2

Overflow,

how can I implement the putchar(char) procedure using inline assembly only? I would like to do this in x86-64 assembly. The reason for me doing this is to implement my own standard-lib (or at least part of it). Here is what I have so far:

void putchar(char c)
{   
    /* your code here: print character c on stdout */
    asm(...);
}   

void _start()
{   
    /* exit system call */
    asm("mov $1,%rax;"
        "xor %rbx,%rbx;"
        "int  $0x80"
    );  
}

I am compiling with:

gcc -nostdlib -o putchar putchar.c

Thanks for helping me!

  • 2
    What OS/environment? What have you tried so far? You'll have to be more precise than that. – Mat Mar 24 '13 at 9:02
  • Thanks for you quick reply, it's Linux on x86-64. I have tried to invoke interrupt 0x80 with %eax, 0x04. But I did not know how to access/forward the function parameter of putchar(char) in/to inline-assembly. – dubbaluga Mar 24 '13 at 9:15
  • 3
    @dubbaluga - You might also want to consider why the real putchar might not be written in assembly. – Bo Persson Mar 24 '13 at 9:34
  • @Mat: The first link does not really provide an answer as it is not inline code. What I really need is a hint on how to forward the content of variables to inline assembly. – dubbaluga Mar 24 '13 at 10:59
2

When using GNU C inline asm, use constraints to tell the compiler where you want things, instead of doing it "manually" with instructions inside the asm template.

For writechar and readchar, we only need a "syscall" as the template, with constraints to set up all the inputs in registers (and the pointed-to char in memory for the write(2) system call), according to the x86-64 Linux system-call convention (which very closely matches the System V ABI's function-calling convention). What are the calling conventions for UNIX & Linux system calls on i386 and x86-64.

This also makes it easy to avoid clobbering the red-zone (128 bytes below RSP), where the compiler might be keeping values. You must not clobber it from inline asm (so push / pop aren't usable unless you sub rsp, 128 first: see Using base pointer register in C++ inline asm for that and many useful links about GNU C inline asm), and there's no way to tell the compiler you clobber it. You could build with -mno-redzone, but in this case input/output operands are much better.


I'm hesitant to call these putchar and getchar. You can do that if you're implementing your own stdio that doesn't support buffering yet, but some functions require input buffering to implement correctly. For example, scanf has to examine characters to see if they match the format string, and leave them "unread" if they don't. Output buffering is optional, though; you could I think fully implement stdio with functions that create a private buffer and write() it, or directly write() their input pointer.

writechar():

int writechar(char my_char)
{
    int retval;  // sys_write uses ssize_t, but we only pass len=1
                 // so the return value is either 1 on success or  -1..-4095 for error
                 // and thus fits in int

    asm volatile("syscall  #dummy arg picked %[dummy]\n"
                    : "=a" (retval)  /* output in EAX */
                    /* inputs: ssize_t read(int fd, const void *buf, size_t count); */
                    : "D"(1),         // RDI = fd=stdout
                      "S"(&my_char),  // RSI = buf
                      "d"(1)          // RDX = length
                      , [dummy]"m" (my_char) // dummy memory input, otherwise compiler doesn't store the arg
                    /* clobbered regs */
                    : "rcx", "r11"  // clobbered by syscall
                );
    // It doesn't matter what addressing mode "m"(my_char) picks,
    // as long as it refers to the same memory as &my_char so the compiler actually does a store

    return retval;
}

This compiles very efficiently with gcc -O3, on the Godbolt compiler explorer.

writechar:
    movb    %dil, -4(%rsp)        # store my_char into the red-zone
    movl    $1, %edi
    leaq    -4(%rsp), %rsi
    movl    %edi, %edx            # optimize because fd = len
    syscall               # dummy arg picked -4(%rsp)

    ret

@nrz's test main inlines it much more efficiently than the unsafe (red-zone clobbering) version in that answer, taking advantage of the fact that syscall leaves most registers unmodified so it can just set them once.

