@ecatmur It means that you can, for example, make a function that can iterate over any set without regard to it's allocator, instead of having to make it a template.
as someone mentioned above, SCARY basically simplifies the signature of an iterator. A set<T> iterator should just depend on the std::set template, and the type T. Without SCARY, it also depends on the allocator type, for example, even though it is utterly irrelevant to the iterator
with SCARY, all set<T, ....> have the same iterator types. Without, they have unique iterator types, forcing you to template code that otherwise didn't need to be templated
It probably enables a few other tricks too. I can't remember all the details. :)
I feel the need to design a language based off C++, but dropping all compatibility, and addressing several concerns of mine. Like operator new, streams, arrays, extension methods, and other random stuff.
and then everything else can actually be printed, and those other objects will compile and execute, you'll just get useless addresses or something out the other end
@Ell Yeah, but why is it stuck with horrid C-like syntax? Because backwards compatibility. Why isn't it designed for functional programming? Because backwards compatibility. I'd rather build RAII into Haskell or something, than make a "C++ without the backwards compatibility"
Your header has bool listening in the declaration of class unix_stream_server, but your .cpp file has another definition of class unix_stream_server which omits the bool listening member. Don't do that. Seriously, don't do that. Include your headers from your implementation files! Please!
I was under the impression that accessing an union member other than the last one set is UB, but I can't seem to find a solid reference (other than answers claiming it's UB but without any support from the standard).
So, is it undefined behavior?
Formally C++ supports a pretty good subset of Unicode even in identifiers, so in theory one could write identifiers with e.g. Norwegian characters, such as antallBlåbærsyltetøyGlass.
In practice, C++ implementations only support A trough Z, digits 0 through 9, and underscore, in identifiers. Som...
[d:\dev\test]
> cl foo.cpp
foo.cpp
foo.cpp(1) : warning C4100: 'p' : unreferenced formal parameter
foo.cpp(1) : error C2552: 'x' : non-aggregates cannot be initialized with initializer list
'X' : Types with user defined constructors are not aggregate
[d:\dev\test]
> g++ foo.cpp
foo.cpp:1:43: error: could not convert '{1, 2, 3, 4}' from '<brace-enclosed initializer list>' to 'X'
[d:\dev\test]
>
I just realized my allocator changes to my hypothetical language would make pointers themselves a library type instead of builtin. I'm trying to figure out if that's what I really want. It might actually be. I'll have to think on it.
No, because then dereferencing a pointer has to be a library function too, I don't think that's a good idea.
frick. What is the right way to do allocators? :(
actually, I don't think I'd have to make pointers themselves a part of the library, you just wouldn't be able to obtain one without.... no that doesn't work either.
@DeadMG I was trying to make it general to the point that, pointers and references could be objects that referred to memory on another machine over a network. C++ allocators can handle that fine, except nobody actually uses reference or pointer, and just use the & and * built into the language, so nobody would use it correctly. I'm trying to figure out how to enforce proper allocator usage.
Problem is I can't figure out how to make that work with a clear separation of language and library.
anyways, a function argument can be implicitly a template; and a return type can be inferred from the body if known; or it will have to be explicit (e.g. decltype) if dynamically linked