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I've been studying C++ for a test and I am currently stuck with pointer arithmetic.

The basic problem is the following:

int numColumns = 3;
int numRows    = 4;

int a[numRows][numColumns];

a[0][0] = 1;
a[0][1] = 2;
a[0][2] = 3;
a[1][0] = 4;
a[1][1] = 5;
a[1][2] = 6;
a[2][0] = 7;
a[2][1] = 8;
a[2][2] = 9;
a[3][0] = 10;
a[3][1] = 11;
a[3][2] = 12;

for (int i=numColumns-1; i>-1;i--)
  cout << a[numRows-1][i] << endl;

A very simple program which prints the lower "row of the matrix". i.e. 12,11,10.

Now I am trying to do the equivalent with a int*.

What I have been told by my classmates is to think it like this:

array[i][j] == p[numColumns*i+j]

If that is correct, shouldn't the following be equivalent to what I'm looking for:

int* p = reinterpret_cast<int*> a;
for (int i=numColumns-1; i>-1;i--)
  cout << p[numColumns*(numRows-1)+i] << endl;


share|improve this question
Have you tried it? –  Beta Aug 26 '10 at 19:15
Welcome to SO! Thanks for telling us that you were studying for a test. I added the homework tag to your question. You're asking these in a good way. –  John Aug 26 '10 at 19:15

4 Answers 4

up vote 2 down vote accepted

int array[3][5] is NOT an abstraction (in the C++ language) for int array[3*5]. The standard says that a 2 dimensional array (and N-dimensional arrays in general) are arrays of arrays. That array[3][5] is an array of three elements, where each element is an array containing 5 elements (integers in this case). C++'s type system does make that distinction.

According to the C++ standard, and array T array[N] is a contiguous block of memory containing the N elements of type T. So that means that a multidimensional array, let's say int array[3][5] will be a continuous block of memory containing 3 int[5] arrays, and each int[5] array is a contiguous block of 5 ints.

On my machine, the memory ends up laid out exactly as you would expect - identical to int array[3*5]. The way the memory is treated is different however, due to the type system (which distinguishes between int[] and int[][]). This is why you need to use a reinterpret_cast which essentially tells your compiler "take this memory and without doing any conversion, treat it like this new type".

I'm not completely sure if this memory layout is guaranteed however. I couldn't find anything in the standard stating that arrays can't be padded. If they can be padded (again, I'm not sure) then it's possible that the int[5] array is not actually 5 elements long (a better example would be char[5], which I could see being padded to 8 bytes).

Also there is an appreciable difference between int* and int** since the latter doesn't guarantee contiguous memory.

EDIT: The reason that C++ distinguishes between int[3*5] and int[3][5] is because it wants to guarantee the order of the elements in memory. In C++ int[0][1] and int[0][2] are sizeof(int) apart in memory. However in Fortran, for example, int[0][0] and int[1][0] are sizeof(int) apart in memory because Fortran uses column major representation.

Here's a diagram to help explain:

0 1 2
3 4 5
6 7 8

Can be made into an array that looks like {0,1,2,3,4,5,6,7,8} or an array that looks like: {0,3,6,1,4,7,2,5,8}.

share|improve this answer

Hint: in your original code, the type of a is more similar to int**, so you shouldn't cast it to int*. It is a pointer to pointer to something.

If you want to access it like an 1-D array, then a has to be defined as an 1-D array as well.

share|improve this answer
Really? I thought that multi-dimensionals arrays were just an "abstraction" for us, since the following is equivalent: int array[3][5]; int array[3*5]; –  Juan Pablo Velasquez Aug 26 '10 at 19:34

@rwong: Really? I thought that multi-dimensionals arrays were just an "abstraction" for us, since the following are equivalent:

int array[3][5];
int array[3*5];

Anyways, I detemined what was wrong. As usual it was not my code, but copy-pasting someone's code and working from there.

What I had was this:

for(int i=numRows-1; i>-1 ;i++)
  cout << p[numColumns*numRows-1+i] << endl;

Is funny because I did not copy-paste my code from VS, but actually wrote it from scratch to "illustrate" my error.

Lesson to be learnt here ;)

Edit: I'm still not sure about what rwong explained here. Would anyone care to elaborate?

share|improve this answer
I believe you are thinking of regular C, not C++. In regular C, int a[rows][cols]; int *b = (int*)a; a[x][y] == b[x*cols + y]; would return true. –  bta Aug 26 '10 at 21:30
What rwong is saying is that strictly speaking, the a in a[x][y] is a pointer-to-a-pointer (or int**). An item from the first dimension (a[x]) is a int*, not necessarily an array. You can have an array of pointers to dynamically-allocated arrays. In that case, you can index the "matrix" like a[x][y] but the rows are not necessarily contiguous in memory so the syntax a[x*cols + y] would most likely not work. –  bta Aug 26 '10 at 21:37

Another way to think about it: since a is similar to an int**, is there a part of a that's similar to an int*?

share|improve this answer
wait a min. Now I'm even more confused. <br/> What I know is that the identifier of an array is equivalent to an address of its first element, so a pointer and an array are the same concept. <br/> If this is true, and multi-dimension arrays are just an abstraction for programmers where the compiler remembers the depth of each "dimension", then how can a matrix be equivalent to a int**? Am I missing something? –  Juan Pablo Velasquez Aug 26 '10 at 19:51
Yes. In C++ int[][] is not an abstraction for int[]. int[][] is its own type. The reason is that C++ is a row major language. int[] allows you to use row or column major layouts. For example, you can do p[ywidth+x] (row major) or p[xheight+y] (column major). In C++ int[x][y] is always p[y*width+x]. –  Niki Yoshiuchi Aug 26 '10 at 20:53

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