Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

recently, i am looking into assembly codes for #define, const and enum:

C codes(#define):

3   #define pi 3  
4   int main(void)
5   {
6      int a,r=1;             
7      a=2*pi*r;
8      return 0;
9   }

assembly codes(for line 6 and 7 in c codes) generated by GCC:

6   mov $0x1, -0x4(%ebp)
7   mov -0x4(%ebp), %edx
7   mov %edx, %eax
7   add %eax, %eax
7   add %edx, %eax
7   add %eax, %eax
7   mov %eax, -0x8(%ebp)

C codes(enum):

2   int main(void)
3   {
4      int a,r=1;
5      enum{pi=3};
6      a=2*pi*r;
7      return 0;
8   }

assembly codes(for line 4 and 6 in c codes) generated by GCC:

6   mov $0x1, -0x4(%ebp)
7   mov -0x4(%ebp), %edx
7   mov %edx, %eax
7   add %eax, %eax
7   add %edx, %eax
7   add %eax, %eax
7   mov %eax, -0x8(%ebp)

C codes(const):

4   int main(void)
5   {
6      int a,r=1;  
7      const int pi=3;           
8      a=2*pi*r;
9      return 0;
10  }

assembly codes(for line 7 and 8 in c codes) generated by GCC:

6   movl $0x3, -0x8(%ebp)
7   movl $0x3, -0x4(%ebp)
8   mov  -0x4(%ebp), %eax
8   add  %eax, %eax
8   imul -0x8(%ebp), %eax
8   mov  %eax, 0xc(%ebp)

i found that use #define and enum, the assembly codes are the same. The compiler use 3 add instructions to perform multiplication. However, when use const, imul instruction is used. Anyone knows the reason behind that?

share|improve this question
What version of gcc and what optimization flags? – Joe Gauterin Mar 8 '10 at 10:08
gcc (GCC) 4.4.2 20091222 (Red Hat 4.4.2-20) i didn't specify the optimization flag(default). – martin Mar 8 '10 at 10:35
up vote 7 down vote accepted

The difference is that with #define or enum the value 3 doesn't need to exist as an explicit value in the code and so the compiler has decided to use two add instructions rather than allocating space for the constant 3. The add reg,reg instruction is 2 bytes per instruction, so thats 6 bytes of instructions and 0 bytes for constants to multiply by 3, that's smaller code than imul plus a 4 byte constant. Plus the way the add instructions are used, it works out to a pretty literal translation of *2 *3, so this may not be a size optimization, it may be the default compiler output whenever you multiply by 2 or by 3. (add is usually a faster instruction than multiply).

#define and enum don't declare an instance, they only provide a way to give a symbolic name to the value 3, so the compiler has the option of making smaller code.

  mov $0x1, -0x4(%ebp)    ; r=1
  mov -0x4(%ebp), %edx    ; edx = r
  mov %edx, %eax          ; eax = edx
  add %eax, %eax          ; *2
  add %edx, %eax          ; 
  add %eax, %eax          ; *3
  mov %eax, -0x8(%ebp)    ; a = eax

But when you declare const int pi = 3, you tell the compiler to allocate space for an integer value and initialize it with 3. That uses 4 bytes, but the constant is now available to use as an operand for the imul instruction.

 movl $0x3, -0x8(%ebp)     ; pi = 3
 movl $0x3, -0x4(%ebp)     ; r = 3? (typo?)
 mov  -0x4(%ebp), %eax     ; eax = r
 add  %eax, %eax           ; *2
 imul -0x8(%ebp), %eax     ; *pi
 mov  %eax, 0xc(%ebp)      ; a = eax

By the way, this is clearly not optimized code. Because the value a is never used, so if optimization were turned on, the compiler would just execute

xor eax, eax  ; return 0

In all 3 cases.


I tried this with MSVC and in debug mode I get the same output for all 3 cases, MSVC always uses imul by a literal 6. Even in case 3 when it creates the const int = 3 it doesn't actually reference it in the imul.

