I came across a #define in which they use __builtin_expect.

The documentation says:

Built-in Function: long __builtin_expect (long exp, long c)

You may use __builtin_expect to provide the compiler with branch prediction information. In general, you should prefer to use actual profile feedback for this (-fprofile-arcs), as programmers are notoriously bad at predicting how their programs actually perform. However, there are applications in which this data is hard to collect.

The return value is the value of exp, which should be an integral expression. The semantics of the built-in are that it is expected that exp == c. For example:

      if (__builtin_expect (x, 0))
        foo ();

would indicate that we do not expect to call foo, since we expect x to be zero.

So why not directly use:

if (x)
    foo ();

instead of the complicated syntax with __builtin_expect?


Imagine the assembly code that would be generated from:

if (__builtin_expect(x, 0)) {
} else {

I guess it should be something like:

  cmp   $x, 0
  jne   _foo
  call  bar
  jmp   after_if
  call  foo

You can see that the instructions are arranged in such an order that the bar case precedes the foo case (as opposed to the C code). This can utilise the CPU pipeline better, since a jump thrashes the already fetched instructions.

Before the jump is executed, the instructions below it (the bar case) are pushed to the pipeline. Since the foo case is unlikely, jumping too is unlikely, hence thrashing the pipeline is unlikely.

  • 1
    Does it really work like that? Why the foo definition can't come first? The order of function definitions are irrelevant, as far as you have a prototype, right? – kingsmasher1 Sep 8 '11 at 11:36
  • 57
    This is not about function definitions. It is about rearranging the machine code in a way that causes a smaller probability for the CPU to fetch instructions that are not going to be executed. – Blagovest Buyukliev Sep 8 '11 at 11:43
  • 4
    Ohh i understand. So you mean since there is a high probability for x = 0 so the bar is given first. And foo, is defined later since it's chances (rather use probability) is less, right? – kingsmasher1 Sep 8 '11 at 11:47
  • 1
    Ahhh..thanks. That's the best explanation. The assembly code really made the trick :) – kingsmasher1 Sep 8 '11 at 11:55
  • 5
    This may also embed hints for the CPU branch predictor, improving pipelining – Hasturkun Sep 8 '11 at 13:48

Let's decompile to see what GCC 4.8 does with it

Blagovest mentioned branch inversion to improve the pipeline, but do current compilers really do it? Let's find out!

Without __builtin_expect

#include "stdio.h"
#include "time.h"

int main() {
    /* Use time to prevent it from being optimized away. */
    int i = !time(NULL);
    if (i)
    return 0;

Compile and decompile with GCC 4.8.2 x86_64 Linux:

gcc -c -O3 -std=gnu11 main.c
objdump -dr main.o


0000000000000000 <main>:
   0:       48 83 ec 08             sub    $0x8,%rsp
   4:       31 ff                   xor    %edi,%edi
   6:       e8 00 00 00 00          callq  b <main+0xb>
                    7: R_X86_64_PC32        time-0x4
   b:       48 85 c0                test   %rax,%rax
   e:       75 0a                   jne    1a <main+0x1a>
  10:       bf 00 00 00 00          mov    $0x0,%edi
                    11: R_X86_64_32 .rodata.str1.1
  15:       e8 00 00 00 00          callq  1a <main+0x1a>
                    16: R_X86_64_PC32       puts-0x4
  1a:       31 c0                   xor    %eax,%eax
  1c:       48 83 c4 08             add    $0x8,%rsp
  20:       c3                      retq

The instruction order in memory was unchanged: first the puts and then retq return.

With __builtin_expect

Now replace if (i) with:

if (__builtin_expect(i, 0))

and we get:

0000000000000000 <main>:
   0:       48 83 ec 08             sub    $0x8,%rsp
   4:       31 ff                   xor    %edi,%edi
   6:       e8 00 00 00 00          callq  b <main+0xb>
                    7: R_X86_64_PC32        time-0x4
   b:       48 85 c0                test   %rax,%rax
   e:       74 07                   je     17 <main+0x17>
  10:       31 c0                   xor    %eax,%eax
  12:       48 83 c4 08             add    $0x8,%rsp
  16:       c3                      retq
  17:       bf 00 00 00 00          mov    $0x0,%edi
                    18: R_X86_64_32 .rodata.str1.1
  1c:       e8 00 00 00 00          callq  21 <main+0x21>
                    1d: R_X86_64_PC32       puts-0x4
  21:       eb ed                   jmp    10 <main+0x10>

The puts was moved to the very end of the function, the retq return!

