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How do I determine the size of my array in C?

That is, the number of elements the array can hold?

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18 Answers 18

up vote 605 down vote accepted

Executive summary:

int a[17];
n = sizeof(a)/sizeof(a[0]);

To determine the size of your array in bytes, you can use the sizeof operator:

int a[17];
int n = sizeof(a);

On my computer, ints are 4 bytes long, so n is 68.

To determine the number of elements in the array, we can divide the total size of the array by the size of the array element. You could do this with the type, like this:

int a[17];
int n = sizeof(a) / sizeof(int);

and get the proper answer (68 / 4 = 17), but if the type of a changed you would have a nasty bug if you forgot to change the sizeof(int) as well.

So the preferred divisor is sizeof(a[0]), the size of the zeroeth element of the array.

int a[17];
int n = sizeof(a) / sizeof(a[0]);

Another advantage is that you can now easily parameterize the array name in a macro and get:

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

int a[17];
int n = NELEMS(a);
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The generated code will be identical, since the compiler knows the type of *int_arr at compile time (and therefore the value of sizeof(*int_arr)). It will be a constant, and the compiler can optimize accordingly. – Mark Harrison Sep 21 '13 at 19:58
It should be the case with all compilers, since the results of sizeof is defined as a compile-time constant. – Mark Harrison Sep 22 '13 at 5:39
Important: Don't stop reading here, read the next answer! This only works for arrays on the stack, e.g. if you're using malloc() or accessing a function parameter, you're out of luck. See below. – Markus Jan 27 '14 at 14:21
For Windows API programming in C or C++, there is the ARRAYSIZE makro defined in WinNT.h (which gets pulled in by other headers). So WinAPI users don't need to define their own makro. – Lumi Apr 23 '14 at 8:24
@Markus it works for any variable which has an array type; this doesn't have to be "on the stack". E.g. static int a[20]; . But your comment is useful to readers that may not realize the difference between an array and a pointer. – M.M Oct 6 '14 at 2:45

The sizeof way is the right way iff you are dealing with arrays not received as parameters. An array sent as a parameter to a function is treated as a pointer, so sizeof will return the pointer's size, instead of the array's.

Thus, inside functions this method does not work. Instead, always pass an additional parameter size_t size indicating the number of elements in the array.


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

void printSizeOf(int intArray[]);
void printLength(int intArray[]);

int main(int argc, char* argv[])
    int array[] = { 0, 1, 2, 3, 4, 5, 6 };

    printf("sizeof of array: %d\n", (int) sizeof(array));

    printf("Length of array: %d\n", (int)( sizeof(array) / sizeof(array[0]) ));

void printSizeOf(int intArray[])
    printf("sizeof of parameter: %d\n", (int) sizeof(intArray));

void printLength(int intArray[])
    printf("Length of parameter: %d\n", (int)( sizeof(intArray) / sizeof(intArray[0]) ));

Output (in a 64-bit Linux OS):

sizeof of array: 28
sizeof of parameter: 8
Length of array: 7
Length of parameter: 2

Output (in a 32-bit windows OS):

sizeof of array: 28
sizeof of parameter: 4
Length of array: 7
Length of parameter: 1
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why is length of parameter:2 if only a pointer to the 1st array element is passed? – Bbvarghe Aug 5 '13 at 2:42
@Bbvarghe That's because pointers in 64bit systems are 8 bytes (sizeof(intArray)), but ints are still (usually) 4 bytes long (sizeof(intArray[0])). – Elideb Aug 28 '13 at 17:33
@Pacerier: There is no correct code - the usual solution is to pass the length along with the array as a separate argument. – Jean Hominal Oct 5 '13 at 13:58
Wait, so there's no way to access the array directly from a pointer and see its size? New to C here. – sudo Dec 1 '13 at 6:37
@Elideb Thanks for that. I think I read something like that elsewhere after I posted the comment. What ultimately helped me understand it is that when sizeof is called in the same scope that an array is declared, it sees its parameter as a parameter of type int[7] (using the example in the answer), but when called in another scope it sees its parameter as a parameter of type int *. Basically the same thing you said, just in my own words :) – Nickolai Feb 24 '15 at 16:09

