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I know there is several questions about that which gives good (and working) solutions, but none IMHO which says clearly what is the best way to achieve this. So, suppose we have some 2D array :

int tab1[100][280];

We want to make a pointer that points to this 2D array. To achieve this, we can do :

int (*pointer)[280]; // pointer creation
pointer = tab1; //assignation
pointer[5][12] = 517; // use
int myint = pointer[5][12]; // use

or, alternatively :

int (*pointer)[100][280]; // pointer creation
pointer = &tab1; //assignation
(*pointer)[5][12] = 517; // use
int myint = (*pointer)[5][12]; // use 

OK, both seems to work well. Now I would like to know :

  • what is the best way, the 1st or the 2nd ?
  • are both equals for the compiler ? (speed, perf...)
  • is one of these solutions eating more memory than the other ?
  • what is the more frequently used by developers ?
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Remember that an array of pointers (as in int *pointer[280];) is not the same thing as an array of arrays. –  Joachim Pileborg Feb 11 '13 at 9:11
hello, ferdinand. i have corrected the 1st solution with parenthesis. Apologizes. –  Chrysotribax Feb 11 '13 at 9:25

3 Answers 3

up vote 9 down vote accepted
//defines an array of 280 pointers (1120 or 2240 bytes)
int  *pointer1 [280];

//defines a pointer (4 or 8 bytes depending on 32/64 bits platform)
int (*pointer2)[280];      //pointer to an array of 280 integers
int (*pointer3)[100][280]; //pointer to an 2D array of 100*280 integers

Using pointer2 or pointer3 produce the same binary except manipulations as ++pointer2 as pointed out by WhozCraig.

My favourite is pointer3 using a typedef:

typedef int myType[100][280];
myType pointer3;

in your example:

myType *pointer;                // pointer creation
pointer = &tab1;                // assignation
(*pointer)[5][12] = 517;        // use
int myint = (*pointer)[5][12];  // use 

Note: If the array tab1 is used within a function body => this array will be placed within the call stack memory. But the stack size is limited. Using arrays bigger than the free memory stack produces a stack overflow exception.

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hello, please review my first solution : i previously forgot parenthesis in pointer creation. Apologizes. –  Chrysotribax Feb 11 '13 at 9:28
@user216993 You also wrote (pointer*) instead of (*pointer) in the second version. ;-) Ok I update my answer. Cheers –  olibre Feb 11 '13 at 9:31
Thank you, olibre for your clear response. (and apologizes again for typos...). –  Chrysotribax Feb 11 '13 at 10:02
"Using pointer2 or pointer3 produce the same binary" - That is not true when performing pointer-math. ++pointer2 will advance the pointer one "row". ++pointer3 will advance the pointer one entire matrix. They're different types –  WhozCraig Apr 9 '14 at 23:22
You are right @WhozCraig my sentence is wrong. Thanks for the feedback :) I will change it. Cheers ;) –  olibre Apr 10 '14 at 8:10

Both your examples are equivalent. However, the first one is less obvious and more "hacky", while the second one clearly states your intention.

int (*pointer)[280];
pointer = tab1;

pointer points to an 1D array of 280 integers. In your assignment, you actually assign the first row of tab1. This works since you can implicitly cast arrays to pointers (to the first element).

When you are using pointer[5][12], C treats pointer as an array of arrays (pointer[5] is of type int[280]), so there is another implicit cast here (at least semantically).

In your second example, you explicitly create a pointer to a 2D array:

int (*pointer)[100][280];
pointer = &tab1;

The semantics are clearer here: *pointer is a 2D array, so you need to access it using (*pointer)[i][j].

Both solutions use the same amount of memory (1 pointer) and will most likely run equally fast. Under the hood, both pointers will even point to the same memory location (the first element of the tab1 array), and it is possible that your compiler will even generate the same code.

The first solution is "more advanced" since one needs quite a deep understanding on how arrays and pointers work in C to understand what is going on. The second one is more explicit.

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Thanks for your response, Ferdinand. I agree with you : the second solution seems more explicit. I will continue to use this one. –  Chrysotribax Feb 11 '13 at 10:16

int *pointer[280]; //Creates 280 pointers of type int.

In 32 bit os, 4 bytes for each pointer. so 4 * 280 = 1120 bytes.

int (*pointer)[100][280]; // Creates only one pointer which is used to point an array of [100][280] ints.

Here only 4 bytes.

Coming to your question, int (*pointer)[280]; and int (*pointer)[100][280]; are different though it points to same 2D array of [100][280].

Because if int (*pointer)[280]; is incremented, then it will points to next 1D array, but where as int (*pointer)[100][280]; crosses the whole 2D array and points to next byte. Accessing that byte may cause problem if that memory doen't belongs to your process.

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hello again, please review my first solution : i previously forgot parenthesis in pointer creation. Apologizes. –  Chrysotribax Feb 11 '13 at 9:29

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