Here are the basic rules:

For any^{1} type `T`

, you can have any of the following:

```
T *p; // p is a pointer to T
T *a[N]; // a is an array of pointer to T
T (*a)[N]; // a is a pointer to an array of T
T *f(); // f is a function returning pointer to T
T (*f)(); // f is a pointer to a function returning T
```

The postfix `[]`

and `()`

operators have higher precedence than unary `*`

, so an expression like `*p[i]`

is parsed as `*(p[i])`

. If you want to index into what `p`

*points to*, then you need to explicitly group the `*`

operator with `p`

, or `(*p)[i]`

. This precedence rule applies to both expressions and declarations.

Except when it is the operand of the `sizeof`

, `_Alignof`

, or unary `&`

operator, or is a string literal used to initialize a character array in a declaration, an *expression* of type "N-element array of `T`

" will be converted ("decay") to an expression of type "pointer to `T`

" and the value of the expression will be the address of the first element of the array. So given the declaration

```
int a[4] = {10, 20, 30, 40};
```

all of the following are true:

```
Expression Type Decays to Equivalent value
---------- ---- --------- ----------------
a int [4] int * &a[0]
&a int (*)[4] n/a &a[0]
*a int n/a a[0]
```

The expression `a`

has type "4-element array of `int`

" (`int [4]`

). `a`

is not the operand of the `sizeof`

, `_Alignof`

, or unary `&`

operators, so the expression "decays" to type "pointer to `int`

" and the value of the expression is the address of the first element. The result of this expression is exactly equivalent to `&a[0]`

.

The expression `&a`

has type "pointer to 4-element array of `int`

" (`int (*)[4]`

). In this case, `a`

*is* the operand of the unary `&`

operator, so the decay rule doesn't apply.

All of the expressions `a`

, `&a`

, and `&a[0]`

yield the same *value* (the address of the first element of `a`

), but the *types* of the expressions are different (which may affect how the value is represented). The type of `a`

and `&a[0]`

is `int *`

, but the type of `&a`

is `int (*)[4]`

.

Type matters for things like pointer arithmetic. Assume the following declarations:

```
int a[4] = {0, 1, 2, 3};
int *p = a;
int (*ap)[4] = &a;
```

Both `p`

and `ap`

initially point to the same address. However, the *expression* `p + 1`

will yield the address of the next `int`

object following whatever `p`

is pointing to (IOW, `&a[1]`

), while `ap + 1`

will yield the address of the next *4-element array of *`int`

following `a`

.

This is exactly how array subscripting works - the expression `a[i]`

is evaluated as `*(a + i)`

. Given a starting address `a`

, offset `i`

objects (*not bytes*) and dereference the result.

And this is why you get the errors in some of your assignments - the types `int *`

and `int (*)[4]`

are not *compatible*. For one thing, they don't have to be represented the same way (although on any system you're likely to use they will be), and they behave differently when using pointer arithmetic.

Pointers to different types are themselves different types, and are not normally interchangeable.

^{
Well, almost any - functions cannot return array or function types, and you cannot have an array of function type, so for T (*a)[N] T cannot be a function type, and for T (*f)() T cannot be a function or array type.
}
'p'is a pointer to array of four integers. So, if you print adress ofp+1(`printf("p = %p\np++ = %p\n", p, p+1);`

) you will see that the address is4 * sizeof(int)bigger than address of'p'. – mar Jun 5 at 7:16