You have two options at least. The simpler one is to declare a preprocessor macro that hides the complexity of the index calculation, e.g.:

```
#define ARR(A,i,j,k) A[(i)*ylength*zlength+(j)*zlength+(k)]
ARR(myarray,i,j,k) = ARR(myarray,i+1,j,k) + ARR(myarray,i,j+1,k) + ...
```

This is clumsy since the macro will only work with arrays of fixed leading dimensions, e.g. whatever x `ylength`

x `zlength`

.

Much better way to do it is to use so-called dope vectors. Dope vectors are basically indices into the big array. You allocate one big flat chunk of size `xlength * ylength * zlength`

to hold the actual data and then create an index vector (actually a tree in the 3D case). In your case the index has two levels:

- top level, consisting of
`xlength`

pointers to the
- second level, consisting of
`xlength`

arrays of pointers, each containing `ylength`

pointers to the beginning of a block of `zlength`

elements in memory.

Let's call the top level pointer array `A`

. Then `A[i]`

is a pointer to a pointer array that describes the `i`

-th slab of data. `A[i][j]`

is the `j`

-th element of the `i`

-th pointer array, which points to `data[i][j][0]`

(if `data`

was a 3D array). Construction of the dope vector works similar to this:

```
double *data = new double[xlength*ylength*zlength];
double ***A;
A = new double**[xlength];
for (int i = 0; i < xlength; i++)
{
A[i] = new double*[ylength];
for (int j = 0; j < ylength; j++)
A[i][j] = data + i*ylength*zlength + j*zlength;
}
```

Dope vectors are as easy to use as normal arrays with some special considerations. For example, `A[i][j][k]`

will give you access to the desired element of `data`

. One caveat of dope vectors is that the top level consist of pointers to other pointer tables and not of pointers to the data itself, hence `A`

cannot be used as shortcut for `&A[0][0][0]`

, nor `A[i]`

used as shortcut for `&A[i][0][0]`

. Still `A[i][j]`

is equivalent to `&A[i][j][0]`

. Another caveat is that this form of array indexing is slower than normal 3D array indexing since it involves pointer chasing.

Some people tend to allocate a single storage block for both data and dope vectors. They simply place the index at the beginning of the allocated block and the actual data goes after that. The advantage of this method is that disposing the array is as simple as deleting the whole memory block, while disposing dope vectors, created with the code from the previous section, requires multiple invocations of the `free`

operator.