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How much does using the dot operator to access some data cost speed-wise? Eg:

struct A{
    public:
       A(): a(0){};
       int a;
};

int main(){
       A obj;
       int b = 0;

       cout << obj.a;  // How much slower is this
       cout << b;      // Than this...?

       return 0;
}

I know I should benchmark, but are there any general understandings here?

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closed as not constructive by David Rodríguez - dribeas, Will Nov 18 '11 at 12:52

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2  
Huh?! Uhm.. you know... there isn't any difference in that code. –  Xeo Nov 18 '11 at 10:31
2  
struct A{ int a = 0; }; is ill formed! –  Prasoon Saurav Nov 18 '11 at 10:33
3  
@user965369: No, not at all. –  Puppy Nov 18 '11 at 10:35
3  
"I know I should benchmark". Well you should. –  R. Martinho Fernandes Nov 18 '11 at 10:35
2  
@user965369: why? c++ isnt like qbasic where every additional character slows the program down. There are libraries like boost.units that have thousands of lines, but exactly zero runtime impact. –  PlasmaHH Nov 18 '11 at 10:39

6 Answers 6

up vote 10 down vote accepted

Let's take a look at dissasembled code:

       cout << obj.a;  // How much slower is this
0041161D  mov         esi,esp 
0041161F  mov         eax,dword ptr [obj] 
00411622  push        eax  
00411623  mov         ecx,dword ptr [__imp_std::cout (41A34Ch)] 
00411629  call        dword ptr [__imp_std::basic_ostream<char,std::char_traits<char> >::operator<< (41A35Ch)] 
0041162F  cmp         esi,esp 
00411631  call        @ILT+430(__RTC_CheckEsp) (4111B3h) 
       cout << b;      // Than this...?
00411636  mov         esi,esp 
00411638  mov         eax,dword ptr [b] 
0041163B  push        eax  
0041163C  mov         ecx,dword ptr [__imp_std::cout (41A34Ch)] 
00411642  call        dword ptr [__imp_std::basic_ostream<char,std::char_traits<char> >::operator<< (41A35Ch)] 
00411648  cmp         esi,esp 
0041164A  call        @ILT+430(__RTC_CheckEsp) (4111B3h) 

This was compiled without optimizations. And even so, they take the same time. With optimizations, the code is shorter, but still remains largely the same:

       cout << obj.a;  // How much slower is this
00401000  mov         ecx,dword ptr [__imp_std::cout (40203Ch)] 
00401006  push        0    
00401008  call        dword ptr [__imp_std::basic_ostream<char,std::char_traits<char> >::operator<< (402038h)] 
       cout << b;      // Than this...?
0040100E  mov         ecx,dword ptr [__imp_std::cout (40203Ch)] 
00401014  push        0    
00401016  call        dword ptr [__imp_std::basic_ostream<char,std::char_traits<char> >::operator<< (402038h)] 

So for your snippet, the performance is identical. Small differences might occur on different compilers, but the overhead will always be negligible or 0.

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1  
Mate that was just what I was looking for thanks a bunch! –  user965369 Nov 18 '11 at 10:51

In this case, probably none as your struct A a and int b should both be optimized away into constants.

More in general, . means an offset has to be computed, but often (part of) that computation may be done at compile-time. This is not something you should be worried about. Also, if you have, say, multiple variables instead of a single struct on the stack, then accessing them might require exactly the same offset computations.

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In your case it doesn't make any difference, because obj.a can be resolved at compile-time and will not produce any overhead at runtime. You might be interested in this paper(pdf) which analyzes the cost of dispatching virtual function calls.

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Basically, none. At all.

This can heavily depend on your circumstances- if obj is a reference to memory which is not currently in cache, for example, large node-based structures, then it can cost you. Else, it's almost zero. The compiler will ensure that in many or even most cases, it is literally zero.

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The only possible run-time overhead when using the member-access-operator is when dealing with references to base classes and calling a virtual function. But that's really the only possibility. Accessing members will never have a run-time overhead through this operator.

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Both obj.a, (&obj)->a and *(int*)(&obj+0) are same. The offset Here 0 is added to the beginning address. To access it. and I as its not virtual its calculation at compile time. so no extra runtime cost associated with it.

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