I understand when to use a cobbler list (e.g. listing a register which is modified in the assembly so that it doesn't get chosen for use as an input register, etc), but I can't wrap my head around the the earlyclobber constraint &. If you list your outputs, wouldn't that already mean that inputs can't use the selected register (aside from matching digit constraints)?

For example:

    "movl $1, %0;"
    "addl $3, %0;"
    "addl $4, %1;"
    "addl %1, %0;"
    : "=g"(num_out)
    : "g"(num_in)

Would & even be needed for the output variables? The compiler should know the register that was selected for the output, and thus know not to use it for the input.


By default, the compiler assumes all inputs will be consumed before any output registers are written to, so that it's allowed to use the same registers for both. This leads to better code when possible, but if the assumption is wrong, things will fail catastrophically. The "early clobber" marker is a way to tell the compiler that this output will be written before all the input has been consumed, so it cannot share a register with any input.

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  • So that means that the compiler could assume, for example, that the eax register I use for an input is no longer needed by the time the output is needed, so it reuses the eax register? Does this mean the output in my code in the original question does in fact require a & modifier? – Vilhelm Gray Apr 4 '13 at 19:29
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    Your code is wrong for multiple reasons. For instance, you're modifying an input register. – R.. GitHub STOP HELPING ICE Apr 4 '13 at 20:31
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    A typical "earlyclobber" for x86 is the use of extending multiplication, where EDX:EAX / RDX:RAX implicitly are outputs. When those instructions are used in a multi-input asm() statement, the d and a registers can not be used as input after the earlyclobber output "consumed" the contents. If that specific input operand is used more than once, the compiler will put it into a different register. – FrankH. Apr 19 '13 at 8:43

Minimal educational example

Here I provide a minimal educational example that attempts to make what https://stackoverflow.com/a/15819941/895245 mentioned clearer.

This code is of course not useful in practice, and could be achieved more efficiently a single lea 1(%q[in]), %out instruction.


#include <assert.h>
#include <inttypes.h>

int main(void) {
    uint64_t in = 1;
    uint64_t out;
    __asm__ (
        "mov %[in], %[out];" /* out = in */
        "inc %[out];"        /* out++ */
        "mov %[in], %[out];" /* out = in */
        "inc %[out];"        /* out++ */
        : [out] "=&r" (out)
        : [in] "r" (in)
    assert(out == 2);

Compile and run:

gcc -ggdb3 -std=c99 -O3 -Wall -Wextra -pedantic -o main.out main.c

This program is correct and the assert passes, because & forces the compiler to choose different registers for in and out.

This is because & tells the compiler that in might be used after out was written to, which is actually the case here.

Therefore, the only way to not wrongly modify in is to put in and out in different registers.

The disassembly:

gdb -nh -batch -ex 'disassemble/rs main' main.out


   0x0000000000001055 <+5>:     48 89 d0        mov    %rdx,%rax
   0x0000000000001058 <+8>:     48 ff c0        inc    %rax
   0x000000000000105b <+11>:    48 89 d0        mov    %rdx,%rax
   0x000000000000105e <+14>:    48 ff c0        inc    %rax

which shows that GCC chose rax for out and rdx for in.

If we remove the & however, the behavior is unspecified.

In my test system, the assert actually fails, because the compiler tries to minimize register usage, and compiles to:

   0x0000000000001055 <+5>:     48 89 c0        mov    %rax,%rax
   0x0000000000001058 <+8>:     48 ff c0        inc    %rax
   0x000000000000105b <+11>:    48 89 c0        mov    %rax,%rax
   0x000000000000105e <+14>:    48 ff c0        inc    %rax

therefore using rax for both in and out.

The result of this is that out is incremented twice, and equals 3 instead of 2 in the end.

Tested in Ubuntu 18.10 amd64, GCC 8.2.0.

More practical examples

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  • Worth mentioning that this example is only an intentionally simplistic easy-to-understand example. An asm statement where the first or last instruction is mov usually means you're doing it wrong. Use constraints to get the compiler to put inputs where you want them, or take outputs wherever you leave them (even in EFLAGS with GCC6 condition-code outputs.) Also, x86 can copy-and-increment with lea 1(%q[in]), %out. (q modifier to force 64-bit address size, regardless of output size. gcc.gnu.org/onlinedocs/gcc/…) – Peter Cordes Feb 27 '19 at 4:23
  • @PeterCordes definitely, that code is useless. A useful example would also be a good addition. – Ciro Santilli 郝海东冠状病六四事件法轮功 Feb 27 '19 at 9:45
  • Nothing jumped to mind immediately, just thought it would be worth a comment in the code for the benefit of people trying to learn inline asm in general that it should basically never start with mov, because constraints. (Although copying a input that you read multiple times is one actually reasonable use-case.) – Peter Cordes Feb 27 '19 at 9:47
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    @CiroSantilli新疆改造中心六四事件法轮功 Another use of =&r, which nobody seems to have mentioned explicitly, is having temporary register variables that one can refer to by meaningful names, e.g. %[running_sum] instead of hard-coded %r8. – Alexey Frunze Feb 27 '19 at 11:45
  • @AlexeyFrunze cool! I ended up adding an example of that at: stackoverflow.com/questions/6682733/… – Ciro Santilli 郝海东冠状病六四事件法轮功 Mar 2 '19 at 22:56

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