It is worth noting that sizeof doesn't help when dealing with an array value that has decayed to a pointer: even though it points to the start of an array, to the compiler it is the same as a pointer to a single element of that array. A pointer does not "remember" anything else about the array that was used to initialize it.

int a[10];
int* p = a;

assert(sizeof(a) / sizeof(a[0]) == 10);
assert(sizeof(p) == sizeof(int*));
assert(sizeof(*p) == sizeof(int));
share|improve this answer
I remember that the CRAY had C with char of 32 bits. All the standard says is that integer values from 0 to 127 can be represented, and its range is at least either -127 to 127 (char is signed) or 0 to 255 (char is unsigned). – vonbrand Feb 1 '13 at 20:57
This is an excellent response. I want to comment that all of above assertions are evaluated to TRUE. – Javad Jun 4 '15 at 23:23

The sizeof "trick" is the best way I know, with one small but (to me, this being a major pet peeve) important change in the use of parenthesis.

As the Wikipedia entry makes clear, C's sizeof is not a function; it's an operator. Thus, it does not require parenthesis around its argument, unless the argument is a type name. This is easy to remember, since it makes the argument look like a cast expression, which also uses parenthesis.

So: If you have the following:

int myArray[10];

You can find the number of elements with code like this:

size_t n = sizeof myArray / sizeof *myArray;

That, to me, reads a lot easier than the alternative with parenthesis. I also favor use of the asterisk in the right-hand part of the division, since it's more concise than indexing.

Of course, this is all compile-time too, so there's no need to worry about the division affecting the performance of the program. So use this form wherever you can.

It is always best to use sizeof on an actual object when you have one, rather than on a type, since then you don't need to worry about making an error and stating the wrong type.

For instance, say you have a function that outputs some data as a stream of bytes, for instance across a network. Let's call the function send(), and make it take as arguments a pointer to the object to send, and the number of bytes in the object. So, the prototype becomes:

void send(const void *object, size_t size);

And then you need to send an integer, so you code it up like this:

int foo = 4711;
send(&foo, sizeof (int));

Now, you've introduced a subtle way of shooting yourself in the foot, by specifying the type of foo in two places. If one changes but the other doesn't, the code breaks. Thus, always do it like this:

send(&foo, sizeof foo);

Now you're protected. Sure, you duplicate the name of the variable, but that has a high probability of breaking in a way the compiler can detect, if you change it.

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Btw, are they identical instructions at the processor level? Does sizeof(int) require lesser instructions than sizeof(foo)? – Pacerier Sep 21 '13 at 6:53
@Pacerier: no, they are identical. Think of int x = 1+1; versus int x = (1+1);. Here, parentheses are purely absolutely just aesthetic. – quetzalcoatl Oct 5 '13 at 13:22
@Aidiakapi That's not true, consider C99 VLAs. – unwind Jan 13 at 13:18
@unwind Thanks, I stand corrected. To correct my comment, sizeof will always be constant in C++ and C89. With C99's variable length arrays, it may be evaluated at runtime. – Aidiakapi Jan 13 at 16:47
int size = (&arr)[1] - arr;

Check out this link for explanation

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Small nitpick: the result of pointer subtraction has type ptrdiff_t. (Typically on 64-bit system, this will be a larger type than int). Even if you change int to ptrdiff_t in this code, it still has a bug if arr takes up more than half of the address space. – M.M Oct 6 '14 at 2:37
@M.M Another small nitpick: Depending on your system architecture, the address space is not nearly as large as the pointer size on most systems. Windows for example limits address space for 64-bit applications to 8TB or 44 bits. So even if you have an array larger than half of your address space 4.1TB for example, it'll not be a bug. Only if your address space exceeds 63-bits on those systems, it's possible to even encounter such bug. In general, don't worry about it. – Aidiakapi Jan 8 at 17:00

If you know the data type of the array, you can use something like:

int arr[] = {23, 12, 423, 43, 21, 43, 65, 76, 22};

int noofele = sizeof(arr)/sizeof(int);

Or if you don't know the data type of array, you can use something like:

noofele = sizeof(arr)/sizeof(arr[0]);

Note: This thing only works if the array is not defined at run time (like malloc) and the array is not passed in a function. In both cases, arr (array name) is a pointer.

