Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

[Edit: It seems this is an issue on gcc versions prior to 4.4, I got confused because of a gcc bugzilla entry reporting it for 4.5 (latest). Sorry, I should've tested with more recent versions. Still, the problem is somewhat valid as most people don't run gcc 4.4+.]

Is it possible to tell the compiler the variable used in a switch fits within the provided case statements? In particular if it's a small range and there's a jump table generated.

extern int a;
main()
{
        switch (a & 0x7) {   // 0x7  == 111  values are 0-7
        case 0: f0(); break;
        case 1: f1(); break;
        case 2: f2(); break;
        case 3: f3(); break;
        case 4: f4(); break;
        case 5: f5(); break;
        case 6: f6(); break;
        case 7: f7(); break;
        }
}

I tried xor'ing to low bits (as the example), using enums, using gcc_unreachable() to no avail. The generated code always checks if the variable is inside the range, adding a pointless branch conditional and moving away the jump table calculation code.

Note: this is in the innermost loop of a decoder, performance matters significantly.

It seems I'm not the only one.

There is no way to tell gcc that the default branch is never taken, although it will omit the default branch if it can prove that the value is never out of range based on earlier conditional checks.

So, how do you help gcc prove the variable fits and there's no default branch in the example above? (Without adding a conditional branch, of course.)

EDIT1: This was on OS X 10.6 Snow Leopard with GCC 4.2 (default from Xcode.) It didn't happen with GCC 4.4/4.3 in linux (reported by Nathon and Jens Gustedt.)

EDIT2: The functions in the example are there for readability, think those are inlined or just statements. Making a function call on x86 is expensive.

Also the example, as mentioned in the note, belongs inside a loop on data (big data.)

The generated code with gcc 4.2/OS X is:

[...]
andl    $7, %eax
cmpl    $7, %eax
ja  L11
mov %eax, %eax
leaq    L20(%rip), %rdx
movslq  (%rdx,%rax,4),%rax
addq    %rdx, %rax
jmp *%rax
.align 2,0x90
L20:
.long   L12-L20
.long   L13-L20
.long   L14-L20
.long   L15-L20
.long   L16-L20
.long   L17-L20
.long   L18-L20
.long   L19-L20
L19:
[...]

The problem lies on cmp $7, %eax / ja L11.

EDIT3:

OK, I'm going with the ugly solution and adding a special case for gcc versions below 4.4 using a different version without a switch and using goto and gcc's &&label extensions.

static void *jtb[] = { &&c_1, &&c_2, &&c_3, &&c_4, &&c_5, &&c_6, &&c_7, &&c_8 };
[...]
goto *jtb[a & 0x7];
[...]
while(0) {
c_1:
// something
break;
c_2:
// something
break;
[...]
}

Note the array of labels is static so it's not computed every call.

Thanks everyone for the great help! And sorry to those with valid answers who didn't get the mark :(

share|improve this question

6 Answers 6

up vote 3 down vote accepted

I tried compiling something simple and comparable with -O5 and -fno-inline (my f0-f7 functions were trivial) and it generated this:


 8048420:   55                      push   %ebp ;; function preamble
 8048421:   89 e5                   mov    %esp,%ebp ;; Yeah, yeah, it's a function.
 8048423:   83 ec 04                sub    $0x4,%esp ;; do stuff with the stack
 8048426:   8b 45 08                mov    0x8(%ebp),%eax ;; x86 sucks, we get it
 8048429:   83 e0 07                and    $0x7,%eax ;; Do the (a & 0x7)
 804842c:   ff 24 85 a0 85 04 08    jmp    *0x80485a0(,%eax,4) ;; Jump table!
 8048433:   90                      nop
 8048434:   8d 74 26 00             lea    0x0(%esi,%eiz,1),%esi
 8048438:   8d 45 08                lea    0x8(%ebp),%eax
 804843b:   89 04 24                mov    %eax,(%esp)
 804843e:   e8 bd ff ff ff          call   8048400 
 8048443:   8b 45 08                mov    0x8(%ebp),%eax
 8048446:   c9                      leave  

Did you try playing with optimization levels?

share|improve this answer
    
Yeah, exactly the same code for -O3 and -O5, as stated on another comment I'm using gcc 4.2 but the bugzilla entry says it happens with gcc 4.5, too. –  alecco Jul 14 '10 at 20:50
1  
Hmm, mine is gcc (Debian 4.4.4-6) 4.4.4. –  nmichaels Jul 14 '10 at 20:53
4  
There is no -O5 (gcc.gnu.org/onlinedocs/gcc-4.4.4/gcc/Optimize-Options.html), so not really surprising that it does the same as -O3 ;-) –  Peter Jul 14 '10 at 21:10
    
Just tried it on Gentoo with 4.5 and had the same result as you! Argh. Still, this is for an open source project so can't demand users have the latest gcc version. Now I'm torn on who to assign the answer as correct :-/ –  alecco Jul 14 '10 at 21:22

I didn't try, but I'm not sure that gcc_unreachable does the same thing as __builtin_unreachable. Googling the two, gcc_unreachable appears to be designed as a as an assertion tool for development of GCC itself, perhaps with a branch prediction hint included, whereas __builtin_unreachable makes the program instantly undefined — which sounds like deleting the basic block, which is what you want.

http://gcc.gnu.org/onlinedocs/gcc/Other-Builtins.html#index-g_t_005f_005fbuiltin_005funreachable-3075

share|improve this answer
    
Yeah, here's proof that gcc_unreachable is a function and not the abstract representation of void code: old.nabble.com/… –  Potatoswatter Oct 2 '10 at 5:48

Have you tried declaring the switch variable as a bitfield?

struct Container {
  uint16_t a:3;
  uint16_t unused:13;
};

struct Container cont;

cont.a = 5;  /* assign some value */
switch( cont.a ) {
...
}

Hope this works!

share|improve this answer
    
Interesting. But no luck, it still compares to 7 and "ja L5". I'm using gcc 4.2 BTW (Forgot to mention!) But the guy on the gcc bugzilla reported it happens in gcc 4.5 for him (though it might be non-x86.) –  alecco Jul 14 '10 at 20:45

This question is certainly interesting from the standpoint of a missed compiler optimization that is seemingly obvious to us, and I did spend considerable time trying to come up with a straightforward solution, largely out of personal curiousity.

