I'm a Java programmer struggling to understand C pointers and arrays. (FULL DISCLOSURE: I'm also a CS student, and yes, this question helps me with a programming assignment.)

I'm trying to create an array of int* pointers, then ensure that every pointer is NULL. Later, this will come into play when I need to look up data in the array; whether there is a valid int or a NULL in a given spot will be important.

So allocating the space for the array is easy, but how to set all those pointers to NULL? Here's my less-than-stellar attempt:


#define TABLESIZE   10

int main(int argc, char *argv[]){

    int* table = (int*) malloc(TABLESIZE * sizeof(int));

    // Initialize all *int pointers to NULL
    int i;
    for(i=0; i<TABLESIZE; i++){
        if((table+i)!=NULL){           // They may be NULL already?  I don't know...
            *(table+i) = NULL;         // This generates a warning:
                                       // "warning: assignment makes integer from pointer without a cast [-Wint-conversion]"

    // Sanity check :  are all int* are NULL ?
    for(i=0; i<TABLESIZE; i++){
        printf("%d:  %p  %d ", i, (table+i), *(table+i));
        if((table+i) == NULL)

    return 1;

Output is:

$ ./a.exe
0:  0x6000103c0  0
1:  0x6000103c4  0
2:  0x6000103c8  0
3:  0x6000103cc  0
4:  0x6000103d0  0
5:  0x6000103d4  0
6:  0x6000103d8  0
7:  0x6000103dc  0
8:  0x6000103e0  0
9:  0x6000103e4  0


So I'll be flat-out honest... I don't know what the above tells me. I'm guessing that I've created a 1D array where all the values in the array are valid ints, all 0.

But this is problematic for later in my program. When it comes time for my code to insert data into table[x], the code must be able to look at the array and know if another valid int was previously inserted in the same spot. If it sees table[x] = 0, does it conclude a 0 was inserted into index x, or that the spot is available?

I liked the idea of using an array of pointers to ints because that would neatly solve this problem. If my code saw:

  • table[x] --> NULL // This spot is empty and available
  • table[x] --> 0 // This spot is occupied, can't insert here

But I don't think I'm coding what I want.

Any thought/advice/comments/criticism is greatly appreciated.

Thanks! -Pete

  • 1
    @merl: That is nonsense! Typically NULL´ is #define NULL ((void *)0)`. And for documentation purpose/readbility, using the macro is recommended. Also a null pointer is not required to have a bit-representation of all-zero. Commented Sep 29, 2016 at 20:22
  • 1
    table[x] is not a pointer, but an int. So assigning it with NULL won't make sense.
    – Eugene Sh.
    Commented Sep 29, 2016 at 20:22
  • 1
    @merl: With a modern compiler and warnings enabled, you will get a type missmatch warning comparing a void * and an int. Let alone the conversion between a pointer type and an integer is implementation defined and very well will make a diference/problem on many systems. It is absolutely unclear what OP really needs! Commented Sep 29, 2016 at 20:31
  • 1
    @Olaf you are right, all I am saying is that OP cannot differentiate ints by 0 and NULL.
    – merl
    Commented Sep 29, 2016 at 20:32
  • 2
    @KeithThompson sizeof *table seem too ambiguous for people not used to this..
    – Eugene Sh.
    Commented Sep 29, 2016 at 20:38

3 Answers 3

int* table = malloc(TABLESIZE * sizeof(int));

Does not create an array of pointers, rather it creates a single int pointer to the start of block of allocated memory of size (TABLESIZE * sizeof(int))

The reason you are getting an error is that an int* is just that; a pointer to an int.

The * operator is called the 'dereference' operator. Its job when placed before a variable is to say 'go to wherever this pointer is pointing'. Therefore, the line

*(table+i) = NULL; 

Means 'go to wherever table is pointing, move along i * sizeof(int), then set that particular int to NULL. This obviously doesn't make sense - you can't set a an int to NULL, as that's a pointer value. Hence your error.