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int noofele = sizeof(arr)/sizeof(int); is only half-way better than coding int noofele = 9;. Using sizeof(arr) maintains flexibility should the array size change. Yet sizeof(int) needs an update should the type of arr[] change. Better to use sizeof(arr)/sizeof(arr[0]) even if the type is well known. Unclear why using int for noofele vs. size_t, the type returned by sizeof(). – chux May 20 at 20:50

For multidimensional arrays it is a tad more complicated. Oftenly people define explicit macro constants, i.e.

#define g_rgDialogRows   2
#define g_rgDialogCols   7

static char* g_rgDialog[g_rgDialogRows][rgDialogCols] =
    { " ",  " ",    " ",    " 494", " 210", " Generic Sample Dialog", " " },
    { " 1", " 330", " 174", " 88",  " ",    " OK",        " " },

But these constants can be evaluated at compile-time too with sizeof:

#define rows_of_array(name)       \
    (sizeof(name   ) / sizeof(name[0][0]) / columns_of_array(name))
#define columns_of_array(name)    \
    (sizeof(name[0]) / sizeof(name[0][0]))

static char* g_rgDialog[][7] = { /* ... */ };

assert(   rows_of_array(g_rgDialog) == 2);
assert(columns_of_array(g_rgDialog) == 7);

Note that this code works in C and C++. For arrays with more than two dimensions use


etc., ad infinitum.

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sizeof(array) / sizeof(array[0])
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I apologise for commenting on such an old thread but I just wanted to clear up something I messed up explaining when I edited Mark Harrison's answer. I was tired and managed to fall into the old "arrays are actually pointers" trap. I would have just left a comment but apparently I'm not allowed?

My point was that the macro ARRAYELEMENTCOUNT(x) that everyone is making use of evaluates incorrectly. This, realistically, is just sensitive matter because you can't have expressions that result in an 'array' type.

/* Compile as: CL /P "macro.c" */
# define ARRAYELEMENTCOUNT(x) (sizeof (x) / sizeof (x[0]))


Actually evaluates as:

(sizeof (p + 1) / sizeof (p + 1[0]));


/* Compile as: CL /P "macro.c" */
# define ARRAYELEMENTCOUNT(x) (sizeof (x) / sizeof (x)[0])


Correctly evaluates to:

(sizeof (p + 1) / sizeof (p + 1)[0]);

This really doesn't have a lot to do with the size of arrays explicitly I've just noticed a lot of error's from not truly observing how the C preprocessor works. You always wrap the macro parameter, not an expression in might be involved in.

@AlexMelbourne, I reverted your suggested edit as it produced incorrect results for the expression p+1.

This is correct; my example was a bad one. But that's actually exactly what should happen. As I previously mentioned p + 1 will end up as a pointer type and invalidate the entire macro (just like if you attempted to use the macro in a function with a pointer parameter).

At the end of the day, in this particular instance, the fault doesn't really matter (so I'm just wasting everyone's time; huzzah!) because you don't have expressions with a type of 'array'. But really the point about preprocessor evaluation subtles I think is an important one.

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Thanks for the explanation. The original version results in a compile-time error. Clang reports "subscripted value is not an array, pointer, or vector". This seems preferable behavior in this instance, although your comments about evaluation order in macros is well taken. – Mark Harrison Feb 28 '14 at 2:30
I hadn't thought about the compiler complaint as an automatic notification of an incorrect type. Thank-you! – user2379628 Feb 28 '14 at 2:46

"you've introduced a subtle way of shooting yourself in the foot"

C 'native' arrays do not store their size. It is therefore recommended to save the length of the array in a separate variable/const, and pass it whenever you pass the array, that is:

#define MY_ARRAY_LENGTH   15
int myArray[MY_ARRAY_LENGTH];

You SHOULD always avoid native arrays (unless you can't, in which case, mind your foot). If you are writing C++, use the STL's 'vector' container. "Compared to arrays, they provide almost the same performance", and they are far more useful!

// vector is a template, the <int> means it is a vector of ints
vector<int> numbers;  

// push_back() puts a new value at the end (or back) of the vector
for (int i = 0; i < 10; i++)

// Determine the size of the array
cout << numbers.size();

See: http://www.cplusplus.com/reference/stl/vector/

share|improve this answer
I've read that the proper way to declare integer constants in C is to use an enum declaration. – Raffi Khatchadourian Aug 3 '13 at 23:08
The question is not about C++..... – Pacerier Sep 21 '13 at 6:56

@ Magnus: The standard defines sizeof as yielding the number of bytes in the object and that sizeof (char) is always one. The number of bits in a byte is implementation specific.

