3
int matrix[9][9],*p;
p=matrix[0]; 

this works and gives first row of matrix, but how to get first column of matrix I've tried p=matrix[][0]; ? Also I don't understand why below code gets compiler error ?

int matrix[9][9],p[9];  // it looks really ugly, byt why it doesn't work ?
p=matrix[0];            // compiler gives "invalid array assigment"

is it because multidimensional arrays are arrays of arrays - and we should interpret matrix[i][j] as j-th element of i-th nested array ?

15

In C/C++, multidimensional arrays are actually stored as one dimensional arrays (in the memory). Your 2D matrix is stored as a one dimensional array with row-first ordering. That is why getting a column out of it is not easy, and not provided by default. There is no contiguous array in the memory that you can get a pointer to which represents a column of a multidimensional array. See below:

When you do p=matrix[0], you are just getting the pointer to the first element matrix[0][0], and that makes you think that you got the pointer to first row. Actually, it is a pointer to the entire contiguous array that holds matrix, as follows:

matrix[0][0]
matrix[0][1]
matrix[0][2]
.
.
matrix[1][0]
matrix[1][1]
matrix[1][2]
.
.
matrix[8][0]
matrix[8][1]
matrix[8][2]
.
.
matrix[8][8]

As seen above, the elements of any given column are separated by other elements in the corresponding rows.

So, as a side note, with pointer p, you can walk through the entire 81 elements of your matrix if you wanted to.

  • "Stored as one-dimensional arrays" is a bit of an odd way to put it. They're just arrays of arrays, so I'll grant that the memory layout is similar, but the semantics are a bit different. – Carl Norum Mar 6 '13 at 21:13
  • Semantics are different yes, I was referring to the memory layout. I will re-write that part. – meyumer Mar 6 '13 at 21:17
  • 1
    @meyumer mistake, sorry, they are really next to each other in memory – Qbik Mar 6 '13 at 21:23
8

You can get the first column using a loop like

for(int i = 0; i < 9; i++)
{
    printf("Element %d: %d", i, matrix[i][0]);
}

I think the assignment doesn't work properly because you're trying to assign something's that's not an address to a pointer.

(Sorry this is c code)

  • 1
    sorry but I wanted generic solution, be happy it is your first post +1 – Qbik Mar 6 '13 at 21:14
  • I believe it should be matrix[i][0] as C and C++ use 0 as the first element. – Thomas Matthews Mar 6 '13 at 21:34
  • This is the way to do it. You have to loop through the array to get the elements you want. There's no easy way because, as mentioned, the elements are not located in contiguous memory locations. – Nikos Feb 25 '17 at 13:00
3

There is no difference between specifying matrix[81] or matrix[9][9]

matrix[r][c] simply means the same as matrix[9*r+c]

There are other containers better suited fort multidimensional arrays like boost::multi_array

http://www.boost.org/doc/libs/1_53_0/libs/multi_array/doc/index.html

Think of the bare array just like allocating a contiguous piece of memory. You, the programmer then has to handle this piece of memory yourself. The bare name of the array, e.g. matrix is a pointer to the first element of this allocated piece of memory. Then *(matrix+1) is the same as matrix[0][1] or matrix[1].

  • Are you positive that matrix[81] is the same as matrix[9][9]? My understanding is that matrix[9][9] is equivalent to int * matrix[9], which means that it is a container of pointers, not contiguous memory locations. – Thomas Matthews Mar 6 '13 at 21:35
  • 1
    When you asked I became unsure. So I looked it up and now I am sure. See here for example stackoverflow.com/questions/7784758/… – AxelOmega Mar 6 '13 at 21:45
  • I stand corrected, thanks! – Thomas Matthews Mar 6 '13 at 21:49
  • 1
    I need to make a small correction to this. From a memory layout point of view there is no difference. But if the compiler has information about the original array declaration there is a difference on how it is interpreted. For example matrix[R][C] can be accessed linearly from a pointer int* mp (int*)matrix, the cast is needed to avoid warnings. You can access rows as int (row_ptr*)[C] = matrix then pointer arithmetic will ensure you move one whole row, e.g. (row_ptr+1) will point to the second row. Also value access has to be **(row_ptr+1). There are however no pointers in memory. – AxelOmega Mar 7 '13 at 19:42
2

p is an array of int, matrix[0] is a pointer..

  • but p=*(matrix[0]); doesn't work ! – Qbik Mar 6 '13 at 21:16
  • @Qbik *(matrix[0]) is an int, you can't assign an int to an int array – zzk Mar 6 '13 at 21:17
  • now I get it ! I've printed *p and data was correct, but it was only pointer to single int – Qbik Mar 6 '13 at 21:19
1

matrix itself is the nearest thing you can get to a column of the array, inasmuch as (matrix + 1)[0][0] is the same as matrix[1][0].

0

If you want your matrix to contiguous locations, declare it as a one dimensional array and perform the row and column calculations yourself:

int contiguous_matrix[81];

int& location(int row, int column)
{
  return contiguous_matrix[row * 9 + column];
}

You can also iterate over each column of a row:

typedef void (*Function_Pointer)(int&);

void Column_Iteration(Function_Pointer p_func, int row)
{
  row = row * MAXIMUM_COLUMNS;
  for (unsigned int column = 0; column < 9; ++column)
  {
    p_func(contiguous_matrix[row + column]);
  }
}
0

For static declared arrays you can access them like continuous 1D array, p = matrix[0] will give you the 1st column of 1st row. Then the 1D array can be accessed like p[i], *(p+i), or p[current_raw * raw_size + current_column).

The things are getting tricky if a 2D array is represented with **p as it will be interpreted as an array of pointers to 1D arrays.

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