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Does someone know how I can use dynamically allocated multi-dimensional arrays using C? Is that possible?

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7 Answers 7

up vote 47 down vote accepted

With dynamic allocation, using malloc:

int** x;

x = malloc(dimension1_max * sizeof(int*));
for (int i = 0; i < dimension1_max; i++) {
  x[i] = malloc(dimension2_max * sizeof(int));
}

[...]

for (int i = 0; i < dimension1_max; i++) {
  free(x[i]);
}
free(x);

This allocates an 2D array of size dimension1_max * dimension2_max. So, for example, if you want a 640*480 array (f.e. pixels of an image), use dimension1_max = 640, dimension2_max = 480. You can then access the array using x[d1][d2] where d1 = 0..639, d2 = 0..479.

But a search on SO or Google also reveals other possibilities, for example in this SO question

Note that your array won't allocate a contiguous region of memory (640*480 bytes) in that case which could give problems with functions that assume this. So to get the array satisfy the condition, replace the malloc block above with this:

int** x;
int* temp;

x = malloc(dimension1_max * sizeof(int*));
temp = malloc(dimension1_max * dimension2_max * sizeof(int));
for (int i = 0; i < dimension1_max; i++) {
  x[i] = temp + (i * dimension2_max);
}
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2  
This won't compile, you need to declare x as "int **", not "int[][]". –  Adam Rosenfield May 27 '09 at 20:28
    
What does this exactly do? What is dimension1_max and dimension2_max? What does the first "for"? –  rpf May 27 '09 at 20:35
    
Thanks, Adam, I knew something was wrong although I already corrected the first sizeof to int* instead of int. –  schnaader May 27 '09 at 20:39
6  
It is not a multidimensional array - it is array of pointers to int, or array of arrays. To allocate memory for real 2D array you need to use malloc(dim1 * dim2 * sizeof(int)). If some function expects pointer to 2D array, like foo(int * bar[5][6]) and you pass your x, weird things will happen. See en.wikipedia.org/wiki/C_syntax#Multidimensional_arrays –  qrdl May 28 '09 at 6:45
    
Ah, I get what you mean. I've added another example where a contiguous region of memory is provided and also corrected the malloc calls that weren't casted to int*/int**. –  schnaader May 28 '09 at 9:12

Basics

Arrays in c are declared and accessed using the [] operator. So that

int ary1[5];

declares an array of 5 integers. Elements are numbered from zero so ary1[0] is the first element, and ary1[4] is the last element. Note1: There is no default initialization, so the memory occupied by the array may initially contain anything. Note2: ary1[5] accesses memory in an undefined state (which may not even be accessible to you), so don't do it!

Multi-dimensional arrays are implemented as an array of arrays (of arrays (of ... ) ). So

float ary2[3][5];

declares an array of 3 one-dimensional arrays of 5 floating point numbers each. Now ary2[0][0] is the first element of the first array, ary2[0][4] is the last element of the first array, and ary2[2][4] is the last element of the last array. The '89 standard requires this data to be contiguous (sec. A8.6.2 on page 216 of my K&R 2nd. ed.) but seems to be agnostic on padding.

Trying to go dynamic in more than one dimension

If you don't know the size of the array at compile time, you'll want to dynamically allocate the array. It is tempting to try

double *buf3;
buf3 = malloc(3*5*sizeof(double));
/* error checking goes here */

which should work if the compiler does not pad the allocation (stick extra space between the one-dimensional arrays). It might be safer to go with:

double *buf4;
buf4 = malloc(sizeof(double[3][5]));
/* error checking */

but either way the trick comes at dereferencing time. You can't write buf[i][j] because buf has the wrong type. Nor can you use

double **hdl4 = (double**)buf;
hdl4[2][3] = 0; /* Wrong! */

because the compiler expects hdl4 to be the address of an address of a double. Nor can you use double incomplete_ary4[][]; because this is an error;

So what can you do?