Edit: ANSI C++ standard section 5.3.3 Sizeof:

The sizeof operator yields the number of bytes in the object representation of its operand. [...] sizeof (char), sizeof (signed char) and sizeof (unsigned char) are 1; the result of sizeof applied to any other fundamental type is implementation-defined.

Section 1.6 The C++ memory model:

The fundamental storage unit in the C++ memory model is the byte. A byte is at least large enough to contain any member of the basic execution character set and is composed of a contiguous sequence of bits, the number of which is implementation-defined.

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Are there C references instead of C++ references? – Pacerier Sep 21 '13 at 6:59

Size of Array in C:

int a[10];
size_t size_of_array = sizeof(a);      // Size of array a
int n = sizeof (a) / sizeof (a[0]);    // No of elements in array a
size_t size_of_element = sizeof(a[0]); // Size of each element in array a                                          
                                       // Size of each element = size of type
share|improve this answer
Curious that code used size_t size_of_element yet int with int n = sizeof (a) / sizeof (a[0]); and not size_t n = sizeof (a) / sizeof (a[0]); – chux May 20 at 21:02

@Skizz: I am pretty sure I am right, although the best "source" I can give you at the moment is Wikipedia, from the article on sizeof:

Wikipedia is wrong, Skizz is right. sizeof(char) is 1, by definition.

I mean, just read the Wikipedia entry really closely to see that it's wrong. "multiples of char". sizeof(char) can never be anything other than "1". If it were, say, 2, it would mean that sizeof(char) was twice the size of char!

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...yes, and we have ensure assert(sizeof(char) < sizeof(int)). This is a deep concept... – Andreas Spindler Jan 26 '12 at 9:02

If you really want to do this to pass around your array I suggest implementing a structure to store a pointer to the type you want an array of and an integer representing the size of the array. Then you can pass that around to your functions. Just assign the array variable value (pointer to first element) to that pointer. Then you can go Array.arr[i] to get the i-th element and use Array.size to get the number of elements in the array.

I included some code for you. It's not very useful but you could extend it with more features. To be honest though, if these are the things you want you should stop using C and use another language with these features built in.

/* Absolutely no one should use this...
   By the time you're done implementing it you'll wish you just passed around
   an array and size to your functions */
/* This is a static implementation. You can get a dynamic implementation and 
   cut out the array in main by using the stdlib memory allocation methods,
   but it will work much slower since it will store your array on the heap */

#include <stdio.h>
#include <string.h>
#include "MyTypeArray.h"
/* MyTypeArray.h 
typedef struct MyType
   int age;
   char name[20];
} MyType;
typedef struct MyTypeArray
   int size;
   MyType *arr;
} MyTypeArray;

MyType new_MyType(int age, char *name);
MyTypeArray newMyTypeArray(int size, MyType *first);
End MyTypeArray.h */

/* MyTypeArray.c */
MyType new_MyType(int age, char *name)
   MyType d;
   d.age = age;
   strcpy(d.name, name);
   return d;

MyTypeArray new_MyTypeArray(int size, MyType *first)
   MyTypeArray d;
   d.size = size;
   d.arr = first;
   return d;
/* End MyTypeArray.c */

void print_MyType_names(MyTypeArray d)
   int i;
   for (i = 0; i < d.size; i++)
      printf("Name: %s, Age: %d\n", d.arr[i].name, d.arr[i].age);

int main()
   /* First create an array on the stack to store our elements in.
      Note we could create an empty array with a size instead and
      set the elements later. */
   MyType arr[] = {new_MyType(10, "Sam"), new_MyType(3, "Baxter")};
   /* Now create a "MyTypeArray" which will use the array we just
      created internally. Really it will just store the value of the pointer
      "arr". Here we are manually setting the size. You can use the sizeof
      trick here instead if you're sure it will work with your compiler. */
   MyTypeArray array = new_MyTypeArray(2, arr);
   /* MyTypeArray array = new_MyTypeArray(sizeof(arr)/sizeof(arr[0]), arr); */
   return 0;
share|improve this answer
Cannot upvote code that does strcpy(d.name, name); with no handling of overflow. – chux May 20 at 20:58

