Nothing per se, but it's not the complete solution to this particular problem.
Although, for the sake of argument, if std::remove_reference< std::reference_wrapper< T > >::type were T, my given implementation would handle this case.
Yeah, we've went from std::bind(functor, by_val, std::ref(by_ref)); to std::perfect_bind(functor, val(by_val), by_lref, std::move(by_rref));. That's not so much a property of perfect forwarding though as to the semantics of bind (local copy or action at a distance?).
@Potatoswatter Oh wait, you're right.
std::decay handles std::reference_wrapper.
Let me check if that's the ccase for remove_reference, too.
Uses perfect forwarding, but the returned type holds 'copied' types from the original T's.
So the caller can do make_tuple(42); or make_tuple(i); or make_tuple(std::move(i)); and the resulting tuple is the same; perfect forwarding is used for convenience to the caller.
std::forward_as_tuple on the other hand does exactly what the name implies.
But the Standard Library is designed by a committee, wants to avoid naming conflicts at all costs, and wants backwards compatibility... Do you even have the same requirements?
That's the Standard Library that uses std::forward_list and std::unordered_map for single-linked list and hash maps respectively.
If I understand how library requirements work, then it's not specified where the error happens. The program is simply invalid as far as the Standard goes.
@Potatoswatter But there's no underlying type since it's type erasure.
On the other hand, the returned type of std::bind is guaranteed to be conditionally copyable depending on the underlying type :)
You need two different erasures, one which is move-only, one which is copyable.
The lowest address is static_cast< char * >( & my_int ) and the highest is static_cast< char * >( & my_int + 1 ) - 1… but again you shouldn't be doing that.
The C++ spec (§4.7/2) guarantees that narrowing conversions always discard the most-significant bytes by giving back the 'smallest value' congruent to the original integer.
Want to share one interesting real life incident.
Once I was in an interview and was asked to write a program using either C or C++ (just FYI: enter city codes and enter telephone numbers. Then arrange phone numbers for given city code).
After few minutes, while writing printing statements usin...
well if you want to know good or better answers, you format the q well so that you get good answers, not act like a dumb show off...saying i could answer it, let me see how well you guys can.
And this case, it seems a petty case of garnering some rep
Anyway, I checked, and while keypress [Alt 33] (on numeric keypad) of course works in Windows, there is no trigraph sequence for ", and \u0021 doesn't work because a Unicode thing can't designate a character in the basic character set. So of my three solutions only first one survived. But I learned fourth one from above question, namely using the preprocessor to stringize, I didn't think of that.
Calling get does not seem to invoke argument dependent lookup:
auto t = std::make_tuple(false, false, true);
bool a = get<0>(t); // error: unknown identifier 'get'
bool b = std::get<0>(t); // okay
Why?
It hasn't been updated since 2008-ish, and it's not clear if it's just the free version or if the pay version has been revised. It would seem not. Probably because people weren't paying.
Hmm, looking back at TR1 again, I get the impression that their intent was that you reconfigure your compiler to look in the tr1/ directory automatically, and always write #include <tuple>.
@cpx yes, sorry, it's a reinterpret_cast. And you can't dereference the resulting pointer, which reflects the fact that C++ doesn't require an implementation to commit to big-endian or little-endian. On a machine with strict pointer semantics it could, I believe, crash.
@AlfPSteinbach Fred illustrated his question with C++11 code. Presenting a similar but not identical case means introducing new variables. I like to isolate my problems :)
> A non-template constructor for class X is a copy constructor if its first parameter is of type X&, const X&, volatile X& or const volatile X&, and either there are no other parameters or else all other parameters have default arguments. [12.8 §2]
The answer lies above in the list that shows the cases where a copy constructor is called. A copy constructor is called when a parameter is passed by value. If we pass our cSource parameter by value, it would need to call the copy constructor to do so. But calling the copy constructor again would mean the parameter is passed by value again, requiring another call to the copy constructor. This would result in an infinite recursion (well, until the stack memory ran out and the the program crashed)
@AlfPSteinbach Well I don't care, that how I run my experiments. If the variable is "what compiler I'm using" I won't damn change the code, too. Science!
