# Dynamic memory allocation code explanation

Being a beginner C/C++ programmer, I am having to spend several hours, trying to decipher the code below: Could someone walk me (step me through the code below for dynamic memory allocation) line by line.

`````` char **alloc_2d_char(const int rows, const int cols)
{
char *data = (char *)malloc(rows*cols*sizeof(char));
char **array= (char **)malloc(rows*sizeof(char*));

for (int i=0; i<rows; i++)
array[i] = &(data[cols*i]);

return array;
}
``````

Pointer to Pointers is explained separately than from Pointers to Arrays. I have been able to get parts of the information from various sources, but none that stitches the lines cohesively.

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It's plain C, not C++ – littleadv Jun 17 '11 at 0:08
Your comments have been immensely useful. Thanks a ton! – Ashmohan Jun 17 '11 at 0:23

The code is using a single contiguous block of memory to hold a 2-D array.

``````char *data = (char *)malloc(rows*cols*sizeof(char));
``````

Ok -- this line is allocating space for the entire 2-D array. The 2-D array is `rows` rows by `cols` columns. So the total number of elements is `rows * cols`. Then you have to multiply that by the amount of space each element takes up, which is `sizeof(char)` since this is a 2-D array of `char`. Thus the total amount of memory to be allocated is `rows * cols * sizeof(char)` which is indeed the argument to `malloc`.

The `malloc` call returns a pointer to the allocated memory. Since this memory will be used to hold `char`, you cast the return value to `char *`.

``````char **array= (char **)malloc(rows*sizeof(char*));
``````

`array` is being declared as type "pointer to pointer to char" because that's what it's going to do. It'll point to memory that will hold pointers to char. It will be one pointer for each row. So you have to allocate `rows * sizeof(char *)` memory: the number of pointers times the size of a pointer of the right type. And since this was allocated to point to pointers to char, we cast the return value to `char **`.

``````for (int i=0; i<rows; i++)
array[i] = &(data[cols*i]);
``````

This is the magic :). This sets each pointer in `array` to point to within the block of actual data allocated earlier. Consider a concrete example where `rows` is 2 and `cols` is 3. Then you have the block of 6 characters in memory:

`````` [0][1][2][3][4][5]
``````

And `data[n]` (for `n` from `0` to `5`) is the n-th element and `&data[n]` is the *address of the n-th element.

So what that loop does in this case is do:

``````array[0] = &data[0];
array[1] = &data[3];
``````

So `array[0]` points to the sub-block starting at `[0]` and `array[1]` points to the sub-block starting at `[3]`. Then when you add the second subscript you're indexing from the start of that pointer. So `array[0][2]` means "get the pointer stored in `array[0]`. Find what it points to, then move ahead 2 elements from there.:

`array[0]` points to `[0][1][2]` (well, actually points to `[0]`). Then you move two elements ahead and get `[2]`.

Or if you start with `array[1][1]`, `array[1]` points to `[3][4][5]` (and actually points at `[3]`. Move one element ahead and get `[4]`.

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Thank you very much. What is the role of **alloc_2d_char? That is, why is everything else enveloped inside this pointer to pointer? – Ashmohan Jun 17 '11 at 0:18
`alloc_2d_char` is the name of a function that returns a value whose type is `char **`. If it helps make it clearer, you could think of the function declaration as `char** alloc_2d_char()` instead of `char **alloc_2d_char()`. – QuantumMechanic Jun 17 '11 at 0:21
Thanks QM! One last query. What makes the above dynamic vs. say something like this for defining arrays: double *A = new double[cols]; – Ashmohan Jun 17 '11 at 17:57
`double *A = new double[cols]` is a dynamic memory allocation. It's just using the C++ way of allocating memory rather than the C way of allocating memory. The C way would be `double *A = (double *) malloc(cols * sizeof(double))` – QuantumMechanic Jun 17 '11 at 18:49
That would dynamically allocate a 2-D `char` array of size `locNmyo+2` by `locTmyo+2`. While the function does hand you back pointer-to-pointer-to-char (`char **`), C's rules for how pointer dereferencing is done and how arrays are dealt with internally mean that if you have `char **array = alloc_2d_char(locNmyo+2, locTmyo+2);` you will be able to do `array[i][j]` and it will Just Work. Though when you're done with the array you need to properly free it. First you must free the memory pointed to by `&array[0][0]` and then you can free the pointers-to-char pointed to by `array`. – QuantumMechanic Jun 20 '11 at 2:05

The first malloc is getting memory for the 2D character array. The second malloc is getting memory for rows index.