  • Do the row and column arithmetic yourself
  • Allocate and do the work in a function
  • Use an array of pointers (the mechanism qrdl is talking about)

Do the math yourself

Simply compute memory offset to each element like this:

  for (i=0; i<3; ++i){
     for(j=0; j<3; ++j){
        buf3[i * 5 + j] = someValue(i,j); /* Don't need to worry about 
                                             padding in this case */
     }
  }

Allocate and do the work in a function

Define a function that takes the needed size as an argument and proceed as normal

void dary(int x, int y){
  double ary4[x][y];
  ary4[2][3] = 5;
}

Of course, in this case ary4 is a local variable and you can not return it: all the work with the array must be done in the fuction you call of in fuctions that it calls.

An array of pointers

Consider this:

double **hdl5 = malloc(3*sizeof(double*));
/* Error checking */
for (i=0; i<3; ++i){
   hdl5[i] = malloc(5*sizeof(double))
   /* Error checking */
}

Now hdl5 points to an array of pointers each of which points to an array of doubles. The cool bit is that you can use the two-dimensional array notation to access this structure---hdl5[0][2] gets the middle element of the first row---but this is none-the-less a different kind of object than a two-dimensional array declared by double ary[3][5];.

This structure is more flexible then a two dimensional array (because the rows need not be the same length), but accessing it will generally be slower and it requires more memory (you need a place to hold the intermediate pointers).

Note that since I haven't setup any guards you'll have to keep track of the size of all the arrays yourself.

Arithmetic

c provides no support for vector, matrix or tensor math, you'll have to implement it yourself, or bring in a library.

Multiplication by a scaler and addition and subtraction of arrays of the same rank are easy: just loop over the elements and perform the operation as you go. Inner products are similarly straight forward.

Outer products mean more loops.

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1  
Just one point - array of arrays is array of pointers, not a real multidimensional array. en.wikipedia.org/wiki/C_syntax#Multidimensional_arrays –  qrdl May 28 '09 at 6:50
1  
@qrdl: As I read the standard int **a1; and int *a2[i]; int a3[n][m]; are different critters with different semantics. The last one gets allocated a block of continguous (possibly padded) memory without a separate set of intermediate pointers... Try printf("%d\n",sizeof(int[3][5])/sizeof(int)); –  dmckee May 28 '09 at 14:53
    
Does "allocate in a function" work? How would the compiler know how much memory to allocate in the stack for the array ary4 if x and y are unkown? –  MIkhail Jan 8 at 18:59
1  
@MIkhail Er ... x and y are known at run time, and the compiler is not restricted to sizing the stack frame all in one go. Try it. Of course you can't return that array, you have to do all the work in the function, so my text is a bit misleading. I'll edit to fix that up. –  dmckee Jan 9 at 0:59
1  
@MIkhail For what it's worth, I think the compiler does need to know the size of globally scoped arrays at compile time. –  dmckee Jan 9 at 2:01

Since C99, 13 years now, C has 2D arrays with dynamical bounds. If you want to avoid that such beast are allocated on the stack (which you should), you can allocate them easily in one go as the following

double (*A)[n] = malloc(sizeof(double[n][n]));

and that's it. You can then easily use it as you are used for 2D arrays with something like A[i][j]. And don't forget that one at the end

free(A);

Randy Meyers wrote series of articles explaining variable length arrays (VLAs).

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@Novelocrat, why don't you just put things that you find interesting in a comment? –  Jens Gustedt Nov 1 '13 at 21:07
    
Parts 2, 3, and 4 of Meyers's series are also available from Dr Dobbs. –  Novelocrat Nov 1 '13 at 21:19
1  
This is the answer. O.o at everything else on this page, and despair for democracy. –  Sam Watkins Feb 3 at 12:56

If you know the number of columns at compile time, it's pretty simple:

#define COLS ...
...
size_t rows;
// get number of rows
T (*ap)[COLS] = malloc(sizeof *ap * rows); // ap is a *pointer to an array* of T

You can treat ap like any 2D array:

ap[i][j] = x;

When you're done you deallocate it as

free(ap);

