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I'm quite new at working with C++ and haven't grapsed all the intricacies and subtleties of the language.

What is the most portable, correct and safe way to add an arbitrary byte ofset to a pointer of any type in C++11?

SomeType* ptr;
int offset = 12345 /* bytes */;
ptr = ptr + offset;             // <--

I found many answers on Stack Overflow and Google, but they all propose different things. Some variants I have encountered:

  1. Cast to char *:

    ptr = (SomeType*)(((char*)ptr) + offset);
    
  2. Cast to unsigned int:

    ptr = (SomeType*)((unsigned int)ptr) + offset);
    
  3. Cast to size_t:

    ptr = (SomeType*)((size_t)ptr) + offset);
    
  4. "The size of size_t and ptrdiff_t always coincide with the pointer's size. Because of this, it is these types that should be used as indexes for large arrays, for storage of pointers and pointer arithmetic." - About size_t and ptrdiff_t on CodeProject

    ptr = (SomeType*)((size_t)ptr + (ptrdiff_t)offset);
    
  5. Or like the previous, but with intptr_t instead of size_t, which is signed instead of unsigned:

    ptr = (SomeType*)((intptr_t)ptr + (ptrdiff_t)offset);
    
  6. Only cast to intptr_t, since offset is already a signed integer and intptr_t is not size_t:

    ptr = (SomeType*)((intptr_t)ptr) + offset);
    

And in all these cases, is it safe to use old C-style casts, or is it safer or more portable to use static_cast or reinterpret_cast for this?

Should I assume the pointer value itself is unsigned or signed?

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4  
There isn't any. It's undefined behaviour to add an arbitrary byte offset to a pointer. You can only do arithmetic on pointers that point to the same array (and one past the end of it). –  jrok Apr 10 '13 at 18:57
3  
@jrok It's perfectly well defined to add an arbitrary offset to a pointer. What's undefined is dereferencing a pointer that doesn't point to valid memory. –  sfstewman Apr 10 '13 at 18:59
3  
@sfstewman: C++ draft n3092 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; otherwise, the behavior is undefined.” –  Eric Postpischil Apr 10 '13 at 19:12
2  
@sfstewman You're wrong. The standard explicitly makes it UB (see the comment above). In practice, yeah, it just works, at least until you smash your own stack or something like that. –  jrok Apr 10 '13 at 19:14
1  
"Should I assume the pointer value itself is unsigned or signed?" - You shouldn't even assume it's an integer. In the end all your solutions converting to integer for doing arithmetic are UB. The only thing you can do with a pointer cast to int is cast it back to a pointer. But casting to int, adding something and casting back is definitely UB. But I have good hope somebody will come up with a very good standard-proved answer for all your possibilities. –  Christian Rau Apr 10 '13 at 19:50
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3 Answers 3

up vote 6 down vote accepted

I would use something like:

unsigned char* bytePtr = reinterpret_cast<unsigned char*>(ptr);
bytePtr += offset;
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I would use the more condensed (reinterpret_cast<unsigned char *>(ptr) + offset) perhaps wrapped in an inline (possibly template) function, depending on how often I needed it and what the returned type ought to be. –  Nik Bougalis Apr 10 '13 at 19:08
    
Please elaborate: why? For example, why not use intptr_t, uintptr_t, size_t, or ptrdiff_t? They have been added for a reason, I reckon. And why unsigned, not signed like in the question I linked at #1? –  Virtlink Apr 10 '13 at 19:09
    
