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I have a section of code in which two array are declared with sizes of 6 and 13, but when 'sizeof()' is used the lengths are returned as 12 and 26.

#include <iostream>
using namespace std;

int main(){


    short int races[6] = {DWARF,ELF,GNOME,HALFELF,HALFLING,HUMAN};

    cout << "sizeof(races)\t"  << sizeof(races) << endl;
    cout << "sizeof(classes)\t"  << sizeof(classes) << endl;


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After you take everyone's advice below and use sizeof(array_var)/sizeof(array_var[0]) remember it does NOT work when you replace the array_var with a pointer_var. If that sounded confusing to you I suggest you read more on arrays, pointers, and the distinguised differences between them. – WhozCraig Nov 2 '12 at 18:34
Look at what you are doing: You are declaring two arrays one with 6 items and one with 13 items. You then call sizeof on these arrays, which, predictably, returns the number of elements in the arrays multiplied by the size of each element. Since you declared your arrays as short int which, on your platform, are 16-bits (or 2 bytes) each, the compiler correctly returns 12 (or 2 * 6) and 26 (or 2 * 13) bytes for races and classes respectively. – Nik Bougalis Nov 2 '12 at 18:36
up vote 10 down vote accepted

sizeof returns the size of a variable (in this case, your arrays), where sizeof(char) is 1. Since a char is one byte wide, sizeof returns the size of the variable in bytes. Since each short int is two bytes wide on your system, an array of 6 of them will have size 12, and an array of 13 will have size 26.

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True, though in this case "byte" only means "8 bits" when an unsigned char is 8 bits long. – Greg Jandl Nov 2 '12 at 18:33
@slavik262 In C everything is defined in terms of sizeof(char), which is by definition 1. If chars are larger than 1 byte you'd have a platform where there is no type small enough to represent 1 byte. This would be legal but bizarre. – John Kugelman Nov 2 '12 at 18:40
The number of bits in an unsigned char is specified by CHAR_BIT from limits.h. sizeof (unsigned char) will always evaluate to 1. – Greg Jandl Nov 2 '12 at 18:43
@slavik262, John Kugelman: sizeof(char) is defined to be 1 in §5.3.3. A byte is at least 8 bits wide in C++11 (§1.7). – dyp Nov 2 '12 at 18:46
@JohnKugelman It wouldn't be legal; as DyP says, C++ defines sizeof to return size "in bytes" (for C++'s own definition of bytes) and sizeof(char) to be 1. Of course it's possible that the byte as defined by C++ might not be a byte as the hardware engineer for a given platform would think of it. – bames53 Nov 2 '12 at 19:07

sizeof returns the size in bytes, which for an array is the number of items × the size of each item. To get the number of items divide by the size of one element.

sizeof(races) / sizeof(races[0])

Be careful with this. It will only work for arrays whose size is known at compile time. This will not work:

void func(short int array[])
    size_t size = sizeof(array) / sizeof(array[0]);

Here array is actually a short int * and sizeof(array) does not return the actual size of the array, which is unknown at compile time.

This is one of many reasons to prefer std::vector or std::array to raw arrays in C++.

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Under what circumstance would this ever be used? If you're allocating a non-fixed size array, you would know (or at some point calculate) the number of members. Better yet, you could use a vector. – Matt Kline Nov 2 '12 at 18:30
@slavik262 If you have a constant array somewhere, this kind of code would keep you from having to update the array and the count of items separately. – Collin Nov 2 '12 at 18:31
You could also use a std::array. – dyp Nov 2 '12 at 18:32
@slavik262 Yeah, you know the size. Without the division though, you have to remember to update both the array and the size field when something changes. – Collin Nov 2 '12 at 18:34
@slavik262 The OP could leave out the explicit 6 and 13 and this trick would still work. – John Kugelman Nov 2 '12 at 18:37

sizeof returns the actual memory in bytes used by the array. A fairly common idiom is to do something like this:

size_t num_races = sizeof(races) / sizeof(races[0]);

num_races would then have the number of elements in the array stored in it.

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sizeof is an operator in C++ that measure the size in number of bytes.I think in your machine integer take 2 bytes that's why It's displaying the double the size of the array.

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Its displaying 2x because he's using arrays of unsigned short integers, which on his platform are 16-bits wide. The machine integer on his platform is likely 32 bits. – WhozCraig Nov 2 '12 at 18:37

The sizeof operator is measured in units such that an unsigned char is 1 unit.

On your platform, short is twice as large as char, thus the results you're seeing.

To properly determine array length, you could use a macro such as:

#define ARRAY_LEN(ary) (sizeof (ary) / sizeof (ary[0]))
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The sizeof operator returns the size in bytes required to represent the type (at compile time).

double array[10]; // type of array is: double[10]

sizeof(array) has the same meaning as sizeof(double[10]), which is equal to:

sizeof(double) * 10

It's an array that can hold 10 double values. sizeof(array[0]) means: size of a single element in array, which is the same as sizeof(double) here. To get the actual number of elements, you have to divide the size of the array by the size of a single element:

size_t num_elem = sizeof(array) / sizeof(array[0]);

However, this doesn't work on pointers!

double* p = array;

sizeof(p) actually translates to sizeof(double*). Its size has nothing to do with the size of double or the size of the array it's pointing to. Instead, it's the size required to store the address to a memory location (32 bits on a 32bit operating). The information about the number of elements is lost!

If you want to safely get the number of elements in an array, you can use this template:

template<typename T, size_t N>
size_t inline static_arrlen(T (&)[N]) {
    return N;

At compile-time, it deduces the type T and number of elements N, returning N.

size_t num_elem = static_arrlen(array); // T=double, N=10

If you're trying to get the array size from a pointer, it won't compile:

static_arrlen(p); // ERROR: could not deduce template argument 
                  // for 'T (&)[N]' from 'double *'
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