@AlfPSteinbach The last question I saw you ask was about the swap semantics for ios_base or something. It was something I would have probably never noticed in the standard, but the question and answers were really instructive. Most of the questions on here seem like garbage, and most answers seem trivial. It's kind of depressing really, but there is some really good stuff on SO.
How do you usually do it when you implement a Template class? Do you put everything in a .h file, or definition in the .h and the declaration in the .cpp file and the include the cpp file into the h file, or include the h file into the cpp and instead include the cpp where the template class should be used?
C#, Java and practically any other language in the world tells you to define your classes inline, because it's just not very intuitive to have it split into two halves like we traditionally do in C++
in C++, we do it to work around a broken compilation model
Quote from The C++ standard library: a tutorial and handbook:
The only portable way of using templates at the moment is to implement them in header files by using inline functions.
Why is this?
templates have to be visible to use them. So wherever you put them, they have to be included. You can put them in one, two or fourteen different files, it makes no difference, I have to include them all in order to use the template
@ManofOneWay I just write my class templates inline
@ManofOneWay But the class still contain a bunch of other implementation details. The header still shows all the private members and base classes and whatnot. It's not a good abstraction, and it was never intended to be an abstraction
headers are a workaround for a broken compilation model, nothing more. They're certainly not a tool for providing abstraction
too bad neither he nor Dave gave an elaborated explanation for why it fails
Dave just said "Unfortunately, as Daveed points out in his comment, it’s even worse than that: because decltype is operating on an lvalue, the version above returns a reference to a temporary! So we’d actually need this:"
@JohannesSchaublitb only if you look at it back to front, and start with the assumption that "we have to have concepts, regardless of how they constrain us"
The objective with concepts was to better describe the code we're writing, so the compiler can better understand what we're doing, and provide better error messages. It was never meant to constrain us or block us from doing useful things. So any time concepts constrain us from doing useful things, they've failed
@JohannesSchaublitb I don't follow. How would polymorphic lambas be non-type checked?
the type checking occurs later during the compilation, and yields a less readable error message, and so what? It still gets type checked, and it allows me to write more expressive and concise code
It's not much of an exaggeration to say that that's why I use C++ and not C#
that's equivalent to saying "the checking for errors occurs later during execution of the program and yields a less reliable error message, and so what?"
nothing necessarily checks that the iterator you are using is really a forward iterator. perhaps it is actually an input iterator and you just ended up in UB land?
moreover, no, I don't think that's equivalent at all. I think there's a world of difference between errors caught late during compilation, and errors caught at runtime
@JohannesSchaublitb but if concepts make it impossible to implement polymorphic lambdas, then that is an extremely high price to pay for a bit more error checking
If I wanted everything to be checked for me, I'd use Java. I use C++ because I'm willing to give up some error checking in order to write more expressive code
In an algorithm I'm writing, I can have the following (simplified of course)
int a[3] = {1,2,3};
int b = a[3];
when the index used to fill b overflows, I never use the value of b. Is the code still incorrect? Do I have to make an explicit boundary check?
Obviously, dereferencing an invalid pointer causes undefined behavior. But what about simply storing an invalid memory address in a pointer variable?
Consider the following code:
const char* str = "abcdef";
const char* begin = str;
if (begin - 1 < str) { /* ... do something ... */ }
The e...
If you have the following code where p is a pointer:
p = p + strlen(p) + size_t(1);
Since strlen() and size_t are both size_t, should I cast the code to ptrdiff_t ?
p = p + (ptrdiff_t)(strlen(p) + size_t(1));
If so why?
Thanks,
Greg
According to C++ standard (3.7.3.2/4) using (not only dereferencing, but also copying, casting, whatever else) an invalid pointer is undefined behavior (in case of doubt also see this question). Now the typical code to traverse an STL containter looks like this:
std::vector<int> toTraverse...
@FredOverflow In the Standard, polymorphism is used to refer to subtype polymorphism. dynamic_cast does something "if the object has polymorphic type", etc. So I think it's reasonable to restrict the meaning from the pure computer science term.
@FredOverflow because the rule is "if P points to the last element, P+1 points to after the last element.". There is no rule "if P points to array element N of an array of M elements, P + (M - N) + 1 points to after the last element"
@DeadMG The inability to pass explicit arguments results from the lack of a suitable template-name more than anything else. It's certainly possible to define a canonical order of implicit template parameters.
But anyway, I thought this was all defined in terms of addresses, and one-past-end is fine no matter how you get there. It's a property of the pointer value, not the pointer expression.
§5.7/5: "If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow." — so even if the behavior is undefined, the obvious failure mode is excluded.
for any int a[5]; then a + 3 is defined to point to the same element as a + 1 + 1 + 1
and, in addition, the compiler cannot treat them differently for one-past-the-end, because in the case of dynamic arrays or just arrays not allocated in that TU, it cannot know when it's at the end
when it hits a conflict, it copies the state of the parser and lexer, and does work in parallel, until it hits a point where all other paths die except one
that's the plan. the user declares all the state of the lexer and parser, so that lexical tie in works automagical
@JohannesSchaublitb Not yet. I started writing phases 5-6, but that required too much target machine description, so I went back for polishing and adding features.
Quote from The C++ standard library: a tutorial and handbook:
The only portable way of using templates at the moment is to implement them in header files by using inline functions.
Why is this?
According to C++ standard (3.7.3.2/4) using (not only dereferencing, but also copying, casting, whatever else) an invalid pointer is undefined behavior (in case of doubt also see this question). Now the typical code to traverse an STL containter looks like this:
std::vector<int> toTraverse...