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I'm trying to simply print out the values contained in an array.

I have an array of strings called 'result'. I don't know exactly how big it is because it was automatically generated.

From what I've read, you can determine the size of an array by doing this:


Is this correct? Because for my program, sizeof(result) = 16 and sizeof(result[0]) = 16 so that code would tell me that my array is of size 1.

However that doesn't appear correct, because if I manually print out the array values like this:

std::cout << result[0] << "\n";
std::cout << result[1] << "\n";
std::cout << result[2] << "\n";
std::cout << result[3] << "\n";

...then I see the resulting values I'm looking for. The array is upwards of 100+ values in length/size.

It seems like it should be very simple to determine the size/length of an array... so hopefully I'm just missing something here.

I'm a bit of a C++ newb so any help would be appreciated.

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I used sizeof(result)/sizeof(result[0]) for primitive types and it used to work, but if you are using strings, why are you still going with array, go for a vector. – Narendra N Feb 16 '10 at 5:32
Please show the declaration for result. Without it, it's impossible to tell what your problem is. – David Thornley Feb 16 '10 at 18:26
@David Thornley: I think it is safe to assume he is not dealing with a real array containing one element, the only other way he could get 16 for both sizeof calls. – user123456 Feb 17 '10 at 0:57
@HansPassant Let us assume sensibly that the strings are stored in arrays of char (e.g. char result[][16] = { "maximum", "of", "fifteen", "characters", "per", "string" };)... What evidence is there to suggest that the machine is 128-bit? What does 128-bit even mean? Is it the width of the bus? If so, there are 64-bit machines that don't have 64-bit buses and 32-bit machines that do. Is it the width of the native types? If so, even Pentium Pros back in 1995 had a few 128-bit registers... – Seb Feb 7 at 3:24
up vote 10 down vote accepted

You cannot determine the size of an array dynamically in C++. You must pass the size around as a parameter.

As a side note, using a Standard Library container (e.g., vector) allieviates this.

In your sizeof example, sizeof(result) is asking for the size of a pointer (to presumably a std::string). This is because the actual array type "decays" to a pointer-to-element type when passed to a function (even if the function is declared to take an array type). The sizeof(result[0]) returns the size of the first element in your array, which coincidentally is also 16 bytes. It appears that pointers are 16 bytes (128-bit) on your platform.

Remember that sizeof is always evaluated at compile-time in C++, never at run-time.

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As a side comment, there are better ways of checking the size of an array (for the cases where the array is in scope and has not decayed into a pointer) that are typesafe:

// simple: runtime result
template <typename T, std::size_t N>
inline std::size_t sizeof_array( T (&)[N] ) {
   return N;

// complex: compile time constant
template <typename T, std::size_t N>
char (&static_sizeof_array( T(&)[N] ))[N];   // declared, not defined
#defined SIZEOF_ARRAY( x ) sizeof(static_sizeof_array(x))

In both cases the compiler will detect if you try to pass in a pointer (dynamic array or decayed array):

void f( int array[] ) { // really: void f( int *array )
//   sizeof_array(array);              // compile time error
//   int another[SIZEOF_ARRAY(array)]; // compile time error
int main() {
   int array[] = { 1, 2, 3 };
   std::cout << sizeof_array(array) << std::endl; // prints 3
   int another_array[ SIZEOF_ARRAY(array) ];
   std::cout << sizeof_array(another_array) << std::endl; // 3 again
share|improve this answer
This answer is important. Unlike the C trick, this one will refuse to work on pointers, and you will never end up with 1. Only arrays are accepted. If you have no array to give to the macro, then it means you'll have to keep track of the size of the initial array manually. – Luc Hermitte Feb 16 '10 at 9:59
Very nice! I didn't know you could do this. I didn't even know about the reference-to-array type until this question. Bjarne makes absolutely no mention of it in the bible. – user123456 Feb 16 '10 at 14:16
This are both generic solutions to provide the number of elements in the array, not the size it takes in memory. Using sizeof to calculate the number of elements (sizeof(array)/sizeof(array[0])) is worse than these solutions in that user code can mistakenly pass a pointer (or any other object that has operator[] defined taking an integer) and the code will silently compile and provide false results. The advantage of the sizeof(array)/sizeof(array[0]) over the first variant is that it provides a compile time constant, but that is not an advantage over the second (more complex) variant. – David Rodríguez - dribeas Feb 16 '10 at 15:39
I have seen it in different places, and I use it to avoid having to count elements in initializer lists. Note that it has exactly the same use cases as the sizeof(array)/sizeof(array[0]) in the OP, and if you search in S.O. and other programming forums you will find that there are quite a few questions/answers about array sizes. – David Rodríguez - dribeas Feb 16 '10 at 16:11
I never maintain manually an explicit constant for the size of stack allocated initialized constant arrays. This is not DRY. Instead, I define my array, and use the "second" trick to obtain the exact number of elements. If I need to match this array to another constant (e.g. from an enum), then I use a STATIC_ASSERT (see loki, boost, ...) to check both sizes (the implicit size of the array, and the enum max value) match. – Luc Hermitte Feb 17 '10 at 15:23

If what you have is a "real" array, then the sizeof(x)/sizeof(x[0]) trick works. If, however, what you have is really a pointer (e.g. something returned from a function) then that trick doesn't work -- you'll end up dividing the size of a pointer by the sizeof a pointer. They are pointers to different types, but on a typical system all pointers are the same size, so you'll get one. Even when the pointers are different sizes, the result still won't have anything to do with how many strings you have.

