3

The sizeof() operator in C gives the size of its operand at compile time. It does not evaluate its operand. For example,

int ar1[10];
sizeof(ar1) // output 40=10*4
sizeof(ar1[-1]) // output 4
int ar2[ sizeof(ar1) ]; // generate an array of 40 ints.

When it came to C++ template class, I find some strange result.

template<typename T>
struct S{
    T a;
};

sizeof( S<int> )       // output 4
sizeof( S<bool> )      // output 1
sizeof( vector<int> )  // output 24
sizeof( vector<char> ) // output 24
sizeof( vector<bool> ) // output 40

I guess the sizeof on vector or other STL container depends on specific environment.

Question 1. How is sizeof implemented in C/C++? It cannot be a run-time function. Is it a macro? (what I learned in a online tutorial vedio). If it is a Macro, what the #define of it looks like? When the sizeof() is executed?

Question 2. If I add a member method void f(){} to the definition of struct S. The sizeof(S<int>) is still 4. Shouldn't the size of the struct increase?

Question 3. STL containers are template classes. Take vector for example, it has 12 member attributes/types and many member methods? It is easy to explain the output of sizeof( S<int> ). But I find it hard to explain the output of sizeof( vector<int> ). Template class should be instantiated at compile-time and the compiler should have total knowledge of the size of the class, i.e. vector<int>. So should sizeof() operator know.

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  • 2
    You asked too many questions at once. Question 2 is answered here: stackoverflow.com/questions/8058213/…
    – Slava
    Jul 24, 2014 at 19:14
  • sizeof is a keyword in C/C++. I haven't see a name of Macro become a keyword. Maybe sizeof is not a macro.
    – Peng Zhang
    Jul 24, 2014 at 19:15
  • @Slava Thanks. Honestly, I will not use sizeof in those strange way in my code. Just feel too ignorant about the behavior of sizeof.
    – Peng Zhang
    Jul 24, 2014 at 19:16
  • Which video said sizeof was a macro?
    – chris
    Jul 24, 2014 at 19:33
  • @chris It is explained in a chinese vedio at edu.51cto.com/lesson/id-30061.html
    – Peng Zhang
    Jul 24, 2014 at 19:38

2 Answers 2

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As per Question 1: sizeof is implemented and evaluated by the compiler. It is not a macro, and it always provides a compile-time result. Conceptually, you can imagine that the compiler replaces every sizeof with a number.

As per Question 2: sizeof counts the amount of storage that one instance of S occupies. A method does not take per-instance storage, only fields do (since they exist once per instance). A method does, however, occupy static storage somewhere to hold the machine code for the function.

As per Question 3: For sizeof(vector<int>) the compiler computes the size of the vector<int>, which it instantiates in order to do so. If you are confused because a vector can be of variable size: that is true, but the extra storage is allocate from the heap and thus not reflected in the result of sizeof applied to a vector.

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  • Q2 unless it is a first virtual function which will add some storage, this q already answered here stackoverflow.com/questions/8058213/…
    – Slava
    Jul 24, 2014 at 19:18
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    std::vector<bool> is an explicitly called out specialization which may use more space than a normal vector.
    – Mark B
    Jul 24, 2014 at 19:26
  • 1
    @PengZhang vector<bool> it's a really weird data structure, it's basically one of the few exceptions to the rules inside the standard C++ library; just skip it. Jul 24, 2014 at 19:28
  • 1
    @PengZhang, Those are type aliases. They don't take up per-instance space.
    – chris
    Jul 24, 2014 at 19:46
  • 1
    @PengZhang, typedef. #define can't do that (reliably). This extends far beyond the C++ STL. The point is so you can say vector<int>::size_type to get the type that, e.g., size() returns. The actual number of data members is up to the implementation.
    – chris
    Jul 24, 2014 at 19:55
5
  1. sizeof is not a macro. It is a built-in operator and yields a constant expression, so you can imagine that the compiler just replaces it at compile-time with a literal whose value is the size of the object or class operand.

  2. Functions don't take up space inside objects. The code for the function is not stored inside the object.

  3. The size of a container such as std::vector<int> is the amount of memory taken up by the vector's members, plus some implementation-defined padding. It does not include any memory that the vector "owns" by holding pointers. (Note that elements of the vector are not members---when I say members I mean the members declared in the definition of the std::vector class.) So it's independent of how many elements are inside the vector.

3
  • Functions don't take up space inside objects. The code for the function is not stored inside the object - Well, i'm just curious. An object must still hold a pointer to its function, i believe, and if it's true then this pointer takes few bytes of memory, doesn't it? Jul 24, 2014 at 19:24
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    @AndreyChernukha No. If the function is not virtual, then the compiler can determine its address at compile time; calling the member function doesn't require examining the object. If the function is virtual, there's generally only a single pointer added to the object, which points to a table stored somewhere else that gives the addresses of all virtual functions for the object's class.
    – Brian Bi
    Jul 24, 2014 at 19:26
  • Thanks a lot for a good answer. It is hard to choose the other one.
    – Peng Zhang
    Jul 24, 2014 at 19:54

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