The best way is you save this information, for example, in a structure:

typedef struct {
     int *array;
     int elements;
} list_s;

Implement all necessary functions such as create, destroy, check equality, and everything else you need. It is easier to pass as a parameter.

share|improve this answer
Any reason for int elements vs. size_t elements? – chux May 20 at 21:00

You can use the & operator. Here is the source code:

int main(){

    int a[10];

    int *p; 

    printf("%p\n", (void *)a); 
    printf("%p\n", (void *)(&a+1));
    printf("---- diff----\n");
    printf("%zu\n", sizeof(a[0]));
    printf("The size of array a is %zu\n", ((char *)(&a+1)-(char *)a)/(sizeof(a[0])));

    return 0;

Here is the sample output

---- diff----
The size of array a is 10
share|improve this answer
I did not downvote, but this is like hitting a nail with a brick because you didn't notice a hammer lying next to you. Also, people tend to frown on using uninitialized variables... but here i guess it serves your purpose well enough. – Dmitri Sep 11 '14 at 21:18
@Dmitri no uninitialized variables are accessed here – M.M Oct 6 '14 at 2:39
Hmmm. Pointer subtraction leads to ptrdiff_t. sizeof() results in size_t. C does not define which is wider or higher/same rank. So the type of the quotient ((char *)(&a+1)-(char *)a)/(sizeof(a[0])) is not certainly size_t and thus printing with z can lead to UB. Simply using printf("The size of array a is %zu\n", sizeof a/sizeof a[0]); is sufficient. – chux May 20 at 21:10
int a=[10]={1,2,3,4,5};
int n=sizeof(a);

reason: calculates the no of elements held in array rather than no of free spaces allocated to it

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A modern and type-safe solution in C++:

#include <type_traits>

template <unsigned TDimension, typename TArr>
constexpr size_t sizeof_array(TArr (&))
    static_assert(std::is_array<TArr>::value,          "sizeof_array must be called on a compile-time array");
    static_assert(TDimension < std::rank<TArr>::value, "sizeof_array<TDimension>'s dimension is larger than the array");
    return std::extent<TArr, TDimension>::value;
template <typename TArr>
constexpr size_t sizeof_array(TArr (&arr)) { return sizeof_array<0, TArr>(arr); }

int main()
    int regularValue;
    int singleArr[7];
    int doubleArr[5][3];

    constexpr size_t size   = sizeof_array(singleArr);    // == 7
    constexpr size_t size0  = sizeof_array<0>(doubleArr); // == 5
    constexpr size_t size1  = sizeof_array<1>(doubleArr); // == 3

    constexpr size_t badArr = sizeof_array(regularValue); // error not an array
    constexpr size_t badDim = sizeof_array<1>(singleArr); // error dimension out of range

    return 0;
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Please explain the downvote. I understand that the question is tagged C, but when searching Google, this will pop up if you search for C++ as well. Therefore the answer might help people. If you downvoted because it's incorrect, feel free to correct me. – Aidiakapi Mar 14 at 20:42
I didn't down-vote, but if the question is tagged C, you need to stick with C code! If it was tagged C++, then you could also write C code, since a great part of C++ code is also C code. – nbro Mar 19 at 17:47
@nbro It's a site about providing helpful information to people looking for solutions. As for your remark about posting C on a C++ question, I'd consider that even worst. A lot of (not all) C code would be considered bad practice in C++. – Aidiakapi Mar 19 at 22:33
This should be posted as an answer a question about C++. It is out of place and inappropriate here ... them's the rules. "C on a C++ question, I'd consider that even worst" -- some C code wouldn't necessarily be bad practice in C++ (though the amount that qualifies keeps shrinking), but this code won't compile in C and cannot be modified to compile in C, so it qualifies as "worst". – Jim Balter Apr 4 at 5:02
@Aidiakapi I found this question on Google based on the title "How do I determine the size of my array in C". This is not the answer to that question. If you feel strongly that people may want to know the answer for C++, I suggest you create a copy of this question, but titled and worded with "C++" and then post your answer. I will upvote. – Blackhawk Apr 15 at 21:41

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