# What is difference between types int** and int[][]?

If the following assignment is valid:

``````int a[2] = {1,2};
int* b = a;
``````

then what is wrong with this:

``````int a[2][2]={1,2,3,4};
int** b = a;
``````

C++ gives an error that it can't convert `int[][]` to `int**`. What is difference between the two types if `int[]` is the same as `int*`?

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Take a look at all the answers, you'll learn a lot! (But take your time also.;)) –  Beginner Dec 6 '11 at 5:07
related FAQ –  FredOverflow Dec 6 '11 at 5:29
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## 4 Answers

Take it easy. It is only a compiler error. Arrays are pretty tricky. Here is the rule:

The value of a variable of type array decays to the address of element zero of this array

Your first snippet looks like:

``````int a[2] = {1,2};
``````

So according to the rule if `a` is in the right hand side of a assignment then it decays to address of the element zero and that is why it has type `int *`. This brings you to

``````int *b = a;
``````

In the second snippet what you really have is an array of arrays. (By the way, to make it explicit I've changed your code a bit.)

``````int a[2][2]={{1,2},{3,4}};
``````

This time `a` will decay to the pointer to an array of two integers! So if you would want to assign `a` to something, you would need this something to have the same type.

``````int (*b)[2] = a; //Huh!
``````

(This syntax maybe a bit stunning to you, but just think for a moment that we have written `int *b[2];` Got the point? `b` would be an array of pointers to integers! Not really what we wanted...)

You could stop reading here, but you could also move on, because I have not told you all the truth. The rule I mentioned has three exceptions...

The value of the array will not decay to the address of the element zero if

1. array is operand of `sizeof`
2. array is operand of `&`
3. array is a literal string initializer for a character array

Let's explain these exceptions in more detail and with examples:

``````int a[2];

int *pi = a ; /* the same as pi = &a[0]; */

printf("%d\n", sizeof(a)); /* size of the array, not of a pointer is printed! */

int (*pi2)[2] = &a; /* address of the array itself is taken (not the address of a pointer) */
``````

And finally

``````char a[] = "Hello world ";
``````

Here not a pointer to "Hello world" is copied, but the whole string is copied and a points to this copy.

There is really a lot of information and it is really difficult to understand everything at once, so take your time. I recommend you to read K&R on this topic and afterwards this excellent book.

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+1, calming the developer when debugging in C++ is usually the first step. :D –  Russell Dec 6 '11 at 4:16
It's not a warning, it's a fundamental incompatibility in the binary layout of the two types. –  Chris Lutz Dec 6 '11 at 4:18
@ChrisLutz Thank you, just my bad English. –  Beginner Dec 6 '11 at 4:23
OP note that while `b` is valid and it'll compile, in order to use it to access the elements of `a` you're going to need to specify the bounds, ie. `int (*b)[2] = a;`. –  AusCBloke Dec 6 '11 at 4:30
Good answer (way too many people misunderstand this). Suggested reading: section 6 of the comp.lang.d FAQ. –  Keith Thompson Dec 6 '11 at 5:06
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This is something that comes up a lot, so I will attempt to explain it as clearly as I can.

When you make an array, it stores the elements contiguously in memory, so:

``````int arr[2] = { 1, 2 };
``````

Translates to:

``````arr:
+---+---+
| 1 | 2 |
+---+---+
``````

A pointer points to an object in memory, and when dereferenced, via unary `*` or via `[]`, it accesses that contiguous memory. So after

``````int *ptr = arr;
``````

`ptr` (or `&ptr[0]` if you like) points to the box `1` is in, and `ptr + 1` (or `&ptr[1]`) points to the box `2` is in. This makes sense.

But if arrays are contiguous in memory, arrays of arrays are contiguous in memory. So:

``````int arr[2][2] = {{ 1, 2 }, { 3, 4 }};
``````

Looks in memory like this:

``````arr:
+---+---+---+---+
| 1 | 2 | 3 | 4 |
+---+---+---+---+
``````

Which looks a lot like our flat array.

