397

First off, here is some code:

int main() 
{
    int days[] = {1,2,3,4,5};
    int *ptr = days;
    printf("%u\n", sizeof(days));
    printf("%u\n", sizeof(ptr));

    return 0;
}

Is there a way to find out the size of the array that ptr is pointing to (instead of just giving its size, which is four bytes on a 32-bit system)?

8
  • 94
    I've always used parens with sizeof - sure it makes it look like a function call, but I think it's clearer. Jan 29, 2009 at 16:44
  • 21
    Why not? Do you have something against superfluous parentheses? I think it reads a little more easily with them, myself. Jan 29, 2009 at 16:44
  • 6
    @Paul: well .. assuming the left hand side of that call is a pointer to int, I'd write it as int *ptr = malloc(4 * sizeof *ptr); which to me is far clearer. Less parens to read, and bringing the literal constsant to the front, like in maths.
    – unwind
    Jan 29, 2009 at 17:32
  • 4
    @unwind - don't allocate an array of pointers when you meant an array of ints! Jan 29, 2009 at 17:47
  • 6
    There is no "pointer pointing to an array" here. Just a pointer pointing to an int.
    – newacct
    Feb 28, 2013 at 19:01

17 Answers 17

344

No, you can't. The compiler doesn't know what the pointer is pointing to. There are tricks, like ending the array with a known out-of-band value and then counting the size up until that value, but that's not using sizeof().

Another trick is the one mentioned by Zan, which is to stash the size somewhere. For example, if you're dynamically allocating the array, allocate a block one size_t bigger than the one you need, stash the size in the there, and return ptr+sizeof(size_t) as the pointer to the array. When you need the size, decrement the pointer and peek at the stashed value. Just remember to free the whole block starting from the beginning, and not just the array.

17
  • 22
    I'm sorry for this posting a comment so late but if the compiler does not know what the pointer is pointing to how does free know how much memory to clear? I do know that this information is stored internally for functions like free to use. So my question is why can' the compiler do so too? Mar 3, 2013 at 19:19
  • 18
    @viki.omega9, because free discovers the size at runtime. The compiler can't know the size because you could make the array a different size depending on runtime factors (command line arguments, contents of a file, phase of moon,etc). Mar 3, 2013 at 20:48
  • 21
    Quick follow up, why isn't there a function that can return the size the way free does? Mar 3, 2013 at 22:52
  • 5
    Well, if you could guarantee that the function was only called with malloced memory and the library tracks the malloced memory the way most I've seen do (by using an int before the returned pointer) then you could write one. But if the pointer is to a static array or the like, it would fail. Similarly, there is no guarantee that the size of malloced memory is accessible to your program. Mar 3, 2013 at 23:11
  • 15
    @viki.omega9: Another thing to keep in mind is that the size recorded by the malloc/free system may not be the size you asked for. You malloc 9 bytes and get 16. Malloc 3K bytes and get 4K. Or similar situations.
    – Zan Lynx
    Jul 20, 2014 at 3:48
117

The answer is, "No."

What C programmers do is store the size of the array somewhere. It can be part of a structure, or the programmer can cheat a bit and malloc() more memory than requested in order to store a length value before the start of the array.

3
  • 3
    Thats how pascal strings are implemented
    – dsm
    Jan 29, 2009 at 16:44
  • 8
    and apparently pascal strings are why excel runs so fast! Jul 14, 2010 at 19:48
  • 8
    @Adam: It is fast. I use it in a list of strings implementation of mine. It is super-fast to linear search because it is: load size, prefetch pos+size, compare size to search size, if equal strncmp, move to next string, repeat. It's faster than binary search up to about 500 strings.
    – Zan Lynx
    Jul 14, 2010 at 19:52
57

For dynamic arrays (malloc or C++ new) you need to store the size of the array as mentioned by others or perhaps build an array manager structure which handles add, remove, count, etc. Unfortunately C doesn't do this nearly as well as C++ since you basically have to build it for each different array type you are storing which is cumbersome if you have multiple types of arrays that you need to manage.

For static arrays, such as the one in your example, there is a common macro used to get the size, but it is not recommended as it does not check if the parameter is really a static array. The macro is used in real code though, e.g. in the Linux kernel headers although it may be slightly different than the one below:

#if !defined(ARRAY_SIZE)
    #define ARRAY_SIZE(x) (sizeof((x)) / sizeof((x)[0]))
#endif

int main()
{
    int days[] = {1,2,3,4,5};
    int *ptr = days;
    printf("%u\n", ARRAY_SIZE(days));
    printf("%u\n", sizeof(ptr));
    return 0;
}

You can google for reasons to be wary of macros like this. Be careful.

If possible, the C++ stdlib such as vector which is much safer and easier to use.

