I wrote this simple C program:

int main() {
    int i;
    int count = 0;
    for(i = 0; i < 2000000000; i++){
        count = count + 1;

I wanted to see how the gcc compiler optimizes this loop (clearly add 1 2000000000 times should be "add 2000000000 one time"). So:

gcc test.c and then time on a.out gives:

real 0m7.717s  
user 0m7.710s  
sys 0m0.000s  

$ gcc -O2 test.c and then time ona.out` gives:

real 0m0.003s  
user 0m0.000s  
sys 0m0.000s  

Then I disassembled both with gcc -S. First one seems quite clear:

    .file "test.c"  
.globl main
    .type   main, @function  
    pushq   %rbp
    .cfi_def_cfa_offset 16
    movq    %rsp, %rbp
    .cfi_offset 6, -16
    .cfi_def_cfa_register 6
    movl    $0, -8(%rbp)
    movl    $0, -4(%rbp)
    jmp .L2
    addl    $1, -8(%rbp)
    addl    $1, -4(%rbp)
    cmpl    $1999999999, -4(%rbp)
    jle .L3
    .cfi_def_cfa 7, 8
    .size   main, .-main
    .ident  "GCC: (Ubuntu/Linaro 4.5.2-8ubuntu4) 4.5.2"
    .section    .note.GNU-stack,"",@progbits

L3 adds, L2 compare -4(%rbp) with 1999999999 and loops to L3 if i < 2000000000.

Now the optimized one:

    .file "test.c"  
    .p2align 4,,15
.globl main
    .type main, @function
    .size main, .-main
    .ident "GCC: (Ubuntu/Linaro 4.5.2-8ubuntu4) 4.5.2"
    .section .note.GNU-stack,"",@progbits

I can't understand at all what's going on there! I've got little knowledge of assembly, but I expected something like

addl $2000000000, -8(%rbp)

I even tried with gcc -c -g -Wa,-a,-ad -O2 test.c to see the C code together with the assembly it was converted to, but the result was no more clear that the previous one.

Can someone briefly explain:

  1. The gcc -S -O2 output.
  2. If the loop is optimized as I expected (one sum instead of many sums)?
  • 19
    Nice question btw, and welcome to Stackoverflow! This, is a fine example of an excellent first question to ask. :) – Mysticial Jan 12 '12 at 20:49

The compiler is even smarter than that. :)

In fact, it realizes that you aren't using the result of the loop. So it took out the entire loop completely!

This is called Dead Code Elimination.

A better test is to print the result:

#include <stdio.h>
int main(void) {
    int i; int count = 0;
    for(i = 0; i < 2000000000; i++){
        count = count + 1;

    //  Print result to prevent Dead Code Elimination
    printf("%d\n", count);

EDIT : I've added the required #include <stdio.h>; the MSVC assembly listing corresponds to a version without the #include, but it should be the same.

I don't have GCC in front of me at the moment, since I'm booted into Windows. But here's the disassembly of the version with the printf() on MSVC:

EDIT : I had the wrong assembly output. Here's the correct one.

; 57   : int main(){

    sub rsp, 40                 ; 00000028H

; 58   : 
; 59   : 
; 60   :     int i; int count = 0;
; 61   :     for(i = 0; i < 2000000000; i++){
; 62   :         count = count + 1;
; 63   :     }
; 64   : 
; 65   :     //  Print result to prevent Dead Code Elimination
; 66   :     printf("%d\n",count);

    lea rcx, OFFSET FLAT:??_C@_03PMGGPEJJ@?$CFd?6?$AA@
    mov edx, 2000000000             ; 77359400H
    call    QWORD PTR __imp_printf

; 67   : 
; 68   : 
; 69   : 
; 70   :
; 71   :     return 0;

    xor eax, eax

; 72   : }

    add rsp, 40                 ; 00000028H
    ret 0

So yes, Visual Studio does this optimization. I'd assume GCC probably does too.

And yes, GCC performs a similar optimization. Here's an assembly listing for the same program with gcc -S -O2 test.c (gcc 4.5.2, Ubuntu 11.10, x86):

        .file   "test.c"
        .section        .rodata.str1.1,"aMS",@progbits,1
        .string "%d\n"
        .p2align 4,,15
.globl main
        .type   main, @function
        pushl   %ebp
        movl    %esp, %ebp
        andl    $-16, %esp
        subl    $16, %esp
        movl    $2000000000, 8(%esp)
        movl    $.LC0, 4(%esp)
        movl    $1, (%esp)
        call    __printf_chk
        .size   main, .-main
        .ident  "GCC: (Ubuntu/Linaro 4.5.2-8ubuntu4) 4.5.2"
        .section        .note.GNU-stack,"",@progbits
  • 2
    Well, I feel really dumb right now. Didn't think (eew.. didn't know) about Dead code elimination. I tried with printf() and gcc, and it produces quite the same optimized code. Thank you for you answer! – Haile Jan 12 '12 at 20:45
  • 11
    Don't feel dumb. This kind of thing is not obvious at all if you're just getting into micro-benchmarking. It's just part of the learning process. – Mysticial Jan 12 '12 at 20:46
  • It would be interesting to know how the compiler makes this kind of decisions. What if that loop was really needed for some reason? – kechap Jan 12 '12 at 21:39
  • 4
    @marcushatchenson That's a pretty big compiler topic. The basic idea is that the compiler generates a Dependency Graph, which can then be used to prove/disprove whether certain computations are ever needed. Things that are proven to not be needed are then eliminated. – Mysticial Jan 12 '12 at 21:51
  • 10
    @marcushatchenson - the only effect the loop has is to increment count, which is a local variable. The C spec states that nothing outside the function is aware of the local, and the compiler knows that the function doesn't do anything with the result. By the rules of the spec, there's no possible effect on the program if count is not computed, so the optimizer is allowed to junk it. If you declare count as a global, on the other hand, the compiler has to treat it differently. – Russell Borogove Jan 13 '12 at 0:53

Compilers have a few tools at their disposal to make code more efficient or more "efficient":

  1. If the result of a computation is never used, the code that performs the computation can be omitted (if the computation acted upon volatile values, those values must still be read but the results of the read may be ignored). If the results of the computations that fed it weren't used, the code that performs those can be omitted as well. If such omission makes the code for both paths on a conditional branch identical, the condition may be regarded as unused and omitted. This will have no effect on the behaviors (other than execution time) of any program that doesn't make out-of-bounds memory accesses or invoke what Annex L would call "Critical Undefined Behaviors".

  2. If the compiler determines that the machine code that computes a value can only produce results in a certain range, it may omit any conditional tests whose outcome could be predicted on that basis. As above, this will not affect behaviors other than execution time unless code invokes "Critical Undefined Behaviors".

  3. If the compiler determines that certain inputs would invoke any form of Undefined Behavior with the code as written, the Standard would allow the compiler to omit any code which would only be relevant when such inputs are received, even if the natural behavior of the execution platform given such inputs would have been benign and the compiler's rewrite would make it dangerous.

Good compilers do #1 and #2. For some reason, however, #3 has become fashionable.

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