The new code is basically the same as:

int i = !time(NULL);
if (i)
    goto puts;
return 0;
goto ret;

This optimization was not done with -O0.

But good luck on writing an example that runs faster with __builtin_expect than without, CPUs are really smart those days. My naive attempts are here.

C++20 [[likely]] and [[unlikely]]

C++20 has standardized those C++ built-ins: How to use C++20's likely/unlikely attribute in if-else statement They will likely (a pun!) do the same thing.

  • 1
    Check out libdispatch's dispatch_once function, which uses __builtin_expect for a practical optimization. The slow path runs one-time-ever and exploits __builtin_expect to hint the branch predictor that the fast path should be taken. The fast path runs without using any locks at all! mikeash.com/pyblog/… – Adam Kaplan Sep 20 '17 at 0:50
  • Doesn't appear to make any difference in GCC 9.2: gcc.godbolt.org/z/GzP6cx (actually, already in 8.1) – Ruslan Dec 23 '19 at 8:37

The idea of __builtin_expect is to tell the compiler that you'll usually find that the expression evaluates to c, so that the compiler can optimize for that case.

I'd guess that someone thought they were being clever and that they were speeding things up by doing this.

Unfortunately, unless the situation is very well understood (it's likely that they have done no such thing), it may well have made things worse. The documentation even says:

In general, you should prefer to use actual profile feedback for this (-fprofile-arcs), as programmers are notoriously bad at predicting how their programs actually perform. However, there are applications in which this data is hard to collect.

In general, you shouldn't be using __builtin_expect unless:

  • You have a very real performance issue
  • You've already optimized the algorithms in the system appropriately
  • You've got performance data to back up your assertion that a particular case is the most likely
  • 7
    @Michael: That's not really a description of branch prediction. – Oliver Charlesworth Sep 8 '11 at 11:54
  • 3
    "most programmers are BAD" or anyway no better than the compiler. Any idiot can tell that in a for loop, the continuation condition is likely to be true, but the compiler knows that too so there's no benefit telling it. If for some reason you wrote a loop that would almost always break immediately, and if you can't provide profile data to the compiler for PGO, then maybe the programmer knows something the compiler doesn't. – Steve Jessop Sep 8 '11 at 12:17
  • 13
    In some situations, it doesn't matter which branch is more likely, but rather which branch matters. If the unexpected branch leads to abort(), then likelihood doesn't matter, and the expected branch should be given performance-priority when optimizing. – Neowizard Feb 14 '12 at 12:29
  • 1
    The problem with your claim is that the optimizations the CPU can perform with respect to branch probability is pretty much limited to one: branch prediction, and this optimization happens whether you use __builtin_expect or not. On the other hand, the compiler can perform many optimizations based on the branch probability, such as organizing the code so the hot path is contiguous, moving code unlikely to be optimized further away or reducing its size, taking decisions about which branches to vectorize, better scheduling the hot path, and so on. – BeeOnRope Jan 18 '17 at 21:48
  • 1
    ... without information from the developer, it is blind and chooses a neutral strategy. If the developer is right about the probabilities (and in many cases it is trivial to understand that a branch is usually taken/not taken) - you get these benefits. If you aren't you get some penalty, but it is not somehow much larger than the benefits, and most critically, none of this somehow overrides the CPU branch prediction. – BeeOnRope Jan 18 '17 at 21:50

Well, as it says in the description, the first version adds a predictive element to the construction, telling the compiler that the x == 0 branch is the more likely one - that is, it's the branch that will be taken more often by your program.

With that in mind, the compiler can optimize the conditional so that it requires the least amount of work when the expected condition holds, at the expense of maybe having to do more work in case of the unexpected condition.

Take a look at how conditionals are implemented during the compilation phase, and also in the resulting assembly, to see how one branch may be less work than the other.

However, I would only expect this optimization to have noticeable effect if the conditional in question is part of a tight inner loop that gets called a lot, since the difference in the resulting code is relatively small. And if you optimize it the wrong way round, you may well decrease your performance.

