Using a buffer with malloc

I'm trying to store three square, 2d arrays into a buffer so I use one contiguous block of memory. If the array size is rxr, my formula is:

``````buffer = (double*) malloc((r + r + r) * sizeof(double *) +
(r*r + r*r + r*r) * sizeof(double));

if(buffer == NULL) {
printf("out of memory\n");
return 0;
}

for(i = 0, j = 0; i < r; i++) {
a[i] = &buffer[j];
j+=r;
}

for(i = 0; i < r; i++) {
b[i] = &buffer[j];
j+=r;
}

for(i = 0; i < r; i++) {
c[i] = &buffer[j];
j+=r;
}

a = buffer[j];
b = buffer[j + r];
c = buffer[j + r + r];
``````

As you can see, I'm lost. a, b, c, are declared as double pointers (meant to be pointers to arrays of arrays), so I want each to have an array of size r, with each element pointing to its own separate array of size r. Any ideas...

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You're confusing malloc'ing pointers with malloc'ing doubles themselves. Just allocate the doubles like:

``````double* all = (double*) malloc( 3*r*r*sizeof(double));
``````

Then where do your actual matrices go?

``````double *p1 = all;
double *p2 = &all[r*r];
double *p3 = &all[2*r*r];
``````

Please check for off by one errors :) But the point is you don't need to malloc out both the double* and the double.

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I don't know the answer to this question, but wouldn't it be good style to malloc the pointers to the matrices too, since the pointers are themselves arrays? (Comment edit here: doesn't your code just set my pointers to the first element of each array? I want to have an array of pointers signifying the rows, with each pointer pointing to its own array signifying its columns.) – Ed Cota Sep 11 '12 at 14:15
Pointers are not arrays, they are pointers. Yes there is a close affinity between pointers and arrays, but if you `malloc`ed the pointers that would only allocate `sizeof(double *)`, 4 bytes on a 32-bit machine. The name of an array can be used as a pointer, yes, but that points to the first element of the array. `p[0]` and `*p` are the same, and interchangable. – cdarke Sep 11 '12 at 14:58

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.

-

First, two-dimensional arrays are usually better managed as arrays of arrays rather than as pointers to rows, unless there is particular reason to use pointers. For this, we could do:

``````double (*Memory)[r][r] = malloc(3 * sizeof *Memory);
// Now Memory points to three r-by-r arrays of double.
double (*a)[r] = Memory[0];
double (*b)[r] = Memory[1];
double (*c)[r] = Memory[2];
``````

However, if you want to use pointers to rows, then you should allocate space for the pointers separately from allocating space for the elements. (If you do not, there are issues with conformance to the C standard, particularly with padding and alignment. Additionally, your code treated `buffer` as an array of one type, either `double` or `double *`. But the address arithmetic you need sometimes requires pointers to `double` [when setting element addresses] and sometimes requires pointers to `double *` [when setting addresses of pointers to double].) To use pointers to rows, you can allocate with this:

``````double *(*PointerMemory)[r] = malloc(3 * sizeof *PointerMemory);
// PointerMemory points to three arrays of r elements of pointers to double.
double (*ElementMemory)[r][r] = malloc(3 * sizeof *ElementMemory);
``````

Then you can set up pointers to the rows:

``````// Set a to point to the first array of r elements of pointers to double.
double *a[r] = PointerMemory[0];
// Initialize the elements of a to point to rows of the first r-by-r array of double.
for (i = 0; i < r; ++i)
a[i] = ElementMemory[0][i];

// Set b for the second array of pointers and the second array of double.
double *b[r] = PointerMemory[0];
for (i = 0; i < r; ++i)
b[i] = ElementMemory[1][i];

// Set c for the third arrays.
double *c[r] = PointerMemory[0];
for (i = 0; i < r; ++i)
c[i] = ElementMemory[2][i];
``````
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