Now, let's consider how a pointer to a pointer to an `int` would be laid out in memory:

``````ptr:
+-------+-------+
| &sub1 | &sub2 |
+-------+-------+

sub1:
+---+---+
| 1 | 2 |
+---+---+

sub2:
+---+---+
| 3 | 4 |
+---+---+
``````

`ptr` (or `&ptr[0]`) points to `sub1`, and `ptr + 1` (or `&ptr[1]`) points to `sub2`. `sub1` and `sub2` have no actual relation to each other, and can be anywhere in memory, but because it's a pointer to a pointer, the double-dereference of a 2D array is preserved, even though the memory structure is not compatible.

Arrays of type `T` decay to pointers to type `T`, but arrays of arrays of type `T` do not decay to pointers to pointers to type `T`, they decay to pointers to arrays of type `T`. So when our 2D `arr` decays to a pointer, it is not a pointer to a pointer to an `int`, but a pointer to an `int [2]`. The full name of this type is `int (*)[2]`, and to make your line of code work you'd want to use

``````int (*ptr)[2] = arr;
``````

Which is the correct type. `ptr` expects to point to a contiguous array of memory, like `arr` does - `ptr` (or `&ptr[0]`) points to `arr` and `ptr + 1` (or `&ptr[1]`) points to `&arr[1]`. `ptr[0]` points to the box that holds `1`, and `ptr[1]` points to the box that holds `3`, so `ptr[0][0]` yields 1, `ptr[0][1]` yields 2, and so on.

Why do you need to know this? 2D pointers seem more complicated than they're worth - if you were using `malloc` you'd have to call `malloc` repeatedly in a loop, and do the same for `free`. OR, you could use some evil* trickery to make a flat, 1-dimensional allocation of memory act like a 2D array:

``````// x and y are the first and second dimensions of your array
// so it would be declared T arr[x][y] if x and y were static

int (*arr)[y] = malloc(x * y * sizeof(arr[0][0]));
if(!arr) /* error */;
``````

Now `arr` points to a contiguous block of arrays of size `y` of `int` objects. Since the object it points to is an array, we don't need the double-pointer-indirection of `int **` objects, and when you're done, you can free it with one call:

``````free(arr);
``````

Compare this to a version using `int **`:

``````int **arr = malloc(x * sizeof(*arr));
if(!arr) /* error */;
for(size_t ii = 0; ii < x; ii++)
{
arr[ii] = malloc(y * sizeof(**arr));
if(!arr[ii])
{
free(arr[ii]);
free(arr);
}
}
// do work
for(size_t ii = 0; ii < x; ii++)
free(arr[ii]);
free(arr);
``````

The above code has a memory leak. See if you can find it. (Or just use the version with those seemingly tricky pointers-to-arrays.)

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As a side note, `int (*ptr)[2]` may look confusing, and rightly so. The command-line (and now web-based) tool cdecl can help you decode C declarations into plain English. –  Chris Lutz Dec 6 '11 at 4:48
Cool, didn't know it's online.. hope my students haven't found it... –  Beginner Dec 6 '11 at 4:52
@Beginner - Why? It'll help them learn it eventually. ;) –  Chris Lutz Dec 6 '11 at 4:53
+1 for illustrating the memory layout. –  Timothy Jones Dec 6 '11 at 4:59
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The famous decay convention: an array is treated as a pointer that points to the first element of the array.

``````int a[2] = {1,2};
int* b = a; //decay
``````

But the decay convention shouldn't be applied more than once to the same object.

``````int a[2][2]={1,2,3,4};
int** b = a; //decay more than once
``````
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`int[]` isn't the same as `int*`. `int[]` will decay into an `int*` in certain contexts.

You probably should read the comp.lang.c FAQ, particularly:

and perhaps the rest of the Array and Pointers section.

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