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In the following:

#include <string.h>

struct cpuidOut
   long a ;
   long b ;
   long c ;
   long d ;
} ;

void callcpuid( cpuidOut * p, long a )
   memset( p, 0xFF, sizeof(*p) ) ;
   p->a = a ;

   __asm__ ( "cpuid"
             : "+a"(p->a), "=b"(p->b), "=c"(p->c), "=d"(p->d)  // output
             :                                                 // no (only) inputs
             : "a", "b", "c", "d"                              // clobbered registers
           ) ;

I get a compile error:

t.C:22: error: unknown register name 'd' in 'asm'
t.C:22: error: unknown register name 'c' in 'asm'
t.C:22: error: unknown register name 'b' in 'asm'
t.C:22: error: unknown register name 'a' in 'asm'

(same sort of error from either g++ or clang++)

This suprises me since I see a, b, c, d listed in the i386 clobbers in the gcc documentation

I can fix the clobber constraints by being explicit:

"%rax", "%rbx", "%rcx", "%rdx"                  // clobbered registers

but I'm suprised I have to do so? I only need this to work on x86_64, but I thought the "a", "b", "c", "d" style constraints would be nicer in case the code is later needed on i386 too.

EDIT: I'd initially posted the wrong asm after tweaking it a couple of times trying to get it to work, and getting mixed up along the way. The asm above is consistent with my initial question, however, causes a compile error with the compiler unable to schedule the A register. This seems to work instead:

void callcpuid( cpuidOut * p, long a, long b )
   __asm__ ( "cpuid"
             : "=a"(p->a), "=b"(p->b), "=c"(p->c), "=d"(p->d)  // output
             : "0"(a), "1"(b)                                  // inputs
           ) ;

but notice that it avoids the requirement for any clobber constraints at all, since all the clobbers are outputs. That's probably the right way to do it, although I'm still suprised after reading the gcc docs that I can't use the generic reg names "a", "b", "c", "d" in the clobber constraints, instead having to use "%eax", "%rax", ...

share|improve this question
Depending on the use of PIC and the memory model, you might need to save EBX/RBX because, according to the ABI specification, the caller owns it. The "=b"(p->b) destroys EBX/RBX. – jww Aug 21 '15 at 14:57
If I list rbx as an output, won't the compiler have to do a spill for -fpic itself (as opposed to me having to do it explicitly)? – Peeter Joot Aug 21 '15 at 19:06
up vote 1 down vote accepted

This suprises me since I see a, b, c, d listed in the i386 clobbers in the gcc documentation

The clobbers are not constraints.

Constraints are used when you tell GCC to allocate registers for insn operands, the constraints define the acceptable register class from which to draw registers.

The clobbers, on the other hand, tell GCC about registers, which are modified by the insns, in the cases where it's not evident from the input/output constraints, for example an insn, which modifies a fixed register, which is not one of its operands or when you use hardcoded register names in the inline assembly.

This is needed, so before execution of the inline asm, GCC can stash away values, that it happens to keep in the clobbered registers.

PS. For input-output operands, you can used the "+" modifier:

void callcpuid( cpuidOut * p, long a, long b )
   __asm__ ( "cpuid" : "+a"(p->a), "+b"(p->b), "=c"(p->c), "=d"(p->d)) ;

PS. 32-bit code generated:

movl    (%esi), %eax  ; load p->a
movl    4(%esi), %ebx ; load p->b
movl    %ebx, 4(%esi)  ; write back into p->b
movl    (%esp), %ebx   
movl    %eax, (%esi)   ; write back into p->a
movl    %ecx, 8(%esi)  ; write p->c
movl    %edx, 12(%esi) ; write p->d

64-bit code generated:

movq    (%rdi), %rax   ; load p->a
movq    8(%rdi), %rbx  ; load p->b
movq    %rbx, 8(%rdi)  ; write back p->b
movq    %rax, (%rdi)   ; write back p->a
movq    %rcx, 16(%rdi) ; write p->c
movq    %rdx, 24(%rdi) ; write p->d
share|improve this answer
Thanks. I always called them clobber constraints, so it looks like I confused myself just by nomenclature. ps. Your sample with + doesn't do the job since it doesn't get the a, and b parameters into p->a, p->b respectively. – Peeter Joot Nov 24 '12 at 20:11
Oh, it does work, I've used it many times and in fact I checked it on this example as well. Check edit in a second. – chill Nov 24 '12 at 20:17
All I'm saying is that in my sample the two parameters a and b were inputs. You have a different interface with a pair of unused parameters. If you removed those two parameters and required that the values be put into the structure instead, your code would do the job (which isn't a bad way to do it). – Peeter Joot Nov 24 '12 at 20:33
Oh, right, overlooked it. – chill Nov 24 '12 at 20:56
Be careful with that call to callcpuid. Depending on the memory model and the use of PIC, EBX/RBX may need to be preserved. Then, when you try to preserve EBX/RBX, you run into goodness like What ensures reads/writes of operands occurs at desired times with extended ASM? – jww Aug 21 '15 at 5:19

If you can wait for the next GCC 4.8 release, or if you can use the latest snapshot of GCC (i.e. compile the trunk from svn source), consider using the new builtins __builtin_cpu_is and __builtin_cpu_supports;

otherwise, do what you suggest, e.g. be explicit with clobber constraints.

NB: the link you refer to is also for future GCC 4.8, not for 4.7 or earlier

share|improve this answer
Good suggestion. My final target compiler is actually clang in this case (which implements gcc style asm) ... was just test compiling the code in question. – Peeter Joot Nov 24 '12 at 15:29

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