That said, I have to admit I am highly skeptical that this additional instruction will ever result in a measurable performance difference in practice, especially on a new mac. If you have any significant amount of data, you'll be I/O bound, and a single instruction will never be your bottleneck. If you have a tiny amount of data, then you'll need to perform a lot lot lot of calculations repeatedly before a single instruction will become a bottleneck.

Would you post some code to show that there really is a performance difference? Or describe the code and data your working with?

share|improve this answer
    
Yes. If the branch is unlikely the predictor will mark it. But it will consume 2 cycles. I'm working on a high performance compression algorithm and implementation. One of the problems with compression is the unpredictability due to the nature of compression. Is the next block on decompression a literal or a match? (picking source) How long is it? Does it cross a cache-line or page boundary? (serious performance penalty.) This loop will be processed for every "atom" on decompression. Performance matters: Google has their super-secret compression algorithm, Zippy. (dbs, comms, everything) –  alecco Jul 15 '10 at 15:57
    
When originally posted I thought the bug/issue was broken in recent versions of gcc (because of the gcc bugzilla entry for 4.5 linked.) My bad. @Jens Gustedt above confirmed this. I tested then 4.4/4.5 on a different OS. I'll edit the question to reflect this on top. Thanks! (and have an upvote for valid critical thinking!) –  alecco Jul 15 '10 at 16:10
1  
I agree that performance matters. I'm asking whether that cmpl instruction has a measurable performance effect, and if so, under what real circumstances (because I can't think of any.) It's the difference between this being a question of "how do I hack a specific version of gcc just for the sake of curiousity" and a question about a legitimate code optimization. –  John Jul 15 '10 at 21:24
    
Yeah. At the moment the test data is random chunks of Wikipedia text and still need to finish other parts of the code. But this is the innermost most important decoding loop, for just 1MB of typical plaintext it will be run ~180k times (from tests.) –  alecco Jul 15 '10 at 21:50

Perhaps you could use an array of function pointers instead of a switch ?

#include <stdio.h>

typedef void (*func)(void);

static void f0(void) { printf("%s\n", __FUNCTION__); }
static void f1(void) { printf("%s\n", __FUNCTION__); }
static void f2(void) { printf("%s\n", __FUNCTION__); }
static void f3(void) { printf("%s\n", __FUNCTION__); }
static void f4(void) { printf("%s\n", __FUNCTION__); }
static void f5(void) { printf("%s\n", __FUNCTION__); }
static void f6(void) { printf("%s\n", __FUNCTION__); }
static void f7(void) { printf("%s\n", __FUNCTION__); }

int main(void)
{
    const func f[8] = { f0, f1, f2, f3, f4, f5, f6, f7 };
    int i;

    for (i = 0; i < 8; ++i)
    {
        f[i]();
    }
    return 0;
}
share|improve this answer
1  
Cool, but wouldn't this add a function call overhead? But yes, you answer the question as it doesn't have a branch. (Ouch, there are like 4 valid [answers] now, don't know [wich one] to [mark as accepted]) Edit: I tried forcing inline with no luck. The alternative is a goto and using gcc's &&label (something I tried yesterday but didn't mention as I didn't want to force GCC dependencies in the code.) –  alecco Jul 14 '10 at 21:41
    
(Sorry to dead post…) Function call overhead is a given as long as you're doing a true function call. That should be eliminated if you turn it into a tail call by having fN return int. –  Potatoswatter Sep 30 '10 at 4:39

Perhaps just use a default label for the fist or last case?

share|improve this answer
    
I forgot to mention I tried this, too. This just makes the conditional jump include the first or last cases, still branching. It seems like gcc can't tell the value is in the range 0-7. –  alecco Jul 14 '10 at 20:48
1  
@aleccolocco: too bad. You didn't tell what version of gcc you have, maybe you just have a bad one? I suppose you also tried all optimizing flags? –  Jens Gustedt Jul 14 '10 at 21:02
1  
@aleccolocco: sorry only read the description of your compiler after my last comment. I experimented on my machine (64 bit, gcc 4.4.3) I get a perfect jump table, and the only warning is the missing return for main. I'll also try on my phone an ARM with gcc 4.2 –  Jens Gustedt Jul 14 '10 at 21:11
1  
On ARM with gcc 4.2 it produces a jump table too, but isn't able to optimize out the bound check, which 4.4.3 does. The two instructions, and and cmp are really succeeding each other, so this is not very much optimized. BTW, I observed that the generated code is quite different when I add a return statement after the switch. –  Jens Gustedt Jul 14 '10 at 21:27
1  
gcc 4.4.3 on i686: jump table, no bound check. gcc 4.0.1 on i686: jump table, bound check. So my guess is that the version makes the difference, but unfortunately I don't have my hands on a machine with 4.5 to do a test. –  Jens Gustedt Jul 14 '10 at 21:41

Your Answer

 
discard

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.