By the way, since pointers can also be treated like arrays in C, the above line is also the exact equivalent of

table[i] = NULL;

If you want your initial malloc to be an array of pointers you need to allocate space not for int but for int*, so you could do

int** table = malloc(TABLESIZE * sizeof(int*));

Then you have an int** (Double pointer - aka a pointer to a pointer) referencing a block of TABLESIZE int*'s

Once you have done this, the code below that line will correctly set your pointers to NULL. To then achieve the table as described in your question, you will need to do a further malloc for each cell before you put an int in it. So for example to put '3' into cell 2

if(*(table + 2) == NULL) {
   *(table + 2) = malloc(sizeof(int));
**(table + 2) = 3;

Note the double deference on the last line: 'Go to wherever table is pointing, move along 2 * sizeof(int*), then go to wherever that pointer is pointing.' Again, this can also be achieved with array syntax

if(table[2] == NULL) {
    table[2] = malloc(sizeof(int));
*table[2] = 3;

Be careful not to call malloc() on the same cell twice; if you do this you will have a memory leak.

  • 1
    Don't cast the return of malloc and friends, it's considered harmful. It's required in C++, but frowned upon in C Commented Sep 29, 2016 at 20:52
  • 1
    @BenWainwright: The pointer apparently exists without mallocing an object and assiggning that address. My reference is the C standard. Always a good reading. And me knowing the C language. You confuse the object and a pointer to it. Commented Sep 29, 2016 at 22:59
  • 1
    By the way, since pointers can also be treated like arrays in C, in this generic form it is at least misleading. The access to an object that is referred by a pointer can be done as the pointer would be declared as an array. That's all. There are big fundamental differences between arrays and pointers. Commented Sep 30, 2016 at 4:17
  • 1
    Do not confuse the OP, @AminNegm-Awad. int *table = NULL; does not produce a pointer to NULL -- it creates a variable of pointer type whose value, not its referrent, is NULL. I.e., a null pointer. Commented Sep 30, 2016 at 13:03
  • 1
    @BenWainwright Thanks Ben, this is great. Very clearly explained. :)
    – Pete
    Commented Sep 30, 2016 at 20:13

I'm a Java programmer struggling to understand C pointers and arrays.

Yes, the "struggling" part is evident in your code.

A C array is simply an ordered collection of elements of a specified type, arranged contiguously in memory. This is similar to a Java array, but Java provides no means for you to see or probe the arrangement of the elements in memory, and its arrays have additional data associated with them (in particular, they know their own lengths).

A C pointer is a value that represents the address of some other object, where "object" means a stored value of any type, including built-in (Java: "primitive") types, aggregate types (structures and arrays), pointer types, and even no particular type. This is similar in some ways to a Java "reference", which is reflected in the fact that Java raises "NullPointerException" if it tries to dereference a null reference.

It is very important to understand that although there is a close relationship between arrays and pointers, they are not at all the same thing. That should be clear from the descriptions above, but I regularly come across clueless claims to the contrary.

It is also important to understand that pointer values can be invalid -- not pointing to any object. You can easily have a pointer value, maybe stored in a variable or an array, whose value is garbage. This is something to manage, not to be afraid of.

Furthermore, it is important to understand that pointer values do not necessarily have to be obtained via memory allocation functions. They can also be obtained via the address-of operator (&) or through evaluation of an expression involving an array, or garbage pointer values can spring up naturally when a pointer is declared but not initialized.

I'm trying to create an array of int* pointers

I'm not sure whether you mean an array whose elements have type int * (pointer to int), an array whose elements have type int ** (pointer to pointer to int), or maybe an array whose elements have type int. My guess from your wording would be the first, reading you literally yields the second, and your actual code presents something like the third.

