So, if I'm understanding correctly, what you want are three `r`

x `r`

arrays (`a`

, `b`

, and `c`

), but you want all three of them stored contiguously; essentially, the backing store will be a single 3 x `r`

x `r`

array.

If the size `r`

is not known at compile time *and* you're working in C99 or a C11 implementation that supports variable-length arrays, you could do something like the following:

```
size_t r = ...;
double (*a)[r] = NULL;
double (*b)[r] = NULL;
double (*c)[r] = NULL;
double (*backing_store)[r][r] = malloc(3 * sizeof *backing_store);
if (!backing_store)
{
// panic and exit
}
a = backing_store[0];
b = backing_store[1];
c = backing_store[2];
```

You can then use `a`

, `b`

, and `c`

as though they were regular `r`

x`r`

arrays of `double`

:

```
a[i][j] = ...;
printf("%f\n", b[x][y]);
```

etc.

When you're done, you only need to free `backing_store`

:

```
free(backing_store);
```

Why does this work?

The expression `backing_store`

has type "pointer to `r`

-element array of `r`

-element array of `double`

. Since the expression `backing_store[i]`

is equivalent to `*(backing_store + i)`

, the subscript operator implicitly dereferences the pointer, so the type of the expression is "`r`

-element array of `r`

-element array of `double`

". Each of `backing_store[0]`

, `backing_store[1]`

, and `backing_store[2]`

is an `r`

x `r`

array of `double`

.

Remember that in most contexts, an expression of type "`N`

-element array of `T`

" is implicitly converted ("decays") to an expression of type "pointer to `T`

", and its value is the address of the first element in the array.

Thus, the expression `backing_store[0]`

is converted from type "`r`

-element array of `r`

-element array of `double`

" to "pointer to `r`

-element array of `double`

", which just happens to be the type of `a`

, and the value is the address of the first subarray (which happens to be the same as `backing_store`

). Again, applying the subscript operator implicitly dereferences the pointer, so `a[i][j]`

gives the `j`

th element of the `i`

th array after `a`

.

If `r`

*is* known at compile time (i.e., it is a *constant expression*) then the procedure is the same, you just don't have to declare the variable `r`

:

```
#define R ...
double (*a)[R] = NULL;
double (*b)[R] = NULL;
double (*c)[R] = NULL;
double (*backing_store)[R][R] = malloc(3 * sizeof *backing_store);
if (!backing_store)
{
// panic and exit
}
a = backing_store[0];
b = backing_store[1];
c = backing_store[2];
```

If `r`

is *not* known at compile time *and* you don't have variable-length arrays available (using C89 or a C11 compiler that doesn't support VLAs), then it can get a little messier. Here we treat `backing_store`

as a 1-d array of `double`

and compute 1-d subscripts into each subarray:

```
double *a = NULL;
double *b = NULL;
double *c = NULL;
double *backing_store = malloc(3 * r * r * sizeof *backing_store);
if (!backing_store)
{
// panic
}
a = backing_store;
b = backing_store + r * r;
c = backing_store + 2 * r * r;
a[i*r+j] = ...;
printf("%f\n", b[x*r+y]);
```

Again, you should only need to free `backing_store`

when you're done:

```
free(backing_store);
```

Not as pretty as using 2-d subscripts, but it should work.