  • But at the end it is all about checking the condition by the compiler, do you mean to say that the compiler always assumes this branch and proceeds, and later if there is not a match then ? What happens? I think there is something more about this branch prediction stuff in compiler design, and how it works. – kingsmasher1 Sep 8 '11 at 11:08
  • 2
    This is truly a micro-optimization. Look up how conditionals are implemented, there's a small bias towards one branch. As a hypothetical example, suppose a conditional becomes a test plus a jump in the assembly. Then the jumping branch is slower than the non-jumping one, so you'd prefer to make the expected branch the non-jumping one. – Kerrek SB Sep 8 '11 at 11:10
  • Thanks, your and Michael i think have similar views but put in different words :-) I understand the exact compiler internals about Test-and-branch are not possible to explain here :) – kingsmasher1 Sep 8 '11 at 11:23
  • They're also very easy to learn about by searching the internet :-) – Kerrek SB Sep 8 '11 at 11:41
  • I better go back to my college book of compiler design - Aho, Ullmann, Sethi :-) – kingsmasher1 Sep 8 '11 at 11:43

I don't see any of the answers addressing the question that I think you were asking, paraphrased:

Is there a more portable way of hinting branch prediction to the compiler.

The title of your question made me think of doing it this way:

if ( !x ) {} else foo();

If the compiler assumes that 'true' is more likely, it could optimize for not calling foo().

The problem here is just that you don't, in general, know what the compiler will assume -- so any code that uses this kind of technique would need to be carefully measured (and possibly monitored over time if the context changes).

  • This may have, in fact, been exactly what the OP had originally intended to type (as indicated by the title) -- but for some reason the use of else was left out of the body of the post. – nobar Jun 2 '15 at 14:41

I test it on Mac according @Blagovest Buyukliev and @Ciro. The assembles look clear and I add comments;

Commands are gcc -c -O3 -std=gnu11 testOpt.c; otool -tVI testOpt.o

When I use -O3 , it looks the same no matter the __builtin_expect(i, 0) exist or not.

(__TEXT,__text) section
0000000000000000    pushq   %rbp     
0000000000000001    movq    %rsp, %rbp    // open function stack
0000000000000004    xorl    %edi, %edi       // set time args 0 (NULL)
0000000000000006    callq   _time      // call time(NULL)
000000000000000b    testq   %rax, %rax   // check time(NULL)  result
000000000000000e    je  0x14           //  jump 0x14 if testq result = 0, namely jump to puts
0000000000000010    xorl    %eax, %eax   //  return 0   ,  return appear first 
0000000000000012    popq    %rbp    //  return 0
0000000000000013    retq                     //  return 0
0000000000000014    leaq    0x9(%rip), %rdi  ## literal pool for: "a"  // puts  part, afterwards
000000000000001b    callq   _puts
0000000000000020    xorl    %eax, %eax
0000000000000022    popq    %rbp
0000000000000023    retq

When compile with -O2 , it looks different with and without __builtin_expect(i, 0)

First without

(__TEXT,__text) section
0000000000000000    pushq   %rbp
0000000000000001    movq    %rsp, %rbp
0000000000000004    xorl    %edi, %edi
0000000000000006    callq   _time
000000000000000b    testq   %rax, %rax
000000000000000e    jne 0x1c       //   jump to 0x1c if not zero, then return
0000000000000010    leaq    0x9(%rip), %rdi ## literal pool for: "a"   //   put part appear first ,  following   jne 0x1c
0000000000000017    callq   _puts
000000000000001c    xorl    %eax, %eax     // return part appear  afterwards
000000000000001e    popq    %rbp
000000000000001f    retq

Now with __builtin_expect(i, 0)

(__TEXT,__text) section
0000000000000000    pushq   %rbp
0000000000000001    movq    %rsp, %rbp
0000000000000004    xorl    %edi, %edi
0000000000000006    callq   _time
000000000000000b    testq   %rax, %rax
000000000000000e    je  0x14   // jump to 0x14 if zero  then put. otherwise return 
0000000000000010    xorl    %eax, %eax   // return appear first 
0000000000000012    popq    %rbp
0000000000000013    retq
0000000000000014    leaq    0x7(%rip), %rdi ## literal pool for: "a"
000000000000001b    callq   _puts
0000000000000020    jmp 0x10

To summarize, __builtin_expect works in the last case.

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