# Cast Array to Matrix in C/C++?

If I have a function which internally uses a 3x3 matrix, but due to API limitations must pass it a contiguous array of nine elements, is there a way to essentially cast an array to a 2d array?

The following approach doesn't work, but hopefully it conveys what I'm trying to do.

I'm aware that packages like Eigen make this trivial, but unfortunately it's not an option for me in this case.

``````void transpose_3x3( double x[3][3] ) {
...
}

void foo( double x[9], double y[3][3] ) {

transpose_3x3(y)  // OK

double *my_x[3][3] = &x[0];

transpose_3x3(&my_x);  // How?

}
``````

Edit

Thanks to Daniel for showing me the correct target for a cast, I was able to use the C++ reinterpret_cast function to accomplish this. While the union and memcpy solutions work, a single explicit cast seems to be the most straightforward solution, IMHO.

``````#include <iostream>

void print_matrix( double x[3][3] ) {

for(unsigned int i=0; i< 3; i++) {
for(unsigned int j=0; j<3; j++) {
std::cout << x[i][j] << "  ";
}
std::cout << std::endl;
}
}

int main() {

double a[9] = { 1, 2, 3, 4, 5, 6, 7, 8, 9};
double (*b)[3] = reinterpret_cast<double (*)[3]>(a);

print_matrix(b);
return 0;
}
``````
-
Do you want C, or C++ answer? Choose one, you cannot, generally, have both. –  Griwes Jan 9 at 23:08
@Griwes: Unless you need a solution that can be compiled as both ... –  Goz Jan 9 at 23:13
@Goz, which proves that you are doing something very wrong. –  Griwes Jan 9 at 23:13
@Griwes or you are using header files used by both languages, which is quite common. –  user142019 Jan 9 at 23:15
@RobFalck All you need is a simple cast, you just have to cast to the right type. –  Daniel Fischer Jan 10 at 1:17

``````void transpose_3x3( double x[3][3] ) {
...
}
``````

Note that the first dimension `3` is ignored. The type of `transpose_3x3` is really

``````void transpose_3x3(double (*)[3])
``````

And that tells us how to proceed, you have to cast `x` to a `double (*)[3]`, a pointer to an array of three `double`s.

``````void foo(double x[9], double y[3][3]) {
// Note that the actual types of the parameters are
// double *x
// double (*y)[3]

transpose_3x3(y);
transpose_3x3((double(*)[3])x);
}
``````

Of course, passing a cast `x` will wreak havoc if the passed-in `x` is shorter than 9 elements, but that would also be the case if `y` is too short.

-
Thank you. I was unable to figure out the proper syntax of the destination of the cast. It seems that the way to do this using the C++ casting functions would be: double (b)[3] = reinterpret_cast<double ()[3]>(a) where a is `double a[3]` –  Rob Falck Jan 10 at 14:15
Yup. That or a C-style cast. –  Daniel Fischer Jan 10 at 14:28
@DanielFischer +1 for the interesting C-style casting. Compiles both as C and C++! –  informatik01 Jan 10 at 15:33

I can't think of a way to do an explicit cast.

However you could just memcpy it. Calls to memcpy are not as stupid as you may think. The compiler will often see that the 2 bits of data actually represent the same thing and that the memcpy is a fixed size and optimise out the actual copy.

I must say I've never tried it with something quite so large as the matrix you are doing but I can't see why it wouldn't work.

Edit: In fact I thought I'd give it a try. I wrote the following code:

``````void transpose_3x3( double (*x)[3][3] )
{
const double t01    = (*x)[0][1];
const double t02    = (*x)[0][2];
const double t12    = (*x)[1][2];
(*x)[0][1] = (*x)[1][0];
(*x)[0][2] = (*x)[2][0];
(*x)[1][0] = t01;
(*x)[1][2] = (*x)[2][1];
(*x)[2][0] = t02;
(*x)[2][1] = t12;
}

void foo()
{
double x[9] = { 1.0f, 2.0f, 3.0f,
4.0f, 5.0f, 6.0f,
7.0f, 8.0f, 9.0f };

double y[3][3];
memcpy( y, x, sizeof( double ) * 9 );

transpose_3x3( &y );

printf( "%f, %f, %f\n", y[0][0], y[0][1], y[0][2] );
printf( "%f, %f, %f\n", y[1][0], y[1][1], y[1][2] );
printf( "%f, %f, %f\n", y[2][0], y[2][1], y[2][2] );
}
``````

And built it in release mode with VS2010.

