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I've got a function whose inner code I want to convert into assembly (for various reasons):

int foo(int x, int y, int z);

I generated the assembly code using:

clang -S -mllvm --x86-asm-syntax=intel foo.c

The assembly output: foo.s starts off with something like:

_foo:                               ## @foo
## BB#0:
    push    RBP
    .cfi_def_cfa_offset 16

I assume this is the corresponding assembly code for that function. My question is, what part of the assembly output should I copy into the C code (I'm trying to use inline assembly) so that the function would work? The code should look like:

int foo(int x, int y, int z) {
   __asm__("..."); // <-- What goes inside?


share|improve this question
You can let your debugger to run on assembly code then you can step on that function and find out actually what part needs to be used. But keep in mind that the complier optimizes a lot of thing so it may not be correct always. – Jun 4 '14 at 10:24
Hmm, so if I found where the function actually starts, would copy and pasting the assembly code directly into C (wrapped around with asm etc.) work? I won't need to specify operand lists or clobber lists or anything right? – Peter Jun 4 '14 at 10:27
Unless your asm is tiny and you think it should get inlined, write your whole function in an asm source file, and call it. (Keep a prototype for it in a C header file of course.) Then your build system has to know to compile that asm source for x86 and/or x86-64 builds, instead of just with #ifdef in C. Getting inline asm correct, esp. getting the constraints, clobbers, and inputs/outputs exactly right, is hard but required for it to work correctly. (If you do go that route, check the disassembly output to make sure your ASM is slotting in the way you expect). – Peter Cordes Jul 6 '15 at 2:49

You have to see the disassembly of that function and write the __asm__. For example below code

int foo(int x, int y, int z) {
x = y+z; return x; }

will yeild a disassembly of following :

int foo(int x, int y, int z) {
  push        ebp  
  mov         ebp,esp 
  sub         esp,0C0h 
  push        ebx  
  push        esi  
  push        edi  
  lea         edi,[ebp-0C0h] 
  mov         ecx,30h 
  mov         eax,0CCCCCCCCh 
  rep stos    dword ptr es:[edi] 

  x = y+z;
  mov         eax,dword ptr [y] 
  add         eax,dword ptr [z] 
  mov         dword ptr [x],eax 

  return x;
  mov         eax,dword ptr [x] 

so you have to add below for statement x= y+z,

 mov         eax,dword ptr [y] 
 add         eax,dword ptr [z] 
 mov         dword ptr [x],eax 
share|improve this answer
Okay, I have a slight issue with this, the compiler is complaining that I'm not returning a variable (because I'm returning via assembly), any way to solve this? – Peter Jun 4 '14 at 10:51
Include the mov eax,dword ptr [x] , it worked. int foo(int x, int y, int z) { x = y+z; _asm{ mov eax,dword ptr [x] } } – Balu Jun 4 '14 at 10:57
Are you using MSVC for compiling? Do you know to do the same thing with clang? – Peter Jun 4 '14 at 11:06
yes. Clang I never used before. But, Clang-based C++ compilers allow inline assembly with these caveats: You cannot mix assembly with C++ code. Do not touch the stack pointer (RSP). The assembler must use the AT&T line-by-line syntax, not the more familiar block-of-Intel syntax. For more information, see GCC-Inline-Assembly-HOWTO. Clang-based C++ compilers support inline assembly in a different style than the inline assembly supported by BCC32: The Assembly syntax supported by Clang-based C++ compilers is line-by-line AT&T syntax, not the more familiar block-of-Intel syntax. – Balu Jun 4 '14 at 12:34

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