I have a list of objects list <Bullets *> bullets ; Don't I need to make an instance of it? In C# you have to....I guess because everything is an object there
Well some of my worst project experience was using AC Foundation (Andersen Consulting Foundation), which was a Smalltalk framework translated to C. We coded this thing, lots of GUI stuff in low level very much copy-code C, for Windows 3.x and OS/2, with a good deal of COBOL and SQL added. Argh.
What is this idiom and when should it be used? Which problems does it solve? Will the idiom change when C++0x is used?
Although it's been mentioned in many places, we didn't have any singular "what is it" question and answer, so here it is. Here is a partial list of places where it was previousl...
@LewsTherin You can simply swap the to-be-deleted element in the vector with the last element and then simply remove that last element. Almost as efficient as the list approach. Of course that only works if you don't care about order.
In computer science, a gap buffer is a dynamic array that allows efficient insertion and deletion operations clustered near the same location. Gap buffers are especially common in text editors, where most changes to the text occur at or near the current location of the cursor. The text is stored in a large buffer in two contiguous segments, with a gap between them for inserting new text. Moving the cursor involves copying text from one side of the gap to the other (sometimes copying is delayed until the next operation that changes the text). Insertion adds new text at the end of the fir...
@cpx an interface in C++ is not much more than a convention. but there is some slight support for class interfaces. you can emulate a java interface by having all methods pure virtual, and using only virtual inheritance from the interface class.
ADL doesn't directly apply to template-id's such as get<0>, so the compiler doesn't really get started down that path. C++11 §14.8.1/8 (in C++03, 14.8.1/6):
[ Note: For simple function names, argument dependent lookup (3.4.2) applies even when the function name is not visible within the...
Can inherit from zero or more base interfaces. Cannot inherit from a base class. Can only contain public, pure virtual methods. Cannot contain constructors, destructors, or operators. Cannot contain static methods. Cannot contain data members; properties are allowed.
I like this example because it makes it clear why it's forbidden. std::vector<double> numbers = 10; looks way too much like the initialization of the first element.
> A declaration is a definition unless it declares a function without specifying the function’s body (8.4), it contains the extern specifier (7.1.1) or a linkage-specification25(7.5) and neither an initializer nor a function-body, it declares a static data member in a class definition (9.2, 9.4),
> it is a class name declaration (9.1), it is an opaque-enum-declaration (7.2), it is a template-parameter (14.1), it is a parameter-declaration (8.3.5) in a function declarator that is not the declarator of a function-definition, or it is a typedef declaration (7.1.3), an alias-declaration (7.1.3), a using-declaration (7.3.3), a static_assert-declaration (Clause 7), an attribute-declaration (Clause 7), an empty-declaration (Clause 7), or a using-directive (7.3.4).
Maybe I'll eventually work up to a refactoring tool framework or such. Dunno. Anyway it's the probably the most advanced currently out there, at what it does.
the standards committee said in bloomington meeting they want to make that stringizing a weird unicode string will not show the UCN spelling in the result string
Anyway the fix, if the debated change is exactly as you said, is for me to delete the line in my stringize routine which inserts a backslash before every non-basic-source character.
However, a user-inserted backslash before a UCN is another case which produces a weird hex code, and is independent from stringizing.
Actually it was fairly natural. I started writing the code after seeing your question, but hit upon the corner case and wrote in "this is ambiguous" before later revisiting it and seeing the solution.
@cpx Hard to tell... I had already programmed in C++ for several years before I read Effective C++, and almost every chapter was still in eye-opener for me.
If this really goes anywhere, it'll be an introspective/explanatory tool first, such as for showing name resolution.
Then maybe look for some niche, like C++ to JavaScript compilation, which could be self-hosting in a sluggish sense.
In other words, not likely to go much further than a preprocessor in the near future. It's a crowded field and there are already good frontends out there.
Although, if you want to contribute to the project, I'll happily accept your checkins :vD
can you explain me this line -> this is the case whenever the type of the name or expression preceding the qualifying operator is dependent on a template parameter, and the name that follows the operator is a template-id (in other words, a template name followed by template arguments in angle brackets). For example, in the expression
ok , then line above from book : whenever the type of the name or expression preceding the qualifying operator -> How does this line explains shell<T> ?
In practice, specifying template for member templates is rarely necessary, and G++ at least will help tell you when it is necessary.
So I wouldn't worry too much about memorizing these rules… the more important thing is understanding why templates are used and how they solve engineering problems.
Fair nuff. Simply put, if the object or type before the :: or -> depends on a template argument, and the name after the :: or -> is a member template for which you are specifying explicit arguments inside < >, then you need ::template or ->template.
If that isn't simple, it's because so many requirements have to be satisfied. It's really a corner case.
@JohannesSchaublitb: By the way, my main problem with the preprocessor is failure to evaluate expressions for #if. Do you know of a good self-contained C++ expression evaluator? Clang is supposed to be modular, does it have a helpful component?
In particular, G++ rejects #if "hello"[2] which is a valid constant expression. Does Clang accept this?
@Potatoswatter I would have thought an lvalue for a static storage duration object would not have been a constant expression. Did something change for C++11?
i.e. I'm accustomed to prvalue constant expressions only.
@LucDanton Actually, it depends whether string literals are constexpr and not merely const — an assertion I didn't check. It only makes sense that they would be in the context of user-defined literals, but let me see…
Hmm, the exact wording is "a glvalue of literal type that refers to a non-volatile object defined with constexpr". A string literal has no definition, thus it is not defined with constexpr.
I am reading this specific topic in Templates complete guide : 9.3.3 Dependent Names of Templates
... some damn code
template<typename T, int N>
class Weird {
public:
void case1(Shell<T>::template In<N>::template Deep<N>* p) {
p->template Deep<N&g...
@LucDanton Rather than go to the Standard initially, I just tried an experiment with G++ and it accepted it. How's this for an abomination? ideone.com/oH8F6
@JohannesSchaublitb Well, the intent is that replacing all the identifiers with 0 simplifies everything greatly. Of course I don't need to support such to make Boost Functional preprocess.
>> Whatever you do, do not repeat the exact same question twice. If you got no reply the first time, its either because none of us know an answer, or you didn't give us enough information. Change your question, and provide more supporting information, before asking again. <<
What you're saying is basically "I asked this question and got an answer to it. I didn't understand the answer, but I won't tell you what the answer was. Please explain the answer to me even though I haven't told you what it was"
If you don't understand the answer you got, why don't you just say "here is the answer I got, I don't this part of it, can anyone explain it?"
I think he is like "I may have found a bug in the book but I need someone to verify that I indeed found a bug. The problem is, this book says that Shell<T> is an expression."
The answer to "is this a name or an expression" is obviously either "it is a name" or "it is an expression". If the answer you get is "it is a name", and you don't understand why, then your next question should not be "is it a name or an expression", but "why is it a name?"
for example (p + 0)-> ... the postfix expression is not a name, but an expression. in p-> ..., the postfix expression is both a name and an expression. and in Shell<T>::... it is not an expression but a name
finally in decltype(Shell<T>())::... it is neither a name nor an expression. but the book is not about c++11 so it doesn't handle this case
Looks like there's the critical mass of regulars to ask what has been bugging me this morning (and which I've discussed with Potatoswatter earlier today): we already have the convention when turning a move-only type into a copiable, shared type to name the new type shared_*, as is the case with std::future and std::shared_future.
What would be the converse convention when writing a move-only type with roughly the same functionality as a copyable type?