First, some background information:

Except when it is the operand of the `sizeof`

, `_Alignof`

, or unary `&`

operators, or is a string literal being used to initialize another array in a declaration, an expression of type "N-element array of `T`

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

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

```
int a[10];
```

anytime the expression `a`

appears in the code, its type will be converted from "10-element array of `int`

" to "pointer to `int`

", or `int *`

, *except* for cases like `sizeof a`

, `_Alignof a`

, and `&a`

. If we have a 2D array of T, such as

```
int a[10][10];
```

the expression `a`

will be converted from type "10-element array of 10-element array of `int`

" to "pointer to 10-element array of `int`

", or `int (*)[10]`

(look familiar? that's the type of your pointer `p`

).

If we want to dynamically allocate an N-element array of type `T`

, we write something like

```
T *p = malloc(N * sizeof *p);
```

`sizeof *p`

is equivalent to `sizeof (T)`

. In this particular case, type `T`

is "10-element array of `int`

", or `int [10]`

. We want to allocate 4 such arrays, so we can write

```
int (*p)[10];
p = malloc(4 * sizeof *p);
```

This allocates space for 4 10-element arrays of `int`

, and assigns the result to `p`

. (`sizeof *p == sizeof (int [10])`

).

So how does this become a 2D array?

Remember that the expression `a[i]`

is equivalent to `*(a + i)`

; we find the address of the `i`

'th *element* of type `T`

following `a`

and dereference the result. In this case `p[i]`

gives us the address of the `i`

th *10-element array of *`int`

following `p`

. Since we dereference the pointer as part of the subscript operation, the *type* of the expression `p[i]`

is "10-element array of `int`

". Thus we can subscript this expression again and get `p[i][j]`

.