If you don't know the number of columns at compile time, but you're working with a C99 compiler or a C2011 compiler that supports variable-length arrays, it's still pretty simple:

size_t rows;
size_t cols;
// get rows and cols
T (*ap)[cols] = malloc(sizeof *ap * rows);
...
ap[i][j] = x;
...
free(ap);

If you don't know the number of columns at compile time and you're working with a version of C that doesn't support variable-length arrays, then you'll need to do something different. If you need all of the elements to be allocated in a contiguous chunk (like a regular array), then you can allocate the memory as a 1D array, and compute a 1D offset:

size_t rows, cols;
// get rows and columns
T *ap = malloc(sizeof *ap * rows * cols);
...
ap[i * rows + j] = x;
...
free(ap);

If you don't need the memory to be contiguous, you can follow a two-step allocation method:

size_t rows, cols;
// get rows and cols
T **ap = malloc(sizeof *ap * rows);
if (ap)
{
  size_t i = 0;
  for (i = 0; i < cols; i++)
  {
    ap[i] = malloc(sizeof *ap[i] * cols);
  }
}

ap[i][j] = x;

Since allocation was a two-step process, deallocation also needs to be a two-step process:

for (i = 0; i < cols; i++)
  free(ap[i]);
free(ap);
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It would be nice if the downvoter would tell me what they think I got wrong. –  John Bode Oct 31 '13 at 14:54

malloc will do.

 int rows = 20;
 int cols = 20;
 int *array;

  array = malloc(rows * cols * sizeof(int));

Refer the below article for help:-

http://courses.cs.vt.edu/~cs2704/spring00/mcquain/Notes/4up/Managing2DArrays.pdf

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1  
The question asks for C. That was C++. –  slugonamission Oct 9 '12 at 16:20
    
@rahul I would suggest that if you make the edit you did above that you leave the article you had linked. Despite the syntax being specific to C++, all of the concepts introduced there would hold for the method you propose in your edited answer –  im so confused Oct 9 '12 at 16:26
    
@AK4749:- I deleted it as I was afraid to loose my points. I had lost many of them earlier also as people here are very specific to there questions and do not want to explore.!!! Anyways Thanx a lot for boosting me –  Rahul Tripathi Oct 9 '12 at 16:29
    
@RahulTripathi yes, i've noticed that "analness" about SO as well, but in its defense, it isn't a forum but rather a place to get specific questions answered. A different vibe to get used to i guess :/ –  im so confused Oct 9 '12 at 16:37
    
I do agree with you AK4749...!!!! –  Rahul Tripathi Oct 9 '12 at 16:39
int rows, columns;
/* initialize rows and columns to the desired value */

    arr = (int**)malloc(rows*sizeof(int*));
        for(i=0;i<rows;i++)
        {
            arr[i] = (int*)malloc(cols*sizeof(int));
        }
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1  
too complicated, modern C can do real multi-dimensional arrays in one go –  Jens Gustedt Oct 9 '12 at 18:18

There's no way to allocate the whole thing in one go. Instead, create an array of pointers, then, for each pointer, create the memory for it. For example:

int** array;
array = (int**)malloc(sizeof(int*) * 50);
for(int i = 0; i < 50; i++)
    array[i] = (int*)malloc(sizeof(int) * 50);

Of course, you can also declare the array as int* array[50] and skip the first malloc, but the second set is needed in order to dynamically allocate the required storage.

It is possible to hack a way to allocate it in a single step, but it would require a custom lookup function, but writing that in such a way that it will always work can be annoying. An example could be L(arr,x,y,max_x) arr[(y)*(max_x) + (x)], then malloc a block of 50*50 ints or whatever and access using that L macro, e.g.

#define L(arr,x,y,max_x) arr[(y)*(max_x) + (x)]

int dim_x = 50;
int dim_y = 50;

int* array = malloc(dim_x*dim_y*sizeof(int));

int foo = L(array, 4, 6, dim_x);

But that's much nastier unless you know the effects of what you're doing with the preprocessor macro.

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1  
wrong, much too complicated, modern C can do better, please see my answer. –  Jens Gustedt Oct 9 '12 at 18:17

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