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I imagine we all agree that it is considered idiomatic C to access a true multidimensional array by dereferencing a (possibly offset) pointer to its first element in a one-dimensional fashion, e.g.:

void clearBottomRightElement(int *array, int M, int N)
    array[M*N-1] = 0;  // Pretend the array is one-dimensional

int mtx[5][3];
clearBottomRightElement(&mtx[0][0], 5, 3);

However, the language-lawyer in me needs convincing that this is actually well-defined C! In particular:

  1. Does the standard guarantee that the compiler won't put padding in-between e.g. mtx[0][2] and mtx[1][0]?

  2. Normally, indexing off the end of an array (other than one-past the end) is undefined (C99, 6.5.6/8). So the following is clearly undefined:

    struct {
        int row[3];           // The object in question is an int[3]
        int other[10];
    } foo;
    int *p = &foo.row[7];     // ERROR: A crude attempt to get &foo.other[4];

    So by the same rule, one would expect the following to be undefined:

    int mtx[5][3];
    int (*row)[3] = &mtx[0];  // The object in question is still an int[3]
    int *p = &(*row)[7];      // Why is this any better?

    So why should this be defined?

    int mtx[5][3];
    int *p = &(&mtx[0][0])[7];

So what part of the C standard explicitly permits this? (Let's assume C99 for the sake of discussion.)


Note that I have no doubt that this works fine in all compilers. What I'm querying is whether this is explicitly permitted by the standard.

share|improve this question
Posting this as a comment since i'm not sure. AFAIK arrays are guaranteed to be continuous in memory whereas structs might have padding between those members. If you look at the assembler code of the array access you should be able to see that the operation performed on the [][] access is the same as *(array + x * index + y). – RedX Jun 9 '11 at 9:52
I am no language-lawyer so I will not add an answer, however, this is exactly how it works for raster imaging. Basically all you have is bytes and you know how many bytes are in a row. To go to the next row you have to offset the original pointer with the number of rows*width. So in the case of well-defined data, I would say this is perfectly fine coding. – Wouter Simons Jun 9 '11 at 9:52
@Wouter: Oh, I have no doubt that it is fine! I use this principle every day, and so does everyone else. I'm purely asking from a language-lawyer pedantry point of view! – Oliver Charlesworth Jun 9 '11 at 9:57
@Oli: Well, lawyers are horrible developers. In memory, the array has no padding and, therefore, indexing multi-dimensional arrays as single dimensional will always work. Your pointer increment is determined from the base array pointer so arr[10] must be arr + 10 * sizeof(arr) which is in the specifications I am sure. This means arr[1][5] with the second dimension always 5 long is: arr + 1 * 5 * sizeof(arrType) + 5 * sizeof (arrType)... – Wouter Simons Jun 9 '11 at 10:01
I don't have the time to write it up, but C99 paragraphs 3 and 4 seem to make this well defined – Hasturkun Jun 9 '11 at 10:06
up vote 5 down vote accepted

The only obstacle to the kind of access you want to do is that objects of type int [5][3] and int [15] are not allowed to alias one another. Thus if the compiler is aware that a pointer of type int * points into one of the int [3] arrays of the former, it could impose array bounds restrictions that would prevent accessing anything outside that int [3] array.

You might be able to get around this issue by putting everything inside a union that contains both the int [5][3] array and the int [15] array, but I'm really unclear on whether the union hacks people use for type-punning are actually well-defined. This case might be slightly less problematic since you would not be type-punning individual cells, only the array logic, but I'm still not sure.

One special case that should be noted: if your type were unsigned char (or any char type), accessing the multi-dimensional array as a one-dimensional array would be perfectly well-defined. This is because the one-dimensional array of unsigned char that overlaps it is explicitly defined by the standard as the "representation" of the object, and is inherently allowed to alias it.

share|improve this answer
Type-punning through unions is no more defined than through pointer casts, but GCC's documentation does beyond the standard for the former and guarantees that the program will do what the programmer expects. "Even with -fstrict-aliasing, type-punning is allowed, provided the memory is accessed through the union type." gcc.gnu.org/onlinedocs/gcc/Optimize-Options.html – Pascal Cuoq Jun 9 '11 at 15:40
@Pascal: C99 allows type punning through unions - this is explicitly mentioned in footnote 82 (p. 73), which was added with TC3 – Christoph Jun 10 '11 at 8:04
I was hoping that someone would answer with "No no! You're wrong! Look the standard explicitly allows it here...", but apparently not. So I've accepted this answer, as this phrases the issue (about aliasing) most succinctly. – Oliver Charlesworth Jun 10 '11 at 14:40
Note that Appendix J.2 in the standard explicitly lists this kind of OOB multi-dimensional array access as an example of UB. – R.. Jun 10 '11 at 16:27
I agree with the answer except with the part that claims that character types get away with it. Specifically when a character pointer is incremented to point to another object, in this case another element of the outer array. Can you elaborate or provide a Standard citation. 6.5 doesn't make any exceptions for char. Thanks. – 2501 2 days ago

All arrays (including multidimensional ones) are padding-free. Even if it's never explicitly mentioned, it can be inferred from sizeof rules.

Now, array subscription is a special case of pointer arithmetics, and C99 section 6.5.6, §8 states clearly that behaviour is only defined if the pointer operand and the resulting pointer lie in the same array (or one element past), which makes bounds-checking implementations of the C language possible.

This means that your example is, in fact, undefined behaviour. However, as most C implementations do not check bounds, it will work as expected - most compilers treat undefined pointer expressions like

mtx[0] + 5 

identically to well-defined counterparts like

(int *)((char *)mtx + 5 * sizeof (int))

which is well-defined because any object (including the whole two-dimensional array) can always be treated as a one-dimensinal array of type char.