11
  • 13
    ARRAY_SIZE is a common paradigm used by practical programmers everywhere.
    – Sanjaya R
    Jan 29, 2009 at 17:19
  • 6
    Yes it is a common paradigm. You still need to use it cautiously though as it is easy to forget and use it on a dynamic array.
    – Ryan
    Jan 29, 2009 at 17:27
  • 2
    Yes, good point, but the question being asked was about the pointer one, not the static array one. Jan 29, 2009 at 17:40
  • 2
    That ARRAY_SIZE macro always works if its argument is an array (i.e. expression of array type). For your so-called "dynamic array", you never get an actual "array" (expression of array type). (Of course, you can't, since array types include their size at compile-time.) You just get a pointer to the first element. Your objection "does not check if the parameter is really a static array" is not really valid, since they are different as one is an array and the other isn't.
    – newacct
    Feb 28, 2013 at 18:52
  • 4
    There is a template function floating around that does the same thing but will prevent the use of pointers. Apr 23, 2013 at 2:24
19

There is a clean solution with C++ templates, without using sizeof. The following getSize() function returns the size of any static array:

#include <cstddef>

template<typename T, std::size_t SIZE>
constexpr std::size_t getSize(T (&)[SIZE]) {
    return SIZE;
}

Here is an example with a foo_t structure:

#include <cstddef>
#include <cstdio>

template<typename T, std::size_t SIZE>
constexpr std::size_t getSize(T (&)[SIZE]) {
    return SIZE;
}

struct foo_t {
    int ball;
};

int main()
{
    foo_t foos3[] = {{1},{2},{3}};
    foo_t foos5[] = {{1},{2},{3},{4},{5}};
    std::printf("%u\n", getSize(foos3));
    std::printf("%u\n", getSize(foos5));
}

Output:

3
5
5
  • 1
    I have never seen the notation T (&)[SIZE]. Can you explain what this means? Also you could mention constexpr in this context. Jun 4, 2014 at 9:43
  • 7
    That's nice if you use c++ and you actually have a variable of an array type. Neither of them is the case in the question: Language is C, and the thing the OP wants to get the array size from is a simple pointer.
    – Oguk
    Oct 12, 2014 at 7:02
  • would this code lead to code bloat by recreating the same code for every different size/type combination or is that magically optimised out of existence by the compiler? Aug 28, 2016 at 10:43
  • @WorldSEnder: That's C++ syntax for a reference of array type (with no variable name, just a size and element-type). Jun 19, 2018 at 2:53
  • @user2796283: This function is optimized away entirely at compile time; no magic is needed; it's not combining anything to a single definition, it's simply inlining it away to a compile-time constant. (But in a debug build, yes, you'd have a bunch of separate functions that return different constants. Linker magic might merge ones that use the same constant. The caller doesn't pass SIZE as an arg, it's a template param that has to already be known by the function definition.) Jun 19, 2018 at 2:55
11

As all the correct answers have stated, you cannot get this information from the decayed pointer value of the array alone. If the decayed pointer is the argument received by the function, then the size of the originating array has to be provided in some other way for the function to come to know that size.

Here's a suggestion different from what has been provided thus far,that will work: Pass a pointer to the array instead. This suggestion is similar to the C++ style suggestions, except that C does not support templates or references:

#define ARRAY_SZ 10

void foo (int (*arr)[ARRAY_SZ]) {
    printf("%u\n", (unsigned)sizeof(*arr)/sizeof(**arr));
}

But, this suggestion is kind of silly for your problem, since the function is defined to know exactly the size of the array that is passed in (hence, there is little need to use sizeof at all on the array). What it does do, though, is offer some type safety. It will prohibit you from passing in an array of an unwanted size.

int x[20];
int y[10];
foo(&x); /* error */
foo(&y); /* ok */

If the function is supposed to be able to operate on any size of array, then you will have to provide the size to the function as additional information.

0
6

For this specific example, yes, there is, IF you use typedefs (see below). Of course, if you do it this way, you're just as well off to use SIZEOF_DAYS, since you know what the pointer is pointing to.

If you have a (void *) pointer, as is returned by malloc() or the like, then, no, there is no way to determine what data structure the pointer is pointing to and thus, no way to determine its size.

#include <stdio.h>

#define NUM_DAYS 5
typedef int days_t[ NUM_DAYS ];
#define SIZEOF_DAYS ( sizeof( days_t ) )

int main() {
    days_t  days;
    days_t *ptr = &days; 

    printf( "SIZEOF_DAYS:  %u\n", SIZEOF_DAYS  );
    printf( "sizeof(days): %u\n", sizeof(days) );
    printf( "sizeof(*ptr): %u\n", sizeof(*ptr) );
    printf( "sizeof(ptr):  %u\n", sizeof(ptr)  );

    return 0;
} 

Output:

SIZEOF_DAYS:  20
sizeof(days): 20
sizeof(*ptr): 20
sizeof(ptr):  4
6

You can do something like this:

int days[] = { /*length:*/5, /*values:*/ 1,2,3,4,5 };
int *ptr = days + 1;
printf("array length: %u\n", ptr[-1]);
return 0;
5

There is no magic solution. C is not a reflective language. Objects don't automatically know what they are.

