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When you've dynamically allocated a buffer of type char * and want to cast it to a particular type, should you use something like

reinterpret_cast<int *>(char *)

or something like

static_cast<int *>(static_cast<void *>(char *))

and why?

I'm personally tempted to use the latter, because to me, it's not really a "reinterpretation" of the data (rather just a mechanical way of allocating the buffer) and it doesn't look like it would be a source of bugs in the same way as a typical reinterpret_cast might be, but is this the correct intuition?

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You shouldn't do this at all, as it's undefined behaviour. –  Kerrek SB Oct 22 '11 at 2:08
    
KerrekSB: What is "this" referring to, exactly? –  Mehrdad Oct 22 '11 at 2:12
2  
@KerrekSB: its completely defined and even used in the implementation of vector (at least in my sgi version). –  Dani Oct 22 '11 at 3:32
    
Those two forms are exactly identical for standard-layout types. per §5.2.10/7 (C++11) –  Cubbi Oct 22 '11 at 4:25
1  
The answers so far seem to treat this as an abstract problem. For a real world example, I run into this situation with sockets or reading data from a file sometimes. I read an array of unsigned char * but the data in the array is actually ints. In this case I want to "reinterpret" my array of unsigned chars as an array of ints. Isn't that exactly what reinterpret_cast is for? –  BHS Oct 22 '11 at 5:35

2 Answers 2

According to Dave Abrahams, using the chained static_casts is the correct, standard way to coerce pointer types.

Personally, I use reinterpret_cast in these cases because I never have to deal with architectures that would do one thing with the chained static_casts and a different thing with the single reinterpret_cast.

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Re the technical, when you have alignment correct (a dynamically allocated buffer is suitable aligned for anything) then you can do

#include <new>

void foo()
{
    char* buf = new char[( sizeof( int )];
    int*  px  = ::new( buf ) int;
    // blah blah
    delete[] buf;
}

As you can see, neither reinterpret_cast nor static_cast is correct.

However, even when using the technically correct C++ facility, as above, it is a very error-prone and verbose way to go about it, i.e. it’s utterly & completely silly.

Instead, just do

void foo()
{
    int x;
    // blah blah
}

Cheers & hth.,

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Using placement new in this manner might work for this case, but this pattern is awfully easy to mess up, particularly if the types are user-defined types (although admittedly, they weren't in the stated problem). –  Michael Price Oct 22 '11 at 3:29
    
@Michael: sorry, you have it completely backwards. placement new is correct for this case, and is very difficult to mess up compared to cast. and in particular for more complex user defined types, simple casting is likely to yield undefined behavior (with indeterminate state of the objects), while placement new is as safe as the class in question. but of course, as I wrote in the answer, even when all technical details are as perfect as they can be, as in my answer, it is an error-prone and verbose thing, generally utterly & completely silly... :-) but that's another question. cheers & hth., –  Cheers and hth. - Alf Oct 22 '11 at 3:39
    
Things that can go wrong with your answer, 1) Miscalculating the size of the char buffer. 2) Forgetting to actually use placement new (results in leak). 3) Calling delete on the wrong pointer (which is very likely if the pointer escapes the stack from which it was initially allocated). 4) I'm sure there's more if I took the time to look more closely. –  Michael Price Oct 22 '11 at 3:56
    
@Michael Price: Consider that your point (1), "miscalculating the buffer", is as easy to do with casting as with placement new. I.e., that your point (1) is an idiotic argument, meaningless balderdash. And likewise for (2), (3) and (4); they're idiotic. I'm sorry. –  Cheers and hth. - Alf Oct 22 '11 at 4:08

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