I'm getting some strange warnings about this code:

typedef double mat4[4][4];

void mprod4(mat4 r, const mat4 a, const mat4 b)
/* yes, function is empty */

int main()
    mat4 mr, ma, mb;
    mprod4(mr, ma, mb);

gcc output as follows:

$ gcc -o test test.c
test.c: In function 'main':
test.c:13: warning: passing argument 2 of 'mprod4' from incompatible pointer
test.c:4: note: expected 'const double (*)[4]' but argument is of type 'double
test.c:13: warning: passing argument 3 of 'mprod4' from incompatible pointer
note: expected 'const double (*)[4]' but argument is of type 'double

If I define the function as:

void mprod4(mat4 r, mat4 a, mat4 b)

Or defining matrices in main as:

mat4 mr;
const mat4 ma;
const mat4 mb;

Or call the function in main as:

mprod4(mr, (const double(*)[4])ma, (const double(*)[4])mb);

Or even defining mat4 as:

typedef double mat4[16];

Makes the warning go away. What is happening here? Am I doing something invalid?

The gcc version is 4.4.3, if relevant.

I also posted on gcc bugzilla: http://gcc.gnu.org/bugzilla/show_bug.cgi?id=47143

My current workaround is making ugly macros that cast stuff for me:


#define mprod4(r, a, b) mprod4(r, (const double(*)[4])a, (const double(*)[4])b)


Answer from Joseph S. Myers on gcc bugzilla:

Not a bug. The function parameters are of type "pointer to array[4] of const double" because const on an array type applies to the element type, recursively, and then the outermost array type, only, of a parameter of array type decays to a pointer, and the arguments passed are of type "pointer to array[4] of double" after array-to-pointer decay, and the only case where qualifiers are permitted to be added in assignment, argument passing etc. is qualifiers on the immediate pointer target, not those nested more deeply.

Sounds pretty confusing to me, like the function expects:

pointer to array[4] of const doubles

and we are passing

pointer to const array[4] of doubles


Or would it be the inverse? The warnings suggest that the function expects a:

const double (*)[4]

which seems to me more like a

pointer to const array[4] of doubles

I'm really confused with this answer. Could somebody who understands what he said clarify and exemplify?

  • Something is seriously wrong here. The code in the question is correct and gives no errors or warnings. The messages in the question would be produced by void mprod4(mat4 r, const double a[4][4], const double b[4][4]) , which is quite different. The "accepted" answer does not explain this at all : the accepted answer explains why T** cannot convert to const T** but that is irrelevant as that is not what's happening here (arrays and pointers are different).
    – M.M
    Mar 28, 2015 at 23:24

6 Answers 6


I believe the problem is the constraints specified in C99, which seem to prohibit mixing qualifications in assignments, except for pointers for which an inclusive-qualifier exception is defined. The problem is that with indirect pointers, you end up passing a pointer to one thing to a pointer to another. The assignment isn't valid because, if it was, you could fool it into modifying a const-qualified object with the following code:

const char **cpp;
char *p;
const char c = 'A';
cpp = &p;  // constraint violation
*cpp = &c; // valid
*p = 0;    // valid by itself, but would clobber c

It might seem reasonable that cpp, which promises not to modify any chars, might be assigned a pointer to an object pointing at non-qualified chars. After all, that's allowed for single-indirect pointers, which is why, e.g., you can pass a mutable object to the second parameter of strcpy(3), the first parameter to strchr(3), and many other parameters that are declared with const.

But with the indirect pointer, at the next level, assignment from a qualified pointer is allowed, and now a perfectly unqualified pointer assignment will clobber a qualified object.

I don't immediately see how a 2-D array could lead to this situation, but in any case it hits the same constraint in the standard.

Since in your case, you aren't actually tricking it into clobbering a const, the right thing for your code would seem to be inserting the cast.

Update: OK guys, as it happens this issue is in the C faq, and this entire discussion has also taken place several times on the gcc bug list and on the gcc mailing list.

The lesson: you can pass a T *x when const T *x is expected, by explicit exception, but T *x and const T *x are still distinct types, so you can't pass a pointer to either one to a pointer to the other.