I don't think this test really tells you anything about const vs define vs enum because this is non-optimized code.

share|improve this answer
+1; Regarding the last paragraph; this is where C++ differs from C in const semantics. C++ will behave as if pi were a literal unless you take its address, so he should I believe get the same code in all three cases for C++ compilation. – Clifford Mar 8 '10 at 10:29
@Clifford: when I turn on full optimizations on my compiler, the program turns into return 0 since a is never used. – John Knoeller Mar 8 '10 at 10:42
but why add can be used, imul can not? i would like to know the reason behind that? like what kind of instructions can be used when using #define & enum, what instructions can not or this depends on compiler i used? if it is true, it depends on the mechanism of compiler? – martin Mar 8 '10 at 10:57
@martin: I wouldn't worry too much about it. The results will be very different if you turn on the optimizer. – John Knoeller Mar 8 '10 at 11:00
Regarding assignment of a being optimised out, declare it volatile and that will prevent that. Regarding Martin's concerns; the whole point of using a compiler is not to have to worry about assembler - let the compiler do its job I say ;-). – Clifford Mar 8 '10 at 13:10

The const keyword merely states that the particular file accessing it isn't allowed to modify it, but other modules may modify or define the value. Therefore, shifts and multiplies aren't allowed, since the value isn't known in advance. The #define'ed values are simply replaced with the literal value after preprocessing, so the compiler can analyze it at compile time. I'm not entirely sure about enums though.

share|improve this answer
Your first statement is true for const function arguments, but not local variables as in this example; by definition an external module or function cannot modify it. – Clifford Mar 8 '10 at 10:25
according to your explanation, when using const, imul instruction can not be used, but why it is used? – martin Mar 8 '10 at 10:33
I should have said shifts and adds, not shifts and multiplies. For instance, to multiply by 13, you can break the 13 down into (x << 3) + (x << 1) + x, but to have a solution for every possible case in an extern int would require the full software multiplication routine, and the hardware to do that is faster and already available. – Arthur Kalliokoski Mar 8 '10 at 11:44
A compiler can see that the value of pi is 3, and can legitimately take advantage of that fact. It's just not required to do so. – Keith Thompson Oct 12 '11 at 21:14

When compiled as C++, identical code is generated to that produced when compiled with C, at least with GCC 4.4.1:

const int pi = 3;


-   0x40132e    <main+22>:      mov    0xc(%esp),%edx
-   0x401332    <main+26>:      mov    %edx,%eax
-   0x401334    <main+28>:      shl    %eax
-   0x401336    <main+30>:      add    %edx,%eax
-   0x401338    <main+32>:      shl    %eax
-   0x40133a    <main+34>:      mov    %eax,0x8(%esp)

The same code is emitted if pi is defined as:

#define pi 3
share|improve this answer
I wonder why the compiler doesn't use lea eax,[eax*2+eax] for the multiply by 3 step. – Skizz Mar 8 '10 at 11:17

In the last case, the compiler treats pi as a variable rather than a literal constant. It may be possible for the compiler to optimise that out with different compiler options.

[edit]Note the entire fragment as written can be optimised out since a is assigned but not used; declare a as a volatile to prevent that occurring.

The semantics of const in C++ differ from that in C in subtle ways, I suspect you'd get a different result with C++ compilation.

share|improve this answer

It appears that you did not actually turn the optimizer on -- even when you thought you did. I compiled this:

int literal(int r)
  return 2*3*r;
int enumeral(int r)
  enum { pi=3 };
  return 2*pi*r;
int constant(int r)
  const int pi=3;
  return 2*pi*r;

... with Apple's gcc 4.2 (rather older than the compiler you used); I can reproduce the assembly you say you got when I use no optimization (the default), but at any higher optimization level, I get identical code for all three, and identical code whether compiled as C or C++:

    movl    4(%esp), %eax
    leal    (%eax,%eax,2), %eax
    addl    %eax, %eax

Based on the comments on John Knoeller's answer, it appears that you did not realize that GCC's command line options are case sensitive. Capital O options (-O1, -O2, -O3, -Os) turn on optimization; lowercase o options (-o whatever) specify the output file. Your -o2 -othing construct silently ignores the -o2 part and writes to thing.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.