@LoïcFaure-Lacroix Ah, I see. And here I was ready to get excited that MS had done some major updating to Excel's macros and such. Oh well, it's not like I actually use Excel or anything.
Since Australia produces 50+% of world's licit poppy straw that is later refined into opiates, I am tempted to become a poppy farmer. What if I let cows chew on poppy plants and produce 'morphine flavoured milk?'
On second thought, no one should do that because it's animal cruelty.
@Roland_dfa this is missing a whole lot of context but what you're saying sounds more like a job for some constexpr or template stuff, rather than macros
I mean you can do "#define something sizeof(arr)" just fine but it sounds like the next thing you want to do is "#define macro2 MYVAR##something" which would not help you
@nwp Excellent point. If you really need to support old compilers, you can still do the job reasonably well on your own: template <class T, std::size_t N> std::size_t size(T (&)[N]) { return N; }. Simply won't compile if you try to pass a pointer.
@PeterT Even in C you do do the job better than this. #define size(array) (sizeof(array) / sizeof(array[0])) This way it works for arrays of arbitrary type, not just int.
In practice constinit won't solve static initialization order initialization problems because it can only be used for the most boring of types. But it will lead to better job security, and confustifated code when people use it to annotate their static ints.
@Mikhail I guess that doesn't surprise me a whole lot. I glanced at it enough to recognize that its basic intent wasn't one I cared much about, and never spent time looking at the details to figure out how well it would do things I didn't care much about.
@Mgetz Can you recall where 2's complement is in the standard exactly? Because that's pretty much what I've been looking for
@Mgetz Also, in c++2014, there is the link to 5.2.4.2, which describes all the three representations of signed integers, doesn't that contradict your statement in a way?
Yes, there are now three (and only three) representations for integers: ones complement, twos complement, and signed magnitude. Previously, if you wanted to implement C++ on a machine using excess-4 balanced ternary representation, you could do that.
Do note, however, that even on a machine with different representation, most conversions involving unsigned still need to act roughly as if you had a 2's complement representation. For example, converting -1 to unsigned will always yield the largest unsigned value. With 2's complement, those both have all bits set. Using another representation, it might have to manipulate bits to get the right result.
@iksemyonov It turns what had been a practical fact for decades into an actual requirement. Little practical difference though, unless you deal with some ancient (and even then fairly fringe) architectures.
@iksemyonov I haven't actually looked up that part of things in years, so I don't remember section numbers any more.
@iksemyonov Yeah, if memory serves, the phrasing is something like "congruent to the source value modulo 2^N, where N is the width of the destination" (but as I said, I haven't looked in years, so my wording could be a bit wrong).
@JerryCoffin Is "congruent" a mathematical term in this context? I know what "congruent triangles" means, but applied to integers, it makes little sense to me.
@iksemyonov Yes. "Congruent to X" basically means "the remainder when divided by X". When you deal with negative number, congruent (at least normally) means you "move" it into the range 0..X-1, so if your remainder was negative, add X to get a positive number.
@iksemyonov All executes on the same processor, so the differences are obviously insignificant.
Personally, I prefer to code in good, portable, ISO-standard Malbolge, but I realize that in the end it's no different from any other programming language.