main:
    movl    $97, %r8d            # my_char = 'a'
    leaq    -1(%rsp), %rsi       # rsi = &my_char
    movl    $1, %edx             # len
.L6:                           # do {
    movb    %r8b, -1(%rsp)       # store the char into the buffer
    movl    %edx, %edi           # silly compiler doesn't hoist this out of the loop
    syscall  #dummy arg picked -1(%rsp)

    addl    $1, %r8d
    cmpb    $123, %r8b
    jne     .L6                # } while(++my_char < 'z'+1)

    movb    $10, -1(%rsp)
    syscall  #dummy arg picked -1(%rsp)

    xorl    %eax, %eax         # return 0
    ret

readchar(), done the same way:

int readchar(void)
{
    int retval;
    unsigned char my_char;
    asm volatile("syscall  #dummy arg picked %[dummy]\n"
                    /* outputs */
                    : "=a" (retval)
                     ,[dummy]"=m" (my_char) // tell the compiler the asm dereferences &my_char

                    /* inputs: ssize_t read(int fd, void *buf, size_t count); */
                    : "D"(0),         // RDI = fd=stdin
                      "S" (&my_char), // RDI = buf
                      "d"(1)          // RDX = length

                    : "rcx", "r11"  // clobbered by syscall
                );
    if (retval < 0)   // -1 .. -4095 are -errno values
        return retval;
    return my_char;   // else a 0..255 char / byte
}

Callers can check for error by checking c < 0.

  • @dubbaluga: GNU C inline asm is hard enough to use without unsafe examples that happen to work for some callers floating around on SO; thanks for accepting this answer :) – Peter Cordes Jun 5 '18 at 7:38
3

Here's an example my_putchar in GCC x86-64 inline assembly (in Intel syntax, converting to AT&T should be trivial).

Compiles with:

gcc -ggdb -masm=intel -o gcc_asm_putchar gcc_asm_putchar.c

Edit: rdi was missing from clobbered registers. Fixed.

Here's the code:

int main(void)
{
    char my_char;

    for (my_char = 'a'; my_char <= 'z'; my_char++)
            my_putchar(my_char);

    my_char = '\n';
    my_putchar(my_char);
    return 0;
}

void my_putchar(char my_char)
{
    int dword_char;
    dword_char = (int)my_char;
    asm volatile(
                    ".intel_syntax noprefix;"
                    "mov r10,rsp;"   // save rsp.
                    "sub rsp,8;"     // space for buffer, align by 8.
                    "mov [rsp],al;"  // store the character into buffer.
                    "mov edi,1;"     // STDOUT.
                    "mov rsi,rsp;"   // pointer to buffer.
                    "mov edx,1;"     // string length in bytes.
                    "mov eax,1;"     // WRITE.
                    "syscall;"       // clobbers rcx & r11.
                    "mov rsp,r10;"   // restore rsp.
                    ".att_syntax prefix;"
                    /* outputs */
                    :
                    /* inputs: eax */
                    : "a"(dword_char)
                    /* clobbered regs */
                    : "rcx", "rdx", "rsi", "rdi", "r10", "r11"
                );
}
  • Thank you - does exactly what I was looking for. :-) – dubbaluga Mar 24 '13 at 13:03
  • does not compile for me. :( Says: gcc_asm_putchar.c:36: undefined reference to `rbp' – Lucas Pottersky Oct 10 '17 at 17:14
  • 1
    "sub rsp,8;" is not safe in inline asm; you clobber the red-zone and there's no way to tell the compiler about it. Use a memory input operand, or sub rsp, 128. Using base pointer register in C++ inline asm. Also, you tell the compiler that rax is input-only, but syscall clobbers it with the return value. Also, your code breaks if compiled with -masm=intel: you unconditionally leave the assembler in AT&T mode for compiler-generated code. – Peter Cordes Jun 5 '18 at 1:28
2

Note that getchar(3)/putchar(3) are macros (for performance) which mess around with complex data in the FILE structure for stdin/stdout, specifically handling buffering and other. The answer by nrz just does a 1 char write(3) to file descriptor 1, something very different.

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