Consider the following code:

int a[25][80];
a[0][1234] = 56;
int* p = &a[0][0];
p[1234] = 56;

Does the second line invoke undefined behavior? How about the fourth line?

  • as array bounds are not checked so it should no give any error! – teacher Sep 1 '11 at 10:40
  • int a[25][80] is allocating a memory of 80*25*4 bytes, and its a contiguous memory allocation so if you are accessing a[0][1234] actually you are accessing memory at 1234 from base address! line 4 is not giving you error is because a[0][1234] = *((*a)+1234) =p[1234]; – teacher Sep 1 '11 at 10:45
  • Thanks for getting this sorted out! I hope someone follows this up with the similar question about std::array<T,N>. I should point out that this question was motivated by a follow-up of the OP of this question -- I've encouraged him to ask about std::array separately, though. – Kerrek SB Sep 1 '11 at 10:55
  • @teacher — Actually, int a[25][80] is of size 80*25*sizeof(int) bytes, which just might happen on most systems to be 80*25*4 bytes. – Todd Lehman Jun 28 '14 at 7:06

It's up to interpretation. While the contiguity requirements of arrays don't leave much to the imagination in terms of how to layout a multidimensional arrays (this has been pointed out before), notice that when you're doing p[1234] you're indexing the 1234th element of the zeroth row of only 80 columns. Some interpret the only valid indices to be 0..79 (&p[80] being a special case).

Information from the C FAQ which is the collected wisdom of Usenet on matters relevant to C. (I do not think C and C++ differ on that matter and that this is very much relevant.)

  • I think there is a signficiant difference between C and C++ here, as C99 includes the text in 6.5.6#8, "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". Therefore &a[0][0] + 80 is not semantically identical to &a[1][0], because the former shall not dereferenced via * but the latter can be. C++ does not have that text and (AFAICS) appears to leave unanswered the issue of when past-the-end iterators may be dereferenced. – M.M Jun 20 '14 at 0:33

Yes, you can(no, it's not UB), it is indirectly guaranteed by the standard. Here's how: a 2D array is an array of arrays. An array is guaranteed to have contiguous memory and sizeof(array) is sizeof(elem) times number of elements. From these it follows that what you're trying to do is perfectly legal.

  • 5
    Guaranteed to work isn't the same as guaranteed to be defined. – Lightness Races in Orbit Sep 1 '11 at 10:42
  • 2
    @kgadek: You're wrong. It's an array of arrays. – Lightness Races in Orbit Sep 1 '11 at 10:42
  • 1
    @Tomalak: Yes, it is. Guaranteed to work in a certain way means being defined – Armen Tsirunyan Sep 1 '11 at 10:44
  • 10
    §5.7/5 "When an expression that has integral 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 integral expression." (emphasis mine) Is this relevant? Specially given the fact that the first array object (a[0]) is not large enough for the index 1234. – R. Martinho Fernandes Sep 1 '11 at 11:03
  • 3
    @Armen: Guaranteed to appear to work isn't the same as guaranteed to be defined.* See Mr Fernandes's quotation. – Lightness Races in Orbit Sep 1 '11 at 11:31

Both lines do result in undefined behavior.

Subscripting is interpreted as pointer addition followed by an indirection, that is, a[0][1234]/p[1234] is equivalent to *(a[0] + 1234)/*(p + 1234). According to [expr.add]/4 (here I quote the newest draft, while for the time OP is proposed, you can refer to this comment, and the conclusion is the same):

If the expression P points to element x[i] of an array object x with n elements, the expressions P + J and J + P (where J has the value j) point to the (possibly-hypothetical) element x[i+j] if 0≤i+j≤n; otherwise, the behavior is undefined.

since a[0](decayed to a pointer to a[0][0])/p points to an element of a[0] (as an array), and a[0] only has size 80, the behavior is undefined.

As Language Lawyer pointed out in the comment, the following program does not compile.

constexpr int f(const int (&a)[2][3])
    auto p = &a[0][0];
    return p[3];

int main()
    constexpr int a[2][3] = { 1, 2, 3, 4, 5, 6, };
    constexpr int i = f(a);

The compiler detected such undefined behaviors when it appears in a constant expression.