The for loop is setting the pointer to each row.

Finally the row index is returned.

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Thanks Richard. I may have need this simplified further...so, OK, as I understand it, "alloc_2D_char" is a pointer to a pointer (and the variables rows and columns are being used here. The parenthesis that follows does what exactly? *data is a 2D pointer, correct? What is **array? What does that line of code mean...*char **array = (char **). Finally,What is the role of the for loop? Is there a simpler method to do the exact same thing? – Ashmohan Jun 17 '11 at 0:09

You can think of the 2-D array that it is creating as an array of single-dimensional arrays. Each row entry points to an array of char that represents the column data for that row.

The following is the original code with comments added to attempt to describe each step:

``````char **alloc_2d_char(const int rows, const int cols)
{
// This allocates the chunk of memory that stores that actual data.
// It is a one single-dimensional array that has rows*cols characters.
char *data = (char *)malloc(rows*cols*sizeof(char));

// This allocates an array of pointers that will then be assigned to the
// individual rows (carved out of the previous allocation).
char **array= (char **)malloc(rows*sizeof(char*));

// This assigns each row to the appropriate position in the data array.
// The &(data[cols*i]) bit of it is the address of a portion in the
// memory pointed to by data.  The cols*i is the offset to the portion that
// represents row i.
for (int i=0; i<rows; i++)
array[i] = &(data[cols*i]);

// After doing this, then you can assign a value such as:
//   array[r][c] = 'x';
// That statement would store 'x' into data[r*c + c]

return array;
}
``````
-

Is not hard to decipher...

``````char *data = (char *)malloc(rows*cols*sizeof(char));
``````

simple memory allocation

``````char **array= (char **)malloc(rows*sizeof(char*));
``````

memory allocation of #row char pointers

``````array[i] = &(data[cols*i]);
``````

every array[i] is a pointer, a pointer to data[cols*i]

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Each `*` in a declaration refers to one level of pointer indirection. so `int **` means a pointer to a pointer to an int. So your function:

``````char **alloc_2d_char(const int rows, const int cols)
{
``````

returns a pointer to a pointer to a char.

``````  char *data = (char *)malloc(rows*cols*sizeof(char));
``````

This declares a pointer to a `char`. The pointer is called `data`. The initialization calls `malloc`, which allocates a number of bytes equal to the value of the argument. This means there are `rows*cols*sizeof(char)` bytes, which will be equal to `rows*cols`, since a `char` is 1 byte. The `malloc` function returns the pointer to the new memory, which means that `data` now points to a chunk of memory that's `rows*cols` big. The `(char *)` before the call to `malloc` just casts the new memory to the same type as the pointer `data`.

``````  char **array= (char **)malloc(rows*sizeof(char*));
``````

`array` is a pointer to a pointer to a `char`. It is also being assigned using `malloc`. The amount of memory being allocated this time is `rows*sizeof(char)`, which is equal to `rows`. This means that `array` is a pointer to a pointer to a chunk of memory big enough to hold 1 row.

`````` for (int i=0; i<rows; i++)
array[i] = &(data[cols*i]);
``````

The rest of your code initializes each element of `array` to hold the address of the corresponding row of the big chunk of memory. Your `data` pointer will point to a chunk of memory that looks like this:

``````col:   0 1 2 3 ... cols-1
row: 0 *
1 *
2 *
3 *
.
.
.
rows-1 *
``````

And your `array` pointer will point to a chunk of memory with a list of pointers, each of which points to one of the asterisks in the memory chunk above.

``````   return array;
}
``````

This just returns your `array` pointer to a pointer, which matches the return type of the `alloc_2d_char` function: `char **`. This means that the caller of the function will essentially obtain an array of pointers, and each of these pointers points to one of the rows of the 2D array.

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Just one clarification...array[i]=&(data[colsi]) is set up so because in computer memory, data is stored sequentially correct? I mean, assume I define Cols to be 20. so &data[colsi] will point to address at location 0 (i.e., i=0), then address at location 20 (i=1), then at location 40 (i=2) and so on? Is this thinking correct? – Ashmohan Jun 17 '11 at 16:59
Yes, that's right. Memory is allocated in contiguous blocks, which means you could, for example, access every element in the table (left to right, top to bottom), by iterating a pointer from `array[0]` to `array[0] + (rows * cols)` – Dominic Gurto Jun 20 '11 at 0:57