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In this small example, c++ forgets size of an array, passed to a constructor. I guess it is something simple, but I cannot see it.

In classes.h, there is this code:

#include <iostream>

class static_class {
 static_class(int array[]) {

class my_class{
 static static_class s;
 static int array[4];


In classes.cpp, there is this code:

#include "classes.h"

int my_class::array[4]={1, 2, 3, 4}; 

static_class my_class::s = static_class(my_class::array);

In main.cpp, there is only simple

#include "classes.h"

int main () {

 return 0;

Now, the desired output (from the constructor of static_class) is 4. But what I get is 1. Why is that?


A lot of answers suggest that sizeof on pointer returns the size of a pointer. That is not true, AFAIK (from - "When the sizeof operator is applied to an array, it yields the total number of bytes in that array, not the size of the pointer represented by the array identifier.")


ok, as I found out, when compiler can see the size, sizeof returns the whole size, but when it decays to a pointer (which is the case here), sizeof actually really returns size of pointer.

share|improve this question
Your first edit makes no sense and contradicts itself. The MSDN quote clearly states that the size of array is returned when sizeof is applied to an array. You are NOT applying sizeof to an array. You are applying it to a pointer, so the MSDN quite is completely irrelevant in your case. You are applying sizeof to a pointer - you are getting the size of a pointer. There's nothing more to it. – AnT May 1 '10 at 1:42
up vote 11 down vote accepted

When declaring a function parameter, the following two are equivalent because an array decays to a pointer when it is passed as an argument:

int array[]
int *array;

So, you end up computing sizeof(int*) / sizeof(int), which happens to be one on your platform because their sizes are the same.

If you need the size of the array in your function, you should pass it as an argument to the function, or use a container that keeps track of the size for you.

share|improve this answer
The thing is, in other cases, sizeof(array) / sizeof(int) actually DOES return size of array. Only in my (fairly crazy, I suppose) example, it doesn't. – Karel Bílek May 1 '10 at 1:08
@Karel: An array decays to a pointer just about any time it is used; when it is the operand of sizeof is one of the times it does not decay to a pointer (there are a handful of other uses, like the unary &, where it does not decay to a pointer). However, an array decays to a pointer when you pass it as an argument to a function, so when you try and use sizeof in the function, all you have is the pointer, so you get the size of the pointer. – James McNellis May 1 '10 at 1:12
OK, that is probably the thing that got me confused... that sometimes, sizeof treats it "specially" as an array, but sometimes just as an ordinary pointer. Thanks – Karel Bílek May 1 '10 at 1:16
the point is - there is no runtime info attached to an array saying how big its is, and anyway sizeof is resolved at compile time. THis should tell you that it will fail. You can call static_class() with any sized array; the compiler cannot possibly know; all the compiler sees is that there will be a pointer to the start of an array of ints passed in – pm100 May 1 '10 at 1:22
@Karel: Really, sizeof doesn't treat anything specially. When you have the array, it gives you the size of the array; when you only have a pointer to the first element of the array, it gives you the size of that first element. Basically, you just have to remember that when the array gets converted to a pointer to its first element, you lose all information about the size of the array, because all you have is a pointer. – James McNellis May 1 '10 at 1:22

There's also a template option, something like this?

class static_class
   template<int I>
   static_class(int (&array)[I])
      std::cout << I << std::endl;

I think that'd work, anyway. sizeof(array)/sizeof(array[0]) only works in scopes where the array's definition is actually visible. In other words, your static_class constructor couldn't "see" the size of the array, all it knew was that it was getting an array of some (any) size. You could pass an array of 100 elements or four, and the function itself would get no information.

In my example, on the other hand, the template will cause one version of the function to be created for each array size that you pass in. This may or may not be desirable. Generally speaking, it's best to keep the array size somewhere handy, like:

class my_class
   static static_class s;
   static const int array_size = 4;
   static int array[array_size];

Then you can pass my_class::array_size around and not have to be worried about what the compiler may or may not have visible regarding array attributes.

share|improve this answer

In C, and therefore I presume in C++, any array that's passed through as a parameter is turned into a simple pointer type, which loses the size information. Since your static_class constructor gets the array from a parameter, it loses its array quality.

share|improve this answer

The basic problem that the other answers hint at is that arrays are not first class types in C/C++. In particular, you cannot declare functions or function types that take arrays as arguments. Now, for historical reasons lost in the depth of time, instead of just saying that declaring a function argument that is an array is an error, it was decided that the compiler should silently turn the array declaration into a pointer declaration. This has lead to no end of confusion with people declaring arrays as arguments and unexpectedly getting pointers instead.

share|improve this answer

becuase array is a pointer at the point where you do sizeof(array). The array never knew its size (see what happens if you try to access an element beyond its end). The compiler knew at the point where it was defined; that all

Anyway the solution you want is std::vector

share|improve this answer

You'd be surprised, but in C++, arrays are just pointers, nothing more. The array size is not stored anywhere, and certainly it not possible to pass function arguments of variable size.

share|improve this answer
Arrays are not pointers. This myth has been debunked too many times to do it here again. It is described in good detail in any C/C++ FAQ. – AnT May 1 '10 at 1:49
Yes, you're right. I stand corrected. – Fyodor Soikin May 1 '10 at 4:40

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