@LewsTherin T x(y); would call the copy constructor to initialize x with y, right? Assume the copy contructor were defined as T::T(T z). z would have to be initialized with y by the copy constructor. This is where the endless recursion starts. Get it?
Whenever you see a function foo(T z), the copy constructor will be invoked to initialize z. Right? So if the copy constructor had the signature T(T z), that z would also have to be initialized by calling the copy constructor before the body of the copy constructor could be entered -> infinite recursion
Except it's not infinite recursion in the familiar sense that causes stack overflow, it's more like the compiler can't even begin to produce code to do it. It just doesn't know where to start.
The compiler says, "I want to call the copy constructor. Well, first I'll need to call the copy constructor. So first I'll need to call the copy constructor. Huh."
so at first 2 copying makes place A copy of y, then when it attempts to initialize that copy with z, it invokes the copy constructor which needs to initialize z it calls t again
@Potatoswatter I'd put it that way: it's an infinite recursion in brainspace, the space where language is conceived. It's not a recursion in the language space, we're not quite there yet.
> A non-template constructor for class X is a copy constructor if its first parameter is of type X&, const X&, volatile X& or const volatile X&, and either there are no other parameters or else all other parameters have default arguments. [12.8 §2]
x(y) -> Invokes T(T z) to create 'x'. Because z is a value parameter we must first copy y into z (using the copy constructor) so this invokes T(T z) to create 'z'. Because z is a value parameter we must first copy y in z1 (using the copy constructor) so this invokes T(T z) to crate 'z'. Becuase z is a value parameter we must first copy y into z2 (using the copy constructor......
@LewsTherin Depends how it's declared. If the assignment operator uses pass-by-value then the copy constructor sure is called, as it would be for any other function. (That's used for copy-and-swap for instance.)
Person q("Mickey"); // constructor is used to build q. Person r(p); // copy constructor is used to build r. Person p = q; // copy constructor is used to initialize in declaration. p = q; // Assignment operator, no constructor or copy constructor.
It's because you attempt to explicitly instantiate get function template, by providing 0 as template argument. In case of templates, ADL works if the template is instantiated implicitly, by template argument deduction.
Please note that it is the explicit instantiation of template which fails. I...
Yeah, I don't understand how GCC is compliant there. Since tuple and get are both std it should work :v( . Ah, and now I've read the answer and I understand, for better or worse.
@Potatoswatter I'd look up ADL rules to see what's going on but as I recall those are a bitch to find and understand. So waiting on a hero to do it for me :)
The get function is defined in the namespace of std. Since you don't have a using namespace std; in your code the compiler doesn't know what get<>() function you are calling. By adding std:: as a namespace declaration in front of it the compiler can find the function and use it.
actually checking the standard my term "specialization" was correct, and nawas' "explicitly instantiate" is wrong. but who remembers all these term definitions.
The terms are copy initialization vs direct initialization (the first term still applies if overload resolution picks a move constructor -- this is at the syntax level).
@FredOverflow in c++03 the T p(q) is a direct initialization, and T p = q is a copy initialization. The latter requires an accessible copy constructor.
@FredOverflow I don't think so. Copy constructor to copy object on object creation... But since assignment doesn't call a copy constructor we need to overload assignment operator
What does copying an object mean? What are the copy constructor and the copy assignment operator? When do I need to declare them myself? How can I prevent my objects from being copied?
> The initialization person b(a); is performed by the copy constructor. Its job is to construct a fresh object based on the state of an existing object. The assignment b = a is performed by the copy assignment operator. Its job is generally a little more complicated, because the target object is already in some valid state that needs to be dealt with.
it was a very silly flame war. Nathan stated that you couldn't wrap a C header in a namespace. I responded by actually doing that for <windows.h>. Of course we were talking about two entirely different things :-). But neither of us understood that. Or at least I didn't.
Developed by Microsoft, the Windows Presentation Foundation (or WPF) is a computer-software graphical subsystem for rendering user interfaces in Windows-based applications. WPF, previously known as "Avalon", was initially released as part of .NET Framework 3.0. Rather than relying on the older GDI subsystem, WPF utilizes DirectX. WPF attempts to provide a consistent programming model for building applications and provides a separation between the user interface and the business logic. It resembles similar XML-oriented object models, such as those implemented in XUL and SVG.
WPF employs X...