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I have following two classes:

template <size_t size>
class Cont{
 public:
 char charArray[size];
};
template <size_t size>
class ArrayToUse{
 public:
 Cont<size> container;
 inline ArrayToUse(const Cont<size+1> & input):container(reinterpret_cast<const Cont<size> &>(input)){}
};

I have three following lines of code at global scope:

const Cont<12> container={"hello world"};
ArrayToUse<11> temp(container);
char (&charArray)[11]=temp.container.charArray;

In totality of my code The only usage of "container" object is for initialization of an object of "ArrayToUse" class as mentioned and after initialization of "charArray" reference to "temp.container.charArray" I'll use that reference in rest of my code, now I'm wondering does compiler reserve memory for "container" object since that's got a temporary usage?

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6  
Yu​​​​​​​​​​ck. –  GManNickG Oct 19 '10 at 20:00
2  
Before getting any more Yucks, maybe you want to drop a note on what you want to achieve by this... this err... this thing. –  xtofl Oct 19 '10 at 20:08
    
Help a C++ noobie out, what exactly does this do? –  dreamlax Oct 19 '10 at 20:42
    
@dreamlax: Makes people say yuck. :) I'm not too sure myself, I didn't feel like putting effort into understanding the rationale of such code. But it basically makes a Cont<12> (which you can think of as char[12]), some other class (ArrayToUse<11>) that has a Cont<11> (or char[11]) constructed with a Cont<12> by reinterpret_cast'ing (big wtf there), then makes a variable that's a reference to a char[11] and binds it to the ArrayToUse<11>'s internal array. I don't the point behind any of it. –  GManNickG Oct 19 '10 at 21:36
1  
@Gman: I think my C++ skills took a step back trying to understand this. –  dreamlax Oct 19 '10 at 22:33

3 Answers 3

up vote 2 down vote accepted

Any variable defined at global scope has memory reserved for it at compile time. That does not mean it's guaranteed to be properly initialized, but it's there all the same.

At link-time, Visual C++ offers the option to strip unused data and functions via /OPT - see here.

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@flownt - it compiles OK for me –  Steve Townsend Oct 19 '10 at 20:01
1  
yes on closer inspection it's okay but the syntax looks quite arcane. in any case the reference is not to container but to the subobject in arraytouse so container may still be optimized out. –  flownt Oct 19 '10 at 20:06
    
@Steve Townsend_I'm not referencing "container" object using charArray, I'm referencing "temp.container.charArray". –  Pooria Oct 19 '10 at 20:12
    
@flownt - the compiler cannot optimize this out. That was the question, if you want to discuss link-time optimization that's a different matter. –  Steve Townsend Oct 19 '10 at 20:16
1  
@Steve - well about vtables 1)they're global, 2) its a link-time optimisation. otoh i made gcc generate code at O3 with lto and I even added static to the first line so it knew this could be the only place where it's used and it still refused to optimise it away, i'd therefore assume compilers are not (yet) smart enough to compile that thing away òr the standard just doesn't allow such a thing(maybe the standard finds it observable..) –  flownt Oct 20 '10 at 21:12

it totaly depends on your particular compiler so i'd say inspect the assembly and find out! the compiler could optimize container out, or it could neglect to do so.

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The compiler should create the container variable in the compiled object file. The linker is the one that can tell if it's needed or not (for an exported symbol, or from another compilation unit if declared extern).

But...

The type Cont<x> is unrelated to Cont<x+1>. You cannot depend on the memory of a member variable being layed out in similar fashions. Heck, you cannot even know if it looks the same, since there is this thing called 'template specialization':

// your code
template <size_t size>
class Cont{
 public:
 char charArray[size];
};

// my evil tweak
// I'm the worst compiler ever but I feel that this
// array would better be represented as a map...
template<> class Cont<12> {
   std::map<int,char> charArray;
};

// your screwed up result
Cont<12> c12;
Cont<11>& c11( reinterpret_cast<Cont<11>&>(c12) );
char (&s11)[11] = c11.charArray; // points to the first byte of a list object...

EDIT -- @UncleBen's comment insinuates I'm overdoing here. And he's right.

according to wikipedia,

  • A pointer to a POD-struct object, suitably converted using a reinterpret cast, points to its initial member and vice versa, implying that there is no padding at the beginning of a POD-struct.

So in this case,

  • where the charArray is the first member of a Cont<n>, and there are no non-POD members

  • there is no assignment operator, nor a destructor

It is safe.

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Unless there is a specialization, does the compiler really have any say in how the class will be laid out in memory (the offset of first member is 0 and the array is contiguous)? –  UncleBens Oct 19 '10 at 21:27
    
@UncleBens: good question - I'll search around on alignment, packing etc... –  xtofl Oct 20 '10 at 7:07

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