But you have many choices:

  1. Obviously, add a parameter
  2. Wrap the call in a macro and automatically add a parameter
  3. Use a more complex object. Define a structure which contains the dynamic array and also the size of the array. Then, pass the address of the structure.
1
  • Objects know what they are . But if you point to a subobject, there's no way of getting information about the complete object or a larger subobject
    – M.M
    Jan 29, 2020 at 4:14
3

My solution to this problem is to save the length of the array into a struct Array as a meta-information about the array.

#include <stdio.h>
#include <stdlib.h>

struct Array
{
    int length;

    double *array;
};

typedef struct Array Array;

Array* NewArray(int length)
{
    /* Allocate the memory for the struct Array */
    Array *newArray = (Array*) malloc(sizeof(Array));

    /* Insert only non-negative length's*/
    newArray->length = (length > 0) ? length : 0;

    newArray->array = (double*) malloc(length*sizeof(double));

    return newArray;
}

void SetArray(Array *structure,int length,double* array)
{
    structure->length = length;
    structure->array = array;
}

void PrintArray(Array *structure)
{       
    if(structure->length > 0)
    {
        int i;
        printf("length: %d\n", structure->length);
        for (i = 0; i < structure->length; i++)
            printf("%g\n", structure->array[i]);
    }
    else
        printf("Empty Array. Length 0\n");
}

int main()
{
    int i;
    Array *negativeTest, *days = NewArray(5);

    double moreDays[] = {1,2,3,4,5,6,7,8,9,10};

    for (i = 0; i < days->length; i++)
        days->array[i] = i+1;

    PrintArray(days);

    SetArray(days,10,moreDays);

    PrintArray(days);

    negativeTest = NewArray(-5);

    PrintArray(negativeTest);

    return 0;
}

But you have to care about set the right length of the array you want to store, because the is no way to check this length, like our friends massively explained.

2

This is how I personally do it in my code. I like to keep it as simple as possible while still able to get values that I need.

typedef struct intArr {
    int size;
    int* arr; 
} intArr_t;

int main() {
    intArr_t arr;
    arr.size = 6;
    arr.arr = (int*)malloc(sizeof(int) * arr.size);

    for (size_t i = 0; i < arr.size; i++) {
        arr.arr[i] = i * 10;
    }

    return 0;
}
2
  • Prefer size_t to store the size. Mar 14, 2021 at 19:03
  • That's a really good&simple approach! BTW intArr after struct can be omitted. Also a shorter and more readable way of writing the malloc line would be arr.arr = malloc(arr.size * sizeof *arr.arr); which makes it more reusable because you don't need to specify "int".
    – Amarok24
    Sep 7, 2022 at 20:28
1

No, you can't use sizeof(ptr) to find the size of array ptr is pointing to.

Though allocating extra memory(more than the size of array) will be helpful if you want to store the length in extra space.

1
int main() 
{
    int days[] = {1,2,3,4,5};
    int *ptr = days;
    printf("%u\n", sizeof(days));
    printf("%u\n", sizeof(ptr));

    return 0;
}

Size of days[] is 20 which is no of elements * size of it's data type. While the size of pointer is 4 no matter what it is pointing to. Because a pointer points to other element by storing it's address.

1
  • 1
    sizeof(ptr) is the size of pointer and sizeof(*ptr) is the size of pointer to which
    – 王奕然
    Dec 27, 2016 at 4:33
1

In strings there is a '\0' character at the end so the length of the string can be gotten using functions like strlen. The problem with an integer array, for example, is that you can't use any value as an end value so one possible solution is to address the array and use as an end value the NULL pointer.

#include <stdio.h>
/* the following function will produce the warning:
 * ‘sizeof’ on array function parameter ‘a’ will
 * return size of ‘int *’ [-Wsizeof-array-argument]
 */
void foo( int a[] )
{
    printf( "%lu\n", sizeof a );
}
/* so we have to implement something else one possible
 * idea is to use the NULL pointer as a control value
 * the same way '\0' is used in strings but this way
 * the pointer passed to a function should address pointers
 * so the actual implementation of an array type will
 * be a pointer to pointer
 */
typedef char * type_t; /* line 18 */
typedef type_t ** array_t;
int main( void )
{
    array_t initialize( int, ... );
    /* initialize an array with four values "foo", "bar", "baz", "foobar"
     * if one wants to use integers rather than strings than in the typedef
     * declaration at line 18 the char * type should be changed with int
     * and in the format used for printing the array values 
     * at line 45 and 51 "%s" should be changed with "%i"
     */
    array_t array = initialize( 4, "foo", "bar", "baz", "foobar" );

