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Basically, I read through parts of http://www.nasm.us/links/unix64abi and at page 29, it shows the initial process stack of a C program.

My question is: I'm trying to interface with glibc from x86-64 nasm and based on what the above shows, argc should be at rsp. So the following code should print argc:

[SECTION .data]
PrintStr: db "You just entered %d arguments.", 10, 0

[SECTION .bss]

[SECTION .text]
extern printf
global main

main:
     mov rax, 0        ; Required for functions taking in variable no. of args
     mov rdi, PrintStr
     mov rsi, [rsp]
     call printf
     ret

But it doesn't. Can someone enlighten me if I have made any mistakes in my code or tell me what the actual stack structure is?

Thanks!

UPDATE: I just randomly tried some offsets and changing the "mov rsi, [rsp]" to "mov rsi, [rsp+28]" did the trick.

But this means that the stack structure shown is wrong. Does anyone know what the initial stack layout is for an x86-64 elf? An equivalent of http://asm.sourceforge.net/articles/startup.html would be really nice.

UPDATE 2: I left out how I build this code. I do it by:

nasm -f elf64 -g <filename>
gcc <filename>.o -o <outputfile>
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1 Answer 1

up vote 1 down vote accepted

The initial stack layout contains argc at the stack pointer, followed by the array char *argv[], not a pointer to it like main receives. Therefore, to call main, you need to do something like:

pop %rdi
mov %rsp,%rsi
call main

In reality there is usually a wrapper function that calls main, rather than the startup code doing it directly.

If you want to simply print argv[0], you could do something like:

pop %rdi
pop %rdi
call puts
xor %edi,%edi
jmp exit
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Hi, thanks for the reply. Just to clarify, I'm not calling a C program with a main function, but just using C library functions. I updated how the code is built in the question. I tried having another global label call the main label, but then it failed at the link stage (gcc is used to link the code). Apparently main must be a global label in this case. –  yanhan May 1 '11 at 1:57
    
If you're going to use libc functions, you should be aware that bypassing the libc startup code may cause them to crash. For example glibc probably wants to initialize the %gs thread-local storage selector even if threads aren't being used, to make sysenter-type syscalls with it and to store other random junk there. You should either create a global main in asm and let the libc startup code call it, or omit libc entirely and perform all your syscalls in asm. –  R.. May 1 '11 at 2:46
    
Hi, am I bypassing libc startup code here? I was following how Jeff Duntemann's "Assembly Language Step by Step" called C code from nasm. Could you provide me with examples of how not to bypass libc startup code if I'm doing so? Thanks! –  yanhan May 1 '11 at 3:15
    
Oh, I'm a fool. Somehow I thought you had written a _start entry point since that's how most people do asm-only programs. If you used main, then the stack will contain nothing meaningful and the arguments will be argc in rdi and argv (of type char **) in rsi. –  R.. May 1 '11 at 3:27
    
Ok I kind of just realized why argc is in rdi and argv in rsi as that is how arguments are passed in x86-64. Just didn't know that it even applies to the main label. Thanks for the help! Btw do you know of an equivalent to http://asm.sourceforge.net/articles/startup.html for x86-64? Because the stack layout there is correct for i386 whereas the one in http://www.nasm.us/links/unix64abi doesn't tally. Or is it because I used main and it applies for _start? –  yanhan May 1 '11 at 6:22

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