intptr_t is an integer type guaranteed to be large enough so a pointer fits. Adding offset to such a type would translate to adding (sizeof(intptr_t) * offset). As for why I would use unsigned char - it's just personal preference. Using char shouldn't really make any difference for this purpose. –  Nik Bougalis Apr 10 '13 at 19:22
2  
@Virtlink: For the purposes of C and C++, an unsigned char is a byte. The allowances in the standard for the number of bits in a char to vary are for old or esoteric platforms where the memory is organized in something like 9-bit units, not so that a C or C++ implementation can give you 16-bit char objects while addressing uses 8-bit units. –  Eric Postpischil Apr 10 '13 at 19:40
1  
@Virtlink Yes, a char doesn't need to be 8 bits, but you know what, you don't care. char is gauranteed to be the unit in which C++ measures sizes and thus the granularity of your systems addressing. And mixing code written for an 8-bit platform (and working at that low a level) with code for a 9-bit platform is hopefully something you're not planning to do. –  Christian Rau Apr 10 '13 at 19:54
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Using reinterpret_cast (or C-style cast) means circumventing the type system and is not portable and not safe. Whether it is correct, depends on your architecture. If you (must) do it, you insinuate that you know what you do and you are basically on your own from then on. So much for the warning.

If you add a number n to a pointer or type T, you move this pointer by n elements of type T. What you are looking for is a type where 1 element means 1 byte.

From the sizeof section 5.3.3.1.:

The sizeof operator yields the number of bytes in the object representation of its operand. [...] sizeof(char), sizeof(signed char) and sizeof(unsigned char) are 1. The result of sizeof applied to any other fundamental type (3.9.1) is implementation-defined.

Note, that there is no statement about sizeof(int), etc.

Definition of byte (section 1.7.1.):

The fundamental storage unit in the C++ memory model is the byte. A byte is at least large enough to contain any member of the basic execution character set (2.3) and the eight-bit code units of the Unicode UTF-8 encoding form and is composed of a contiguous sequence of bits, the number of which is implementation-defined. [...] The memory available to a C++ program consists of one or more sequences of contiguous bytes. Every byte has a unique address.

So, if sizeof returns the number of bytes and sizeof(char) is 1, than char has the size of one byte to C++. Therefore, char is logically a byte to C++ but not necessarily the de facto standard 8-bit byte. Adding n to a char* will return a pointer that is n bytes (in terms of the C++ memory model) away. Thus, if you want to play the dangerous game of manipulating an object's pointer bytewise, you should cast it to one of the char variants. If your type also has qualifiers like const, you should transfer them to your "byte type" too.

    template <typename Dst, typename Src>
    struct adopt_const {
        using type = typename std::conditional< std::is_const<Src>::value,
            typename std::add_const<Dst>::type, Dst>::type;
    };

    template <typename Dst, typename Src>
    struct adopt_volatile {
        using type = typename std::conditional< std::is_volatile<Src>::value,
            typename std::add_volatile<Dst>::type, Dst>::type;
    };

    template <typename Dst, typename Src>
    struct adopt_cv {
        using type = typename adopt_const<
            typename adopt_volatile<Dst, Src>::type, Src>::type;
    };

    template <typename T>
    T*  add_offset(T* p, std::ptrdiff_t delta) noexcept {
        using byte_type = typename adopt_cv<unsigned char, T>::type;
        return reinterpret_cast<T*>(reinterpret_cast<byte_type*>(p) + delta);
    }

Example

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if you have:

myType *ptr;

and you do:

ptr+=3;

The compiler will most certainly increment your variable by:

3*sizeof(myType)

And it's the standard way to do it as far as I know.

If you want to iterate over let's say an array of elements of type myType that's the way to do it.

Ok, if you wanna cast do that using

myNewType *newPtr=reinterpret_cast < myNewType * > ( ptr )

Or stick to plain old C and do:

myNewType *newPtr=(myNewType *) ptr;

And then increment

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1  
I know how it works when you don't cast. I want to add any byte offset (say, 0xABC bytes) to a pointer of any type MyType* regardless of its type's size. If MyType* ptr = (MyType*)0x1000 then I want to end up with ptr == (MyType*)0x1ABC. –  Virtlink Apr 10 '13 at 19:02
    
You should avoid using C-style casts in C++ for anything except perhaps numerical casts. The compiler will apply the first C++ cast that works except for dynamic_cast. One issue (among others) is that C-style casts can remove the constness of an object with no indication it's happening either in source or via a compiler diagnostic. –  Captain Obvlious Apr 10 '13 at 19:28
1  
How does this answer the question? –  JBentley Apr 10 '13 at 19:31
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