    int size( array_t );
    /* print array size */
    printf( "size %i:\n", size( array ));

    void aprint( char *, array_t );
    /* print array values */
    aprint( "%s\n", array ); /* line 45 */

    type_t getval( array_t, int );
    /* print an indexed value */
    int i = 2;
    type_t val = getval( array, i );
    printf( "%i: %s\n", i, val ); /* line 51 */

    void delete( array_t );
    /* free some space */
    delete( array );

    return 0;
}
/* the output of the program should be:
 * size 4:
 * foo
 * bar
 * baz
 * foobar
 * 2: baz
 */
#include <stdarg.h>
#include <stdlib.h>
array_t initialize( int n, ... )
{
    /* here we store the array values */
    type_t *v = (type_t *) malloc( sizeof( type_t ) * n );
    va_list ap;
    va_start( ap, n );
    int j;
    for ( j = 0; j < n; j++ )
        v[j] = va_arg( ap, type_t );
    va_end( ap );
    /* the actual array will hold the addresses of those
     * values plus a NULL pointer
     */
    array_t a = (array_t) malloc( sizeof( type_t *) * ( n + 1 ));
    a[n] = NULL;
    for ( j = 0; j < n; j++ )
        a[j] = v + j;
    return a;
}
int size( array_t a )
{
    int n = 0;
    while ( *a++ != NULL )
        n++;
    return n;
}
void aprint( char *fmt, array_t a )
{
    while ( *a != NULL )
        printf( fmt, **a++ );   
}
type_t getval( array_t a, int i )
{
    return *a[i];
}
void delete( array_t a )
{
    free( *a );
    free( a );
}
2
  • Your code is full of comments, but I think it would make everything easier if you added some general explanation of how this works outside of code, as normal text. Can you please edit your question and do it? Thank you! Mar 11, 2017 at 12:16
  • Creating an array of pointers to each element so you can linear-search it for NULL is probably the least efficient alternative imaginable to just storing a separate size directly. Especially if you actually use this extra layer of indirection all the time. Jun 19, 2018 at 3:03
1
#include <stdio.h>
#include <string.h>
#include <stddef.h>
#include <stdlib.h>

#define array(type) struct { size_t size; type elem[0]; }

void *array_new(int esize, int ecnt)
{
    size_t *a = (size_t *)malloc(esize*ecnt+sizeof(size_t));
    if (a) *a = ecnt;
    return a;
}
#define array_new(type, count) array_new(sizeof(type),count)
#define array_delete free
#define array_foreach(type, e, arr) \
    for (type *e = (arr)->elem; e < (arr)->size + (arr)->elem; ++e)

int main(int argc, char const *argv[])
{
    array(int) *iarr = array_new(int, 10);
    array(float) *farr = array_new(float, 10);
    array(double) *darr = array_new(double, 10);
    array(char) *carr = array_new(char, 11);
    for (int i = 0; i < iarr->size; ++i) {
        iarr->elem[i] = i;
        farr->elem[i] = i*1.0f;
        darr->elem[i] = i*1.0;
        carr->elem[i] = i+'0';
    }
    array_foreach(int, e, iarr) {
        printf("%d ", *e);
    }
    array_foreach(float, e, farr) {
        printf("%.0f ", *e);
    }
    array_foreach(double, e, darr) {
        printf("%.0lf ", *e);
    }
    carr->elem[carr->size-1] = '\0';
    printf("%s\n", carr->elem);

    return 0;
}
0
 #define array_size 10

 struct {
     int16 size;
     int16 array[array_size];
     int16 property1[(array_size/16)+1]
     int16 property2[(array_size/16)+1]
 } array1 = {array_size, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9};

 #undef array_size

array_size is passing to the size variable:

#define array_size 30

struct {
    int16 size;
    int16 array[array_size];
    int16 property1[(array_size/16)+1]
    int16 property2[(array_size/16)+1]
} array2 = {array_size};

#undef array_size

Usage is:

void main() {

    int16 size = array1.size;
    for (int i=0; i!=size; i++) {

        array1.array[i] *= 2;
    }
}
0

Most implementations will have a function that tells you the reserved size for objects allocated with malloc() or calloc(), for example GNU has malloc_usable_size()

However, this will return the size of the reversed block, which can be larger than the value given to malloc()/realloc().


0

There is a popular macro, which you can define for finding number of elements in the array (Microsoft CRT even provides it OOB with name _countof):

#define countof(x) (sizeof(x)/sizeof((x)[0]))

Then you can write:

int my_array[] = { ... some elements ... };
printf("%zu", countof(my_array)); // 'z' is correct type specifier for size_t

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