The resulting assembly is as follows:

``````void foo()
{
00E11000  push        ebp
00E11001  mov         ebp,esp
00E11003  and         esp,0FFFFFFC0h
00E11006  sub         esp,0B8h
double x[9] = { 1.0f, 2.0f, 3.0f,
00E1100C  fld1
00E1100E  push        esi
00E1100F  fstp        qword ptr [esp+2Ch]
00E11013  push        edi
00E11014  fld         qword ptr [__real@4000000000000000 (0E12138h)]
4.0f, 5.0f, 6.0f,
7.0f, 8.0f, 9.0f };

double y[3][3];
memcpy( y, x, sizeof( double ) * 9 );

transpose_3x3( &y );

printf( "%f, %f, %f\n", y[0][0], y[0][1], y[0][2] );
00E1101A  sub         esp,18h
00E1101D  fstp        qword ptr [esp+50h]
00E11021  mov         ecx,12h
00E11026  fld         qword ptr [__real@4008000000000000 (0E12130h)]
00E1102C  lea         esi,[esp+48h]
00E11030  fstp        qword ptr [esp+58h]
00E11034  lea         edi,[esp+90h]
00E1103B  fld         qword ptr [__real@4010000000000000 (0E12128h)]
00E11041  fst         qword ptr [esp+60h]
00E11045  fld         qword ptr [__real@4014000000000000 (0E12120h)]
00E1104B  fstp        qword ptr [esp+68h]
00E1104F  fld         qword ptr [__real@4018000000000000 (0E12118h)]
00E11055  fstp        qword ptr [esp+70h]
00E11059  fld         qword ptr [__real@401c000000000000 (0E12110h)]
00E1105F  fst         qword ptr [esp+78h]
00E11063  fld         qword ptr [__real@4020000000000000 (0E12108h)]
00E11069  fstp        qword ptr [esp+80h]
00E11070  fld         qword ptr [__real@4022000000000000 (0E12100h)]
00E11076  fstp        qword ptr [esp+88h]
00E1107D  rep movs    dword ptr es:[edi],dword ptr [esi]
00E1107F  fstp        qword ptr [esp+10h]
00E11083  fstp        qword ptr [esp+8]
00E11087  fld         qword ptr [esp+90h]
00E1108E  fstp        qword ptr [esp]
00E11091  mov         esi,dword ptr [__imp__printf (0E120A0h)]
00E11097  push        offset string "%f, %f, %f\n" (0E120F4h)
00E1109C  call        esi
printf( "%f, %f, %f\n", y[1][0], y[1][1], y[1][2] );
00E110A1  fld         qword ptr [esp+0C8h]
00E110A8  fstp        qword ptr [esp+10h]
00E110AC  fld         qword ptr [esp+0B0h]
00E110B3  fstp        qword ptr [esp+8]
00E110B7  fld         qword ptr [__real@4000000000000000 (0E12138h)]
00E110BD  fstp        qword ptr [esp]
00E110C0  push        offset string "%f, %f, %f\n" (0E120F4h)
00E110C5  call        esi
printf( "%f, %f, %f\n", y[2][0], y[2][1], y[2][2] );
00E110C7  fld         qword ptr [esp+0D4h]
00E110D1  fstp        qword ptr [esp+10h]
00E110D5  fld         qword ptr [__real@4018000000000000 (0E12118h)]
00E110DB  fstp        qword ptr [esp+8]
00E110DF  fld         qword ptr [__real@4008000000000000 (0E12130h)]
00E110E5  fstp        qword ptr [esp]
00E110E8  push        offset string "%f, %f, %f\n" (0E120F4h)
00E110ED  call        esi
}
``````

You'll note that there is no memcpy. Actually all its doing is manually copying the matrix from x into y and then printing it in a transposed fashion. Basically its interesting seeing what things the compiler will do to optimise things out ...

Edit 2: Of course thinking a bit further after seeing paddy's excellent response it occurs to me that you could just case the thing directly

``````transpose_3x3( (double (*)[3][3])&x );
``````

Which works without memcpy or the union :D

-

Well, this is a little dirty, but you could use a `union` with casting. Someone's going to tell me off for this but I'll post it anyway =)

``````#include <iostream>

using namespace std;

typedef union {
double linear[9];
double square[3][3];
} Matrix;

void transpose_3x3( double x[3][3] )
{
for( int i = 0; i < 3; i++ ) {
for( int j = 0; j < 3; j++ ) {
cout << i << "," << j << ": " << x[i][j] << endl;
}
}
}

void foo( double x[9], double y[3][3] )
{
transpose_3x3( y );
transpose_3x3( ((Matrix*)x)->square );
}

int main()
{
double x[9] = { 1, 2, 3, 4, 5, 6, 7, 8, 9 };
double y[3][3] = { {1, 2, 3}, {4, 5, 6}, {7, 8, 9} };
foo( x, y );
return 0;
}
``````
-
Time to remove the C++ tag from OP's question? Because this is turning into a C memory hack contest, and leaves a lot ask for in terms of good maintainable C++ code. –  gustaf r Jan 9 at 22:58
`union` is just as valid a construct in C++ as it is in C. And if the `Matrix` type is used everywhere instead of arrays, this won't look quite so evil. I'm trying not to troll here, but am aware that I may inadvertently be doing so. –  paddy Jan 9 at 23:06
Its a good solution! –  Goz Jan 9 at 23:07
I like this solution (it taught me something I didn't know before) but for my specific purposes I think Daniel's solution, posed as a reinterpret_cast, works best for me. –  Rob Falck Jan 10 at 14:21
Glad it was helpful. Unions are cool, but there are some upsetting rules in the C standard (to do with not reading from a different member after writing to another) that make them a point of contention. But when you're casting from some memory buffer, the compiler can't know the difference, so I've always felt it should work despite these strictures. And in practice I've found that it does. –  paddy Jan 10 at 19:47

Since you have added the tag for C++, I recommend you write your own matrix class which does this by providing helper functions to access the data with {x, y} parameters as well as with a {contiguous x} parameter.

The code you write is not something you usually see in programs written in C++, since you can achieve the same logic much cleaner and safer.

-
While this is true, the comment "Eigen [...] [is] not an option for me in this case" implies that he has to stick to some legacy/C code. –  Zeta Jan 9 at 22:44
@Zeta, I'm not really following your assumption that far. Anyway, why the C++ tag then? –  gustaf r Jan 9 at 22:47

You can define a pointer to a matrix as follow:

``````int (*matrix)[M][N];
``````

If you have an array M*N, then we can basically create a pointer to an object M*N: The native matrix supported by C isn't multidimensional.

``````int array[M*N]
int (*matrix)[M][N] = (int (*)[M][N]) array;
``````

If you want to access an element from the matrix, then you can create a function which will simplify the repetitive work.

``````int get(int (*matrix)[M][N], int i, int j) { return (*matrix)[i][j]; }
``````
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