This would be the declaration of an array of int *:

int *table[TABLESIZE];

Not having specified an initializer, you cannot rely on any particular values for the elements until you assign values. Code similar to what you presented could be used for that (less the NULL check, which has undefined behavior on account of the initial values being indeterminate, and anyway would provide no advantage whatever), but I'd be inclined to write it slightly differently:

for (int i = 0; i < TABLESIZE; i++) {
    table[i] = NULL;

At this point, the elements of your table are all initialized with the one pointer value that you can be certain does not point to any object. You can check those pointer values, but you must not dereference them:

// Sanity check :  are all int* are NULL ?
for(int i = 0; i < TABLESIZE; i++) {
    printf("%d:  %p  ", i, (void *) table[i]);
    if(table[i] == NULL)

I liked the idea of using an array of pointers to ints because that would neatly solve this problem. If my code saw:

table[x] --> NULL // This spot is empty and available
table[x] --> 0 // This spot is occupied, can't insert here

That does not make sense, because 0 interpreted as a value of any pointer type is a null pointer constant. However, having started by assigning all elements of the table to be NULL, if you intend to set elements to valid pointers when you assign them, then you can check for NULL to see whether a spot is available, since NULL is never a pointer to an object.

Do note, by the way, that if you declare table as a bona fide array, as above, then you do not need to free it. You might, however, need to free some or all of the objects to which its elements point, depending on whether those objects were dynamically allocated, and on whether they have been or will be freed by other means.

  • Thanks John, this does make sense. I'm learning (with some bruises) that C syntax is a lot trickier than I bargained for. This goes a long way to cleaning things up. :)
    – Pete
    Commented Sep 30, 2016 at 20:12

In both C and Java, int holds an integer value. There is no additional, distinguishable null state. Usually, every possible bit-pattern for an int represents a distinct integer value, so it is not physically possible to store this extra state.

If you want to implement something that can be "either 'null' or any possible value in the range of int" then you will have to use additional storage for each array entry. (For example, you could maintain a parallel set of boolean flags indicating whether each entry is "active" or not).

An alternative solution would be to reserve one particular integer value to represent that that array entry should be considered "empty". This technique is called sentinel value.

In Java you can have an array of Integer , which is an array of references that may either be "null" or refer to an int stored elsewhere (the language manages the allocation behind the scenes). To simulate that memory layout in C the code would be:

// Allocate array and initialize all entries to NULL
int * array[ARRAYSIZE] = { NULL };

// Insert at position (repeatable)
if ( array[2] == NULL )
    array[2] = malloc( sizeof(int) );
*array[2] = 10;

// Use item
printf("%d\n", *array[2]);

// Remove from position
free( array[2] );
array[2] = NULL;

To avoid memory leaks you will need to remember to loop through and do the removal procedure before array goes out of scope. It would also be good to check for malloc failure and abort the program or take some other action.

Note that this technique would be considered unusual in C, and not space-efficient compared to the other available options.

  • Ah. The second part of your answer presents a very plausible explanation for what the OP wants to do. I've enough Java background to be a bit embarrassed that it did not occur to me. Commented Sep 30, 2016 at 11:52
  • @M.M This is awesome, thanks for taking the time to lay this out. I've copied this into my notes. :)
    – Pete
    Commented Sep 30, 2016 at 20:11
  • int * array[ARRAYSIZE] = { NULL }; only initialises the 1st element to NULL all other elements are initialised to binary 0s, which not necessarily needs to result in the array's elements carrying a NULL. Although the C Standard states that char * p = 0; and char p = NULL shall compare equal, NULL does not necessarily needs to be represented by a binary 0. Deriving from this: if ( array[2] == NULL ) may fail.
    – alk
    Commented Oct 2, 2016 at 17:36
  • @alk no, it actually makes null pointers. See C11 6.7.9/21 and /10
    – M.M
    Commented Oct 2, 2016 at 21:38
  • @M.M:I stand corrected. I somehow missed 6.7.9/21 explicitly refers */10. Thanks for pointing me to this. I seem to have mixed this up with case of doing: memset(array, 0, sizeof array);
    – alk
    Commented Oct 3, 2016 at 5:34

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