Lemon Drop

@LanguageLawyer Well that's mainly because of the constexpr behavior it needs, but they do justify it's behavior with std::memcpy being "blessed" here. Honestly though I don't even see what they mean there though since that excerpt deals with two objects of the same type, not differing types, but I guess it just implies that memcpy does indeed create an object with the same value.

@LanguageLawyer Well to me this seems like how memcpy is intended to be used as there is really no other way to preform serialization or copy bits between types, so surely the language would be flawed if it didn't allow that behavior. Additionally std::bit_cast is pretty much based on the same idea so it surely has to work for those cases.

@Joel I'm just going to edit it to make it more correct with what was discussed here since I did make some assumptions in how specific the standard is in how integers can be represented. If anything this just shows why I am excited for C++20 :p

I guess also it only says "permits", as in those formats are acceptable based on the constraints specified, but you could have your own architecture with integers that just have their bits scrambled all over the place for no reason, so yeah implementation defined is more likely in that case. You should say what C++ version you're referring to though since again these rules do change around in subtle ways. Also I was referring to the C++17 standard in that one, the C++20 standard simply says it must be two's compliment and doesn't have those additional details.

Oh well I didn't see that for some reason, oh well. I still think what I said is mostly correct though. Implementation defined is still "defined" behavior in the sense that it's not undefined as it will not cause anything to explode, just the result is unspecified and depends on what machine you're running it on.

I do suppose that could imply anything really but they also do say "This document permits two’s complement, ones’ complement and signed magnitude representations for integral types." I know for sure that one's and two's complement are identical for unsigned, but I do not know what signed magnitude is so that might be a potential exception. Edit: Actually since unsigned numbers are really just signed numbers under modulo 2^n those formats will likely all be different past 2^(n-1), but the value in the question 1 is surely within that range in the examples.

@Joel You can check endianness in C++20 too but yes I think that is accurate. I did find where they say it in the C++17 standard though, I seemed to have just overlooked it (6.7.1/7): The representations of integral types shall define values by use of a pure binary numeration system. A footnote then adds: A positional representation for integers that uses the binary digits 0 and 1, in which the values represented by successive bits are additive, begin with 1, and are multiplied by successive integral power of 2, except perhaps for the bit with the highest position.

I think while these rules cited are generic to accommodate any type, integers have a very specific object representation, especially in C++20 where each bit in order is said to represent a power of 2 of the number in question. In 6.2.6.2 of the C standard this is said more clearly: If there are N value bits, each bit shall represent a different power of 2 between 1 and 2^(N-1), so that objects of that type shall be capable of representing values from 0 to 2^N-1 using a pure binary representation; this shall be known as the value representation. IMO this makes it not implementation defined.

And backcompatibility for days @Aaron3468

Sounds like most computer related things in a nutshell

Or a raspberry pi :p

x86 is kind of a bit cryptic compared to most assembly even lol

How fancy

Oh yeah windows does do ARM now doesn't it

Done ARM a bit more but yeah

I mean I can read it because I've stared at enough assembly output from C++ code and the likes, but it's not something I've ever done extensively

So you prob mean x86

"Windows" lol

What kind of assembly lol

They do a lot of the music for razor 1911's demos and those are always nice

Dubmood makes gud stuff

Just use C# you'll have a better time :p

Well yeah but that's java

I'd say its easy to call C code in most languages though lol

Indeed

Everything low level is usually C

Indeed

I don't think it's very garbage

Lol

Like why not just use pure C, it'll teach ya more most likely before moving on

People just end up using C++ as a glorified C compiler

If you didnt know C before, I highly doubt you actually learned much C++ in 2 days

2 days lol

So its much faster

they have it all pre-loaded in memory

But squiggles dont need to recompile it every time

Even recompiling a single file means you need to instantiate all the templates from the stl if you're using any of its libs again and that just takes ages

Compilation

Yeah no lets not do that friends

Time Elapsed 00:00:01.552

To prove this I added a semicolon to a small file I'm working on

Lol

Yes

Compiling c++ takes more time than waiting for squiggles :p

I could do that but I'd have to keep compiling which is kinda just what its designed to prevent

Sometimes its useful to just visually see that you accidentally forgot to implement a method in a class or something

because they're more code quality related

I think they are useful in the case of resharper because they just inform me that I may have forgotten something or am doing something in a bad way so I can learn from that

7 different colors of squiggles all screaming at me

I use resharper too so I have like