) isn't always solving that.
When abs is ambiguous, there are chances that fabs is working as expected. For sqrt I found no such simple escape.
Since weeks I'm hard struggling on C++ "not existing problems". I'm updating an old C++ program to C++14 for more and better template usage than possible before. Often the same template parameter may be actual any standard float or complex type or a class type. Why ever, long double acted somewhat more sensible than other types. All was working, and I had included mpreal before. Then I was setting my default float type to mpreal and got a deluge of syntax errors. That gave thousands of ambiguous overloads e.g. for abs and sqrt, crying for different solutions. Some were needing overloaded help functions, but outside of a template. Had to replace individually a thousand usages of 0.0L and 1.0L with the exact constant type using Zero or One or a type_cast - automatic conversion definition impossible because of ambiguities.
Up to May I found the existing of implicit conversions very nice. But much simpler it would be without any, and to have typesave constants with safe explicit type_casts to any other standard constant type.