  • See my comment below. I don't see why you think that is violated. You can add qualifiers (say, assign a non-const to a const), you just can't remove them. Jan 1, 2011 at 8:18
  • Thanks, but I see no constraint violation in your example. const char **cpp means that we are not allowed to change the memory pointed by (**cpp) right? If so, only violation here would be (**cpp) = 0. Correct me if I am wrong please.
    – pudiva
    Jan 1, 2011 at 8:23
  • +1 My conclusion is different than yours, but we both agree that this is a valid problem.
    – Chris Lutz
    Jan 1, 2011 at 10:16
  • 1
    There IS a violation of in the line "cpp=&p;", because the type pointed to by cpp (which is 'a pointer to a const char') is incompatible with the type of p ('a pointer to a char'). But this whole exercise seems irrelevant to the original problem. Jan 1, 2011 at 11:59
  • Oh, sorry, i see now why it would be bad to do this. Disregard my last comment.
    – pudiva
    Jan 1, 2011 at 13:22

To explain what Joseph said: the function is expecting a pointer to array[4] of const double to be passed in, but you're passing in a pointer to array[4] of double. These types are not compatible, so you get an error. They look like they should be compatible, but they're not.

For the purposes of passing parameters to functions (or for variable assignments), you can always convert an X to a const X, or a pointer to X to a pointer to const X for any type X. For example:

int x1 = 0;
const int x2 = x1;  // ok
int *x3 = &x1;
const int *x4 = x3;  // ok: convert "pointer to int" to "pointer to const int"
int **x5 = &x3;
const int **x6 = x5;  // ERROR: see DigitalRoss's answer
int *const *x7 = x5;  // ok: convert "pointer to (pointer to int)" to
                      //             "pointer to const (pointer to int)"

You're only allowed to add qualifiers (that is, the const, volatile, and restrict qualifiers) to the first level of pointers. You can't add them to higher levels of pointers because, as DigitalRoss mentioned, doing so would allow you to accidentally violate const-correctness. This is what Joseph means by "the only case where qualifiers are permitted to be added in assignment, argument passing etc. is qualifiers on the immediate pointer target, not those nested more deeply."

So, bringing us back to Joseph's response, you can't convert a pointer to array[4] of double to a pointer to array[4] of const double because there is no type X such that you're converting from pointer to X to pointer to const X.

If you try using array[4] of double for X, you'd see that you can convert to pointer to const array[4] of double, which is a different type. However, no such type exists in C: you can have an array of a const type, but there is no such thing as a const array.

Hence, there's no way to perfectly solve your problem. You'll have to either add casts to all of your function calls (either manually or via a macro or helper function), rewrite your functions to not take const parameters (bad since it doesn't let you pass in const matrices), or change the mat4 type to be either a 1-dimensional array or a structure, as user502515 suggested.

  • this answer is well explained. Thanks! And now I can go to sleep ;)
    – Stav Alfi
    Jan 8, 2017 at 23:35

To practically solve this, one could use a struct, and the change of double[4][4] into the a-bit-awkward double (*)[4] is avoided, and constness also works intuitively — while the same amount of memory is used:

struct mat4 {
        double m[4][4];

void myfunc(struct mat4 *r, const struct mat4 *a, const struct mat4 *b)

int main(void)
        struct mat4 mr, ma, mb;
        myfunc(&mr, &ma, &mb);
  • 1
    Thanks for teh suggestion but sorry, its very annoing to write everywere a->m[i][j]. I'm trying to do stuff in a way so I need only to write a[i][j]. In fact I know how to work around this, what bothers me is WHY this happens.
    – pudiva
    Jan 1, 2011 at 13:05
  • @rogi: Because C is a very old language, designed to compile code that was written in it thirty years ago, not deal with this newfangled const stuff. That's pretty much why.
    – Puppy
    Jan 1, 2011 at 17:17

I think in C99, you can do this, but I'm not sure it will help:

void mprod4(double mr[4][4], double ma[const 4][const 4], double mb[const 4][const 4])


I haven't got a C99 compiler handy but I remember reading something in the C99 specification regarding qualifiers within the [] for arrays as arguments. You can also put static in there (e.g. ma[static 4]) but of course that means something else.


Here it is, section paragraph 7.

A declaration of a parameter as “array of type” shall be adjusted to “qualified pointer to type”, where the type qualifiers (if any) are those specified within the [ and ] of the array type derivation. If the keyword static also appears within the [ and ] of the array type derivation, then for each call to the function, the value of the corresponding actual argument shall provide access to the first element of an array with at least as many elements as specified by the size expression.