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How are they pointers to different types? Arrays must be homogenous no? What is a "real" array? Does sizeof really return the entire array size if it is used in the same scope in which a stack-allocated array is created? – user123456 Feb 16 '10 at 5:08
So upon further research, sizeof(x) will return the total size of x, given that x is a stack-allocated array that is defined in the same function. But in this case, you already have a compile-time constant used to declare the size of the array, so you only need know the size of the element-type to compute the size of the array. Once the "array" is passed to a function (even if declared with a formal array parameter), the array is said to "decay" into a pointer. Obviously the compiler could not know the size of an actual array passed at run-time. – user123456 Feb 16 '10 at 5:28
You can avoid decay into pointers by using references to arrays. Besides, even if you have access to the array and element size in the current scope, why always use it explicitly and make changes to your code harder? – Georg Fritzsche Feb 16 '10 at 6:11
@gf: how does that make changes to your code harder (given that you are using a const and not a literal)? When using references to arrays, you MUST supply the array size at compile time. Note, to correct my previous comment, you cannot declare a formal array parameter, only a pointer to the element, or a reference to array type. – user123456 Feb 16 '10 at 6:38
@StingRaySc: When you use an unnamed constant you have to replace it everywhere when changing it, same goes for named constants when you change their names. Also, using reference-to-array-parameters for template functions you don't have to supply the array size explicitly. – Georg Fritzsche Feb 16 '10 at 7:05

Better use std::vector<std::string> instead of a raw array. Then you don't have to manually manage the arrays memory and you can use the size() method if you want to know the number of elements.

If you use a dynamically allocated raw array you are expected to keep track of its size yourself, the size cannot be obtained from the array. Best save it in an extra variable.

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Fair advice, but doesn't answer the question. – user123456 Feb 16 '10 at 5:03
Added a paragraph about the size of arrays... – sth Feb 16 '10 at 5:10

In String vector use size() method

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Something to be aware of: text can be represented in different methods. An array of text can also be represented in different methods.

Array of pointers to C-Style strings

A common method is to have an array of pointers to char. The issue is that the size of the array doesn't represent the size of all of the text. Also, the ownership of the data or pointer must also be established, as the text may have to be delete (and can the callee delete the text or does the caller?). Because it is an array, the size of the array must always accompany the array in all parameters (unless the array is always a fixed size).

Array of char - packed text

Another method is to pass an array of char and have the strings contiguous in the array. One string follows the termination char of the previous. With this array, the total size of all of the strings is represented, no wasted space. Again, with arrays, the size of the array must accompany the array when passed around.

Array of std::string

In C++, text can be represented using std::string. In this case, the array represents the quantity of strings (similar to the array of C-Strings above). To get the total size of all the strings, one must sum up the size of each individual string. Since this is an array, the size of the array must be passed also.


During run-time array sizes must accompany the array when the array is passed around. sizeof is only processed at compile time. A simpler structure is std::vector, which handles size and memory allocation dynamically.

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The sizeof(array)/sizeof(element) works for fixed-length-array of fixed-length-arrays (not of pointers). As an array of strings we most often use a (fixed-length-)array of pointers-to-various-(fixed-)length-strings so this trick wouldn't work. sizeof() is used for objects which size is known at compile time. It's not applicable to dynamically allocated data itself.

When an object contains pointers like in the case of an array of strings, sizeof() returns the size of the highest-level (fixed-size) structure. Often it's just the size of a single pointer. It does not include the size of the allocated data pointed to by the pointers. Because that data actually is not part of the main object, it's indeed one or more separate objects (we have aggregation here instead of composition, see http://en.wikipedia.org/wiki/Object_composition).

In C++ using vectors is very convenient for your needs. Other suitable standard containers could be used too. length() and size() methods are synonyms, see http://www.cplusplus.com/reference/string/string/size/)

P.S. Please note that for std::string s object sizeof(s) is a constant independent of the actual (variable) string length returned by s.length(). The actual allocated memory size is returned by s.capacity() and could be greater than length().

Example using vector array:

#include <iostream>
#include <string>
#include <vector>

using namespace std;

int main()
    string s = "01234";
    cout << "s[" << s.length() << "]=\"" << s << "\"" << endl; 
    cout << "sizeof(s)=" << sizeof(s) << " (implementation dependent)" << endl;
    cout << endl;

    s += "56789012345";
    cout << "s[" << s.length() << "]=\"" << s << "\"" << endl; 
    cout << "sizeof(s)=" << sizeof(s) << " (implementation dependent)" << endl;
    cout << endl;


    cout << "vs[" << vs.size() << "]={";
    size_t sz=0;
    for (size_t index=0; index<vs.size(); index++)
        if (index>0)
            cout << ",";
        cout << "\"" << vs[index] << "\":" << vs[index].size();
    cout << "}:" << sz << endl;
    cout << "sizeof(vs)=" << sizeof(vs) << " (implementation dependent)" << endl;

    return 0;


sizeof(s)=8 (implementation dependent)

sizeof(s)=8 (implementation dependent)

sizeof(vs)=24 (implementation dependent)
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template< class T, size_t N >
std::size_t Length(const T(&)[N])
    return N;

std::cout << Length(another_array) << std::endl;
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