Unfortunately, I haven't found anything like std-discussion for the ISO C standard, so I'll ask here.

Before answering the question, make sure you are familiar with the idea of pointer provenance (see DR260 and/or http://www.open-std.org/jtc1/sc22/wg14/www/docs/n2263.htm). paragraph 7 says:

When a pointer to an object is converted to a pointer to a character type, the result points to the lowest addressed byte of the object. Successive increments of the result, up to the size of the object, yield pointers to the remaining bytes of the object.

The questions are:

  1. What does "a pointer to an object" mean? Does it mean that if we want to get the pointer to the lowest addressed byte of an object of type T, we shall convert a pointer of type cvT* to a pointer to a character type, and converting a pointer to void, obtained from the pointer of type T*, won't give us desired result? Or "a pointer to an object" is the value of a pointer which follows from the pointer provenance and cast to void* does not change the value (analogous to how it was recently formalized in C++17)?

  2. Why the paragraph explicitly mentions increments? Does it mean that adding value greater than 1 is undefined? Does it mean that decrementing (after we have incremented the result several times so that we won't go beyond the lower object boundary) is undefined? In short: is the sequences of bytes composing an object an array?

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    "a pointer to an object" --> a pointer to some non-function, non-void . – chux - Reinstate Monica Aug 16 '18 at 0:08
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    "cast to void* does not change the value" is almost correct. The encoding may change, yet it will equate to the original. Akin to 10 == 10.0 but they have different encodings. Pointers have different properties than integers. There are many questions here - at least 7. Perhaps reduce it. – chux - Reinstate Monica Aug 16 '18 at 0:14
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    While a reasonable person might question the validity of "increment by -1" (rather than "decrement by 1"), I think it's safe to say that you can increment by any positive number. i+=5;//a stupid but accurate comment here is 'increment by 5'. Regarding your very last question, are you specifically wanting to know if if the bytes are contiguous and CAN be treated as a C-array, or are you driving at something different? – zzxyz Aug 16 '18 at 0:39
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    @zzxyz I don't think that you can increment by any positive number. The standard defines increment in (postfix) and in (prefix). I believe it is not correct to invent your own meaning for terms defined in the standard. – A language lawyer Aug 16 '18 at 0:49
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    @M.M If I understand you correctly, you are trying to say that the omission of an explicit definition of behavior does not make it undefined. Well, the standard explicitly states the opposite. – A language lawyer Aug 16 '18 at 8:36

The general description of pointer addition suggests that for any values/types of pointer p and signed integers x and y where ((ptr+x)+y) and (x+y) are both defined by the Standard, (ptr+(x+y)) would behave equivalent to ((ptr+x)+y). While it might be possible to argue that the Standard doesn't explicitly say that incrementing a pointer five times would be equivalent to adding 5, there is nothing in the Standard that would suggest that quality implementations should not be expected to behave in that fashion.

Note that the authors of the Standard didn't try to make it "language-lawyer-proof". Further, they didn't think anyone would care about whether or not an obviously-inferior implementation was "conforming". An implementation that only works reliably if bytes of an object are accessed sequentially would be less versatile than one which supported reliable indexing, while offering no plausible advantage. Consequently, there should be no need for the Standard to mandate support for indexing, because anyone trying to produce a quality implementation would support it whether the Standard mandated it or not.

Of course, there are some constructs which programmers in the 1990s--or even the authors of the Standard themselves--expected quality compilers to handle reliably, but which some of today's "clever" compilers don't. Whether that means such expectations were unreasonable, or whether they remain accurate when applied to quality compilers, is a matter of opinion. In this particular case, I think the implication that positive indexing should behave like repeated incrementing is strong enough that I wouldn't expect compiler writers to argue otherwise, but I'm not 100% certain that no compiler would ever be "clever"/obtuse enough to look at something like:

int test(unsigned char foo[5][5], int x)
  foo[1][0] = 1;

  // Following should yield a pointer that can be used to access the entire
  // array 'foo', but an obtuse compiler writer could perhaps argue that the
  // code is converting the address of foo[0] into a pointer to the first
  // element of that sub-array, and that the resulting pointer is thus only
  // usable to access items within that sub-array.

  unsigned char *p = (unsigned char*)foo;

  // Following should be able to access any element of the object [i.e. foo]
  // whose address was taken

  p[x] = 2;

  return foo[1][0];

and decide that it could skip the second read of foo[1][0] since p[x] wouldn't possibly access any element of foo beyond the first row. I would, however, say that programmers should not try to code around the possibility of vandals writing a compiler that would behave that way. No program can be made bullet-proof against vandals writing obtuse-but-"conforming" compilers, and the fact that a program can be undermined by such vandals should hardly be viewed as a defect.

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  • Great answer. There's a recent related question (for C++) here. Biggest difference in that case being that the behavior is explicitly called out as undefined: stackoverflow.com/questions/51623643/… – zzxyz Aug 16 '18 at 18:11
  • @zzxyz: I don't see what the question about delete has to do with accessing the bytes of an object? Did you copy the wrong link? – supercat Aug 16 '18 at 19:02
  • No I didn't, but I should've clarified what I see as the similarity, which is this: The point at which common sense tells you the compiler should be treating a pointer as "just an integer" (or perhaps "just a void*") is not guaranteed. Some of the comments and answers specifically call that out (regardless of the non-existence of custom destructors). – zzxyz Aug 16 '18 at 19:12
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    @zzxyz: The C89 Standard would have been a fair bit bigger if the authors had tried to enumerate all behavioral guarantees a quality compiler should uphold, including those where (1) all existing compilers upheld them; (2) the easiest way of upholding other parts of the Standard would also uphold the guarantees in question. The authors didn't think anyone would care whether a compiler that behaved in deliberately-less-than-ideal fashion would be "conforming", since they didn't think anyone would try to use the Standard to justify their behavior. – supercat Aug 16 '18 at 19:55

Take a non-char c object and create a pointer to it, i.e.

int obj;
int *objPtr = &obj;

convert the pointer to object to pointer to char:

char *charPtr = (char *)objPtr;

now, charPtr points to the lowest byte or the int obj. increment it:


now it points to the next byte of the object. and so on till you reach the size of the object:

int i;
for (i = 0; i < sizeof(obj); i++) 
    printf("%d", *charPtr++);
| improve this answer | |
  • If you change to char *charPtr = (char *)((void*)objPtr);, where the charPtr will point to? Why? – A language lawyer Aug 16 '18 at 1:02
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    This is not an answer to any of the questions. – A language lawyer Aug 16 '18 at 1:21
  • This question is not about accessing the bytes that represent an object. It is asking about specific details in the language of the C standard. For example, if you convert a pointer to an object to a pointer to void, is it still a “pointer to an object”? That is, is the void *, for the purposes of C 2018 7, a pointer to the same object as the original pointer, regardless of the type? (We are not asking if it can be dereferenced while it is a void *, just whether it still qualifies for the conversion semantics specified in 7.) – Eric Postpischil Aug 16 '18 at 4:32
  • To be more specific, given the charPtr initialized above, the standard clearly says we can access the bytes repeatedly via *charPtr++. But does it says we can access a byte via charPtr[2]? There are no successive increments in that, so the language in 7 does not say so explicitly. That is one of the things the question is getting at. – Eric Postpischil Aug 16 '18 at 4:53

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