  • Does "launder" factor into this? Certainly a function which is supposed to operate on all the bytes of an object (e.g. fwrite or variations thereof) should be able to write out everything in a PODS, even if the PODS happens to start with a two-dimensional array. Deprecating code that does such things without laundering pointers might make sense (though quality compilers should offer an option to keep processing code according to old rules in exchange for some efficiency loss), but there must be some way to get a pointer that can access an entire item. – supercat Jun 11 '18 at 16:22
  • @supercat Maybe you are looking for this question? – xskxzr Jun 11 '18 at 17:09
  • @supercat By the way, this question is about type punning for int array (not about the underlying object representation), and the standard clearly makes it undefined. – xskxzr Jun 11 '18 at 17:16
  • That other question didn't say anything about laundering. nor do the rules about indexing say anything special about character types. IMHO, the character-type exception is one of the worst things that ever happened to the C programming language (or its offshoot C++), since it needlessly blocks what should be useful optimizations even though there was never any need to treat character types differently from any other type that has no padding bits or trap representations. – supercat Jun 11 '18 at 17:31
  • @supercat That problem cannot be resolved with launder, the key is whether there is an underlying char array for object representation. This answer shows the particularity of char*. – xskxzr Jun 11 '18 at 17:35

In the language the Standard was written to describe, there would be no problem with invoking a function like:

void print_array(double *d, int rows, int cols)
  int r,c;
  for (r = 0; r < rows; r++)
    printf("%4d: ", r);
    for (c = 0; c < cols; c++)
      printf("%10.4f ", d[r*cols+c]);

on a double[10][4], or a double[50][40], or any other size, provided that the total number of elements in the array was less than rows*cols. Indeed, the guarantee that the row stride of a T[R][C] would equal C * sizeof (T) was designed among other things to make it possible to write code that could work with arbitrarily-sized multi-dimensional arrays.

On the other hand, the authors of the Standard recognized that when implementations are given something like:

double d[10][10];
double test(int i)
  d[1][0] = 1.0;
  d[0][i] = 2.0;
  return d[1][0]; 

allowing them to generate code that would assume that d[1][0] would still hold 1.0 when the return executes, or allowing them to generate code that would trap if i is greater than 10, would allow them to be more suitable for some purposes than requiring that they silently return 2.0 if invoked with i==10.

Nothing in the Standard makes any distinction between those scenarios. While it would have been possible for the Standard to have included rules that would say that the second example invokes UB if i >= 10 without affecting the first example (e.g. say that applying [N] to an array doesn't cause it to decay to a pointer, but instead yields the Nth element, which must exist in that array), the Standard instead relies upon the fact that implementations are allowed to behave in useful fashion even when not required to do so, and compiler writers should presumably be capable of recognizing situations like the first example when doing so would benefit their customers.

Since the Standard never sought to fully define everything that programmers would need to do with arrays, it should not be looked to for guidance as to what constructs quality implementations should support.

  • The C-faq from the accepted answer says your first example is not in strict conformance with the ANSI C Standard. – xskxzr Apr 11 at 8:58
  • @xskxzr: I said in the language the Standard was written to describe. The authors of the Standard have never made any effort to exhaustively catalog and mandate support for all the constructs that existing implementations processed usefully, and that they expected future implementations to process likewise whether mandated or not. The only time they thought mandates would matter would be when a compiler writer reasonably judged that its customers could benefit from having it do something different, in which case allowing the other behavior would be better than forbidding it. – supercat Apr 11 at 15:01
  • @xskxzr: The authors of the Standard recognized that given int a[10][10]; ... a[i][j]=23;, it would be useful for some purposes to allow compilers to squawk if j exceeds 9. That in no way implies that they did not equally recognize that it would be useful for compilers to usefully process code like the first example above. Fundamentally, they recognized that programmers (and by extension, compiler writers honoring the Spirit of C "trust the programmer") were better placed than the Committee to know when each approach would best help them "do what needs to be done". – supercat Apr 11 at 15:23

You're free to reinterpret the memory any way you'd like. As long as the multiple does not exceed the linear memory. You can even move a to 12, 40 and use negative indexes.