  • Glad I revived this question. I did not know about this feature. Checking it out now...
    – Chris Lutz
    Jan 1, 2011 at 10:22
  • I'm also not sure you can typedef this since qualifiers within [] is only valid for function arguments.
    – dreamlax
    Jan 1, 2011 at 10:25
  • Haven't tested, I believe the relevant part of the standard is §, part 7: "A declaration of a parameter as "array of type" shall be adjusted to "qualified pointer to type", where the type qualifiers (if any) are those specified within the [ and ] of the array type derivation. If the keyword static also appears within the [ and ] of the array type derivation, then for each call to the function, the value of the corresponding actual argument shall provide access to the first element of an array with at least as many elements as specified by the size expression."
    – Chris Lutz
    Jan 1, 2011 at 10:32
  • @Chris Lutz: LOL I was just adding it to my answer as you commented.
    – dreamlax
    Jan 1, 2011 at 10:34
  • @dreamlax - Nice. GCC (4.0) is telling me that the second array's const isn't allowed, but it doesn't seem to be consting anything. I had to write const double ma[const 4][4] and then pass it via *(const double (*)[4][4])&a to the function to get the consting to work. :(
    – Chris Lutz
    Jan 1, 2011 at 10:40

Here's a problem (IMHO): double[4][4] in a function signature.

You know it's a double[4][4], but the compiler sees double(*)[4] in the function paramter list, which notably has no array size constraint. It turns your 2D array of 4 by 4 objects into a pointer to a 1D array of 4 objects, and the pointer can be validly indexed as if it were an array of 4 objects.

I would pass all mat4 objects by pointer:

void mprod4(mat4 *r, const mat4 *a, const mat4 *b);
// and, if you don't want to hairy your syntax
#define mprod4(r, a, b) (mprod4)(&r, (const mat4 *)&a, (const mat4 *)&b)

This will (I believe) ensure const correctness and array size correctness. It may make mprod4 a bit harder to write, and still involves some hairy casts, but it'll (IMHO) be worth it (especially after the macro above):

void mprod4(mat4 *r, const mat4 *a, const mat4 *b)
    // all indexing of the matricies must be done after dereference
    for(int i = 0; i < 4; i++) for(int j = 0; j < 4; j++)
        (*r)[i][j] = (*a)[i][j] * (*b)[i][j];
        // you could make it easier on yourself if you like:
        #define idx(a, i, j) ((*a)[i][j])
        idx(r, i, j) = idx(a, i, j) * idx(b, i, j)

It may look a bit bad when you write it, but I think it'll be cleaner type-wise. (Maybe I've been thinking C++ too much...)

  • Const correctnes is achieved by making const mat4 a. Thanks anyway for your example, maybe its better to write stuff this way.
    – pudiva
    Jan 1, 2011 at 11:17
  • Sorry, In fact const correctness wasn't achieved in my case, even though teh compiler would behave teh way i wanted it to when assigning stuff. Disregard my last comment.
    – pudiva
    Jan 2, 2011 at 3:29

Compiler is just being anal.

You're passing an argument that is essentially a non-const pointer, and the function is declared to accept a const pointer as an argument. These two are, in fact, incompatible. It is not a real problem because the compiler is still supposed to work as long as you can assign the value of the first type to the variable of the second type. Hence a warning but not an error.

EDIT: looks like gcc does not complain about other con-const to const conversions, e.g. passing char* where a const char* is expected. In this case, I'm inclined to agree that Joseph Myers from Bugzilla is correct.

  • I believe this is incorrect. The standard prohibits zillions of things that the compilers merely warn about, because they need to compile legacy code. (And because you can always tell the compiler to treat warnings as errors.) This particular case violates a constraint in the C99 standard. The reasons are complicated but I have given an example. Jan 1, 2011 at 7:57
  • Which part is incorrect? Types are incompatible according to the section of ANSI C standard. Assignment is allowed according to "both operands are pointers to qualified or unqualified versions of compatible types, and the type pointed to by the left has all the qualifiers of the type pointed to by the right." The type on the right has no qualifiers, so we're fine. Jan 1, 2011 at 8:16
  • Thanks. What you said make sense to me. I just dont see why my anal compiler warns about 2d arrays and not 1d ones.
    – pudiva
    Jan 1, 2011 at 8:26
  • Try to declare the function as "void mprod4(double* r, const double* a, const double* b)" and try to pass it a 'double*' as the second argument. Do you get the warning? Jan 1, 2011 at 8:42
  • Now I get teh warning even for teh first argument LOL. And I need it to be mat4 so I can write a[i][j] to index stuff rather than a[i*4+j] which is kinda annoying.
    – pudiva
    Jan 1, 2011 at 11:20

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