No answer has yet talked in detail about why this code may or may not be undefined behaviour.
The standard is underspecified in this area, and there is a proposal active to fix it. Under that proposal, this code would NOT be undefined behaviour, and the compilers generating code that crashes would fail to comply with the updated standard. (I revisit this in my concluding paragraph below).
But note that based on the discussion of
-D_FORTIFY_SOURCE=2 in other answers, it seems this behaviour is intentional on the part of the developers involved.
I'll talk based on the following snippet:
char *x = malloc(9);
pack *y = (pack *)x;
char *z = (char *)&y->c;
char *w = (char *)y;
Now, all three of
w refer to the same memory location, and would have the same value and the same representation. But the compiler treats
z differently to
x. (The compiler also treats
w differently to one of those two, although we don't know which as OP didn't explore that case).
This topic is called pointer provenance. It means the restriction on which object a pointer value may range over. The compiler is taking
z as having a provenance only over
x has provenance over the entire 9-byte allocation.
The current C Standard does not specify provenance very well. The rules such as pointer subtraction may only occur between two pointers to the same array object is an example of a provenance rule. Another provenance rule is the one that applies to the code we are discussing, C 6.5.6/8:
When an expression that has integer type is added to or subtracted from a pointer, the result has the type of the pointer operand. If the pointer operand points to an element of an array object, and the array is large enough, the result points to an element offset from the original element such that the difference of the subscripts of the resulting and original array elements equals the integer expression. In other words, if the expression
P points to the
i-th element of an array object, the expressions
N has the value
n) point to, respectively, the
i−n-th elements of the array object, provided they exist. Moreover, if the expression P points to the last element of an array object, the expression
(P)+1 points one past the last element of the array object, and if the expression
Q points one past the last element of an array object, the expression
(Q)-1 points to the last element of the array object. 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. If the result points one past the last element of the array object, it shall not be used as the operand of a unary
* operator that is evaluated.
The justification for bounds-checking of
memcpy always comes back to this rule - those functions are defined to behave as if they were a series of character assignments from a base pointer that's incremented to get to the next character, and the increment of a pointer is covered by
(P)+1 as discussed in this rule.
Note that the term "the array object" may apply to an object that wasn't declared as an array. This is spelled out in 6.5.6/7:
For the purposes of these operators, a pointer to an object that is not an element of an array behaves the same as a pointer to the first element of an array of length one with the type of the object as its element type.
The big question here is: what is "the array object"? In this code, is it
*y, or the actual 9-byte object returned by malloc?
Crucially, the standard sheds no light whatsoever on this matter. Whenever we have objects with subobjects, the standard does not say whether 6.5.6/8 is referring to the object or the subobject.
A further complicating factor is that the standard does not provide a definition for "array", nor for "array object". But to cut a long story short, the object allocated by
malloc is described as "an array" in various places in the standard, so it does seem that the 9-byte object here is a valid candidate for "the array object". (In fact this is the only such candidate for the case of using
x to iterate over the 9-byte allocation, which I think everyone would agree is legal).
Note: this section is very speculative and I attempt to provide an argument as to why the solution chosen by the compilers here is not self-consistent
An argument could be made that
&y->c means the provenance is the
int64_t subobject. But this does immediately lead to difficulty. For example, does
y have the provenance of
*y? If so,
(char *)y should have the the provenance
*y still, but then this contradicts the rule of 126.96.36.199/7 that casting a pointer to another type and back should return the original pointer (as long as alignment is not violated).
Another thing it doesn't cover is overlapping provenance. Can a pointer compare unequal to a pointer of the same value but a smaller provenance (which is a subset of the larger provenance) ?
Further, if we apply that same principle to the case where the subobject is an array:
char *r = (char *)arr;
++r; ++r; ++r; // undefined behavior - exceeds bounds of arr
arr is defined as meaning
&arr in this context, so if the provenance of
r is actually bounded to just the first row of the array -- perhaps a surprising result.
It would be possible to say that
char *r = (char *)arr; leads to UB here, but
char *r = (char *)&arr; does not. In fact I used to promote this view in my posts many years ago. But I no longer do: in my experience of trying to defend this position, it just can't be made self-consistent, there are too many problem scenarios. And even if it could be made self-consistent, the fact remains that the standard doesn't specify it. At best, this view should have the status of a proposal.
To finish up, I would recommend reading N2090: Clarifying Pointer Provenance (Draft Defect Report or Proposal for C2x).
Their proposal is that provenance always applies to an allocation. This renders moot all the intricacies of objects and subobjects. There are no sub-allocations. In this proposal, all of
w are identical and may be used to range over the whole 9-byte allocation. IMHO the simplicity of this is appealing, compared to what was discussed in my previous section.