Your compiler will throw a bunch of warnings/errors because of subscript out of range (line 2) and incompatioble types (line 3), but as long as the actual variable (int in this case) is one of the intrinsic base-types this is save to do in C and C++. (If the variable is a class/struct it will probably still work in C, but in C++ all bets are off.)

Why you would want to do this.... For the 1st variant: If your code relies on this sort of messing about it will be error-prone and hard to maintain in the long run.

I can see a some use for the second variant when performance optimizing loops over 2D arrays by replacing them by a 1D pointer run over the data-space, but a good optimizing compiler will often do that by itself anyway. If the body of the loop is so big/complex the compiler can't optimize/replace the loop by a 1D run on it's own, the performance gain by doing it manually will most likely not be significant either.

  • 1
    There are situations (granted, not frequent) where you need to reshape your data as a different kind of array, not for performance reasons, but from the mathematical interpretation behind the algorithm. You can do that without casts, but using them may lead to code that is easier to read. This kind of casting is pretty close to what, e.g., MATLAB's reshape function does. – Christopher Creutzig Sep 1 '11 at 11:02

The memory referenced by a is both a int[25][80] and a int[2000]. So says the Standard, 3.8p2:

[ Note: The lifetime of an array object starts as soon as storage with proper size and alignment is obtained, and its lifetime ends when the storage which the array occupies is reused or released. 12.6.2 describes the lifetime of base and member subobjects. — end note ]

a has a particular type, it is an lvalue of type int[25][80]. But p is just int*. It is not "int* pointing into a int[80]" or anything like that. So in fact, the int pointed to is an element of int[25][80] named a, and also an element of int[2000] occupying the same space.

Since p and p+1234 are both elements of the same int[2000] object, the pointer arithmetic is well-defined. And since p[1234] means *(p+1234), it too is well-defined.

The effect of this rule for array lifetime is that you can freely use pointer arithmetic to move through a complete object.

Since std::array got mentioned in the comments:

If one has std::array<std::array<int, 80>, 25> a; then there does not exist a std::array<int, 2000>. There does exist a int[2000]. I'm looking for anything that requires sizeof (std::array<T,N>) == sizeof (T[N]) (and == N * sizeof (T)). Absent that, you have to assume that there could be gaps which mess up traversal of nested std::array.

  • 3
    The elements of an int[25][80] are int[80]'s .Not int. There is no int[2000] object. I'm not sure what the relevance of the text you quoted is supposed to be; an aggregate and its subobjects are all allocated and released simultaneously. – M.M Jun 20 '14 at 0:28
  • @MattMcNabb: How can you claim there is no int[2000] object, when the rules say that the lifetime has started? (Clearly "storage with proper size and alignment is obtained" has been satisfied) – Ben Voigt Jun 20 '14 at 0:34
  • There's no declaration or otherwise of an int[2000]. So there is no such object. (Let alone an object with whatever lifetime). Storage has been obtained for an int[25][80]. That's the same amount of storage as an int[2000] would take, but so what? long[1000] also has the same amount of storage (on some systems) – M.M Jun 20 '14 at 0:35
  • @Matt: So if I wrote int* q = *reinterpret_cast<int(*)[2000]>(p); would that make any difference? Now an int[2000] has been declared (and decayed right back to a pointer). Yes, long[1000] has the same amount of storage, but if you use int[1000] to access long[1000] you can't subscript it without violating strict-aliasing rules, because there are no int objects, only long objects. – Ben Voigt Jun 20 '14 at 0:41
  • @MattMcNabb: But the strict aliasing rule only applies to the int objects which are finally accessed by dereferencing the int*, and those int objects definitely do exist. Also, would it make a difference to you if I wrote int* q = new (p) int[2000];? But my Standard quote says placement-new (to run a constructor) isn't needed for arrays, they exist as soon as storage is obtained. – Ben Voigt Jun 20 '14 at 0:45

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