On further meditation on the wording of section 6.5.6, splitting out-of-bounds access into seemingly well-defined subexpression like

(mtx[0] + 3) + 2

reasoning that mtx[0] + 3 is a pointer to one element past the end of mtx[0] (making the first addition well-defined) and as well as a pointer to the first element of mtx[1] (making the second addition well-defined) is incorrect:

Even though mtx[0] + 3 and mtx[1] + 0 are guaranteed to compare equal (see section 6.5.9, §6), they are semantically different. For example, the former can't be dereferenced and thus does not point to an element of mtx[1].

share|improve this answer
I agree with most of what you said. I'm not sure I can agree with the notion that (mtx[0] + 3) + 2) is valid, because all out-of-bounds pointer additions could be recursively expressed as (((p+1)+1)+1) etc. And if it were well-defined to express them this way, then what would be the point of 6.5.6/8? – Oliver Charlesworth Jun 9 '11 at 10:56
@Oli: C arithmetics is not associative - (a+b)+c is not necessarily identical to a+(b+c); the crux of the matter is that in case of multi-dimensional arrays, a pointer can 'belong' to two arrays at the same time, and pointer arithmetic does not keep track of the originating array, so you only have to validate each subexpression; as far as I can tell, it is indeed possible to iterate over a multi-dimensional array by single-step increments – Christoph Jun 9 '11 at 11:26
@Christoph: I agree with your point about associativity. I guess the only point remaining is whether it's valid to alias an object with a pointer to the one-past-the-end element for the previous object. For example, in my struct example, is the behaviour well-defined for an implementation that guarantees no padding between row and other? – Oliver Charlesworth Jun 9 '11 at 11:34
@Oli: upon re-reading section 6.5.6 and some further meditation, I changed my mind ;) pointers past the last element of an array are 'special' and can't be used in the way I originally described – Christoph Jun 9 '11 at 12:18
Yes the pointer addition is what's potentially problematic. Note that it's not a problem if the base type is a char type, since then any pointer into it is also a pointer into the representation array, which is an array of type unsigned char [sizeof whole_multi_dim_array], and thus all the arithmetic is valid. – R.. Jun 9 '11 at 12:19
  1. It is sure that there is no padding between the elements of an array.

  2. There are provision for doing address computation in smaller size than the full address space. This could be used for instance in the huge mode of 8086 so that the segment part would not always be updated if the compiler knew that you couldn't cross a segment boundary. (It's too long ago for me to remind if the compilers I used took benefit of that or not).

With my internal model -- I'm not sure it is perfectly the same as the standard one and it is too painful to check, the information being distributed everywhere --

  • what you are doing in clearBottomRightElement is valid.

  • int *p = &foo.row[7]; is undefined

  • int i = mtx[0][5]; is undefined

  • int *p = &row[7]; doesn't compile (gcc agree with me)

  • int *p = &(&mtx[0][0])[7]; is in the gray zone (last time I checked in details something like this, I ended up by considering invalid C90 and valid C99, it could be the case here or I could have missed something).

share|improve this answer
You're right, I got the syntax wrong for int *p = &row[7]. I will edit my question. – Oliver Charlesworth Jun 9 '11 at 10:17
What I'm really looking for is an argument based on the wording in the standard... – Oliver Charlesworth Jun 9 '11 at 10:20

My understanding of the C99 standard is that there is no requirement that multidimensional arrays must be laid out in a contiguous order in memory. Following the only relevant information I found in the standard (each dimension is guaranteed to be contiguous).

If you want to use the x[COLS*r + c] access, I suggest you stick to single dimension arrays.

Array subscripting

Successive subscript operators designate an element of a multidimensional array object. If E is an n-dimensional array (n ≥ 2) with dimensions i × j × . . . × k, then E (used as other than an lvalue) is converted to a pointer to an (n − 1)-dimensional array with dimensions j × . . . × k. If the unary * operator is applied to this pointer explicitly, or implicitly as a result of subscripting, the result is the pointed-to (n − 1)-dimensional array, which itself is converted into a pointer if used as other than an lvalue. It follows from this that arrays are stored in row-major order (last subscript varies fastest).

Array type

— An array type describes a contiguously allocated nonempty set of objects with a particular member object type, called the element type. 36) Array types are characterized by their element type and by the number of elements in the array. An array type is said to be derived from its element type, and if its element type is T , the array type is sometimes called ‘‘array of T ’’. The construction of an array type from an element type is called ‘‘array type derivation’’.

share|improve this answer
Exactly, so if you treat a contiguous memory buffer as multidimensional array, it is fine, but the other way around it might not be fine. That sounds about right to me. – Wouter Simons Jun 9 '11 at 11:00
@nimrodm: Your interpretation of the standard largely matches mine. (Which is reassuring, I guess!) – Oliver Charlesworth Jun 9 '11 at 11:06
The first sentence is blatantly false. The layout in memory is exactly determined by the semantics of sizeof and pointer arithmetic. It's only due to the aliasing rules that this usage is undefined, and thus only for non-char types. – R.. Jun 9 '11 at 12:15
I disagree about the mutli-dimensions not requiring to be contiguous. An array with 3 elements inside an array with 3 elements (arr[3][3]) will have to be contiguous to match the description else the second "array" (the one containing the other 3 arrays) would not be allowed to call itself an array since it's layout would not be contiguous. The "inner" array (arr[3]) has array of X whereas the "outer" array is an array of X[sizeof("inner array")]. – RedX Jun 9 '11 at 12:20
It's the latter - an array of int[3] objects. – R.. Jun 10 '11 at 1:50

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