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I'm trying to do some Code Optimization to Eliminate Branches, the original c code is

if( a < b ) 
   k = (k<<1) + 1;
   k = (k<<1)

I intend to replace it with assembly code like below

mov a, %rax 
mov b, %rbx
mov k, %rcx
xor %rdx %rdx
shl 1, %rcx
cmp %rax, %rax
setb %rdx
add %rdx,%rcx
mov %rcx, k 

so I write c inline assembly code like blow,

#define next(a, b, k)\
 __asm__("shl $0x1, %0; \
         xor %%rbx, %%rbx; \
         cmp %1, %2; \
         setb %%rbx; \
         addl  %%rbx,%0;":"+c"(k) :"g"(a),"g"(b))

when I compile the code below i got error of

operand type mismatch for add
operand type mismatch for `setb

so how can I fix it??

share|improve this question
Unless your compiler is really bad you should be able to eliminate branches without resorting to asm, e.g. k = (k << 1) + (a < b); should generate branchless code. –  Paul R Dec 24 '12 at 15:30
As much as writing asm for this code is fundamentally wrong, there still IS a valid question here: how to fix the asm so that it compiles and does what's intended. –  R.. Dec 24 '12 at 15:59
@R.. That's easy to answer. Compile the C code and study the output from the compiler. –  David Heffernan Dec 24 '12 at 16:21
@DavidHeffernan: Actually that won't help. OP's problem seems to have been invalid constraints or operands. Since inline asm is quite different from standalone asm, just looking at generated asm will not solve the inline asm problem. –  R.. Dec 24 '12 at 16:35

3 Answers 3

up vote 2 down vote accepted

Here are the mistakes in your code:

  1. Error: operand type mismatch for 'cmp' -- One of CMP's operands must be a register. You're probably generating code that's trying to compare two immediates. Change the second operand's constraint from "g" to "r". (See GCC Manual - Extended Asm - Simple Constraints)
  2. Error: operand type mismatch for 'setb' -- SETB only takes 8 bit operands, i.e. setb %bl works while setb %rbx doesn't.
  3. The C expression T = (A < B) should translate to cmp B,A; setb T in AT&T x86 assembler syntax. You had the two operands to CMP in the wrong order. Remember that CMP works like SUB.

Once you realize the first two error messages are produced by the assembler, it follows that the trick to debugging them is to look at the assembler code generated by gcc. Try gcc $CFLAGS -S t.c and compare the problematic lines in t.s with an x86 opcode reference. Focus on the allowed operand codes for each instruction and you'll quickly see the problems.

In the fixed source code posted below, I assume your operands are unsigned since you're using SETB instead of SETL. I switched from using RBX to RCX to hold the temporary value because RCX is a call clobbered register in the ABI and used the "=&c" constraint to mark it as an earlyclobber operand since RCX is cleared before the inputs a and b are read:

#include <stdio.h>
#include <stdint.h>
#include <inttypes.h>

static uint64_t next(uint64_t a, uint64_t b, uint64_t k)
    uint64_t tmp;
    __asm__("shl $0x1, %[k];"
        "xor %%rcx, %%rcx;"
        "cmp %[b], %[a];"
        "setb %%cl;"
        "addq %%rcx, %[k];"
        : /* outputs */ [k] "+g" (k), [tmp] "=&c" (tmp)
        : /* inputs  */ [a] "r" (a), [b] "g" (b)
        : /* clobbers */ "cc");
    return k;

int main()
    uint64_t t, t0, k;
    k = next(1, 2, 0);
    printf("%" PRId64 "\n", k);

    scanf("%" SCNd64 "%" SCNd64, &t, &t0);
    k = next(t, t0, k);
    printf("%" PRId64 "\n", k);

    return 0;

main() translates to:

<+0>:   push   %rbx
<+1>:   xor    %ebx,%ebx
<+3>:   mov    $0x4006c0,%edi
<+8>:   mov    $0x1,%bl
<+10>:  xor    %eax,%eax
<+12>:  sub    $0x10,%rsp
<+16>:  shl    %rax
<+19>:  xor    %rcx,%rcx
<+22>:  cmp    $0x2,%rbx
<+26>:  setb   %cl
<+29>:  add    %rcx,%rax
<+32>:  mov    %rax,%rbx
<+35>:  mov    %rax,%rsi
<+38>:  xor    %eax,%eax
<+40>:  callq  0x400470 <printf@plt>
<+45>:  lea    0x8(%rsp),%rdx
<+50>:  mov    %rsp,%rsi
<+53>:  mov    $0x4006c5,%edi
<+58>:  xor    %eax,%eax
<+60>:  callq  0x4004a0 <__isoc99_scanf@plt>
<+65>:  mov    (%rsp),%rax
<+69>:  mov    %rbx,%rsi
<+72>:  mov    $0x4006c0,%edi
<+77>:  shl    %rsi
<+80>:  xor    %rcx,%rcx
<+83>:  cmp    0x8(%rsp),%rax
<+88>:  setb   %cl
<+91>:  add    %rcx,%rsi
<+94>:  xor    %eax,%eax
<+96>:  callq  0x400470 <printf@plt>
<+101>: add    $0x10,%rsp
<+105>: xor    %eax,%eax
<+107>: pop    %rbx
<+108>: retq   

You can see the result of next() being moved into RSI before each printf() call.

share|improve this answer

You could just do this and the compiler will not generate a branch:

k = (k<<1) + (a < b) ;

But if you must, I fixed some stuff in your code now it should work as expected:

        "shl  $0x1, %0; \
        xor  %%eax, %%eax; \
        cmpl %3, %2; \
        setb %%al; \
        addl %%eax, %0;"
        :"=r"(k)        /* output */
        :"0"(k), "r"(a),"r"(b)  /* input */
        :"eax", "cc"   /* clobbered register */ 

Note that setb expects a reg8 or mem8 and you should add eax to the clobbered list, because you change it, as well as cc just to be safe, as for the register constraints, I'm not sure why you used those, but =r and r work just fine. And you need to add k to both the input and output lists. There's more in the GCC-Inline-Assembly-HOWTO

share|improve this answer
Indeed - any decent compiler should generate branchless code for this. –  Paul R Dec 24 '12 at 15:31
I like this one! –  Mats Petersson Dec 24 '12 at 15:31
k*2 would be better –  David Heffernan Dec 24 '12 at 16:17
Aside from slight readability, why is k*2 better? –  Mats Petersson Dec 24 '12 at 16:38
@DavidHeffernan I'm not sure, why is it better? –  mux Dec 24 '12 at 16:57

Given that gcc (and it looks like gcc inline assembler) produces:

leal    (%rdx,%rdx), %eax
xorl    %edx, %edx
cmpl    %esi, %edi
setl    %dl
addl    %edx, %eax


int f(int a, int b, int k)
  if( a < b ) 
    k = (k<<1) + 1;
    k = (k<<1);

  return k;

It would think that writing your own inline assembler is a complete waste of time and effort.

As always, BEFORE you start writing inline assembler, check what the compiler actually does. If your compiler doesn't produce this code, then you may need to upgrade the version of compiler to something a bit newer (I reported this sort of thing to Jan Hubicka [gcc maintainer for x86-64 at the time] ca 2001, and I'm sure it's been in gcc for quite some time).

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