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I am running linux on i386:x86_64.I've written a piece of c code and I've disassembled it as well as read the registers to understand how the program works in assembly. Below is my c program that I've written.

#include <unistd.h>
#include <string.h>
#include <stdio.h>

char *string_in = "Did not work";

int test(char *this){
    char sum_buf[6];
    return 0;

int hello(){
    printf("hello man");
    string_in = "If this triggered, it means our shell code is working\n";
    return 0;

int main(int argc, void **argv){
    test("\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x28\x06\x06\x40\x00\x00\x00\x00\x00");//6f 73
    printf("My string is %s",string_in);
    return 0;

The piece of my code that I've been examining is the test function. When I disassemble the output my test function I get ...

   0x00000000004005b4 <+0>:         push   %rbp
   0x00000000004005b5 <+1>:         mov    %rsp,%rbp
   0x00000000004005b8 <+4>:         sub    $0x20,%rsp
   0x00000000004005bc <+8>:         mov    %rdi,-0x18(%rbp)
   0x00000000004005c0 <+12>:        mov    %fs:0x28,%rax
=> 0x00000000004005c9 <+21>:        mov    %rax,-0x8(%rbp)
   0x00000000004005cd <+25>:        xor    %eax,%eax
   0x00000000004005cf <+27>:        mov    -0x18(%rbp),%rcx
   0x00000000004005d3 <+31>:        lea    -0x10(%rbp),%rax
   0x00000000004005d7 <+35>:        mov    $0x20,%edx
   0x00000000004005dc <+40>:        mov    %rcx,%rsi
   0x00000000004005df <+43>:        mov    %rax,%rdi
   0x00000000004005e2 <+46>:        callq  0x400490 <strncpy@plt>
   0x00000000004005e7 <+51>:        mov    $0x0,%eax
   0x00000000004005ec <+56>:        mov    -0x8(%rbp),%rdx
   0x00000000004005f0 <+60>:        xor    %fs:0x28,%rdx
   0x00000000004005f9 <+69>:        je     0x400600 <test+76>
   0x00000000004005fb <+71>:        callq  0x4004a0 <__stack_chk_fail@plt>
   0x0000000000400600 <+76>:        leaveq 
   0x0000000000400601 <+77>:        retq 

Now my interest lies in line <12>. From my understanding that instruction is telling the computer to take the first 28 bits of the segment register %fs and place it into %rax my accumulator. What bothers me is that before and after this line is executed, I read the register %fs via p/x $fs which shows a value of zero ( even throughout the program ) and thus %rax must be zero. However %rax does not show zero after the instruction has been executed. In fact what does result is a random number. This random number is then placed 8 bytes before %rbp (since it is little endian) and then checked again in case there is a buffer over flow that has overwritten that space.

What I would like to know is what mov %fs:0x28,%rax is really doing. Have I understood it right? Why am I reading zero for %fs when in p/x $fs and how do I read the correct value?

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2 Answers 2

up vote 14 down vote accepted

On x86_64, segmented addressing is no longer used, but the both the FS and GS registers can be used as base-pointer addresses in order to access special operating system data-structures. So what you're seeing is a value loaded at an offset from the value held in the FS register, and not bit manipulation of the contents of the FS register.

Specifically what's taking place, is that FS:0x28 on Linux is storing a special sentinel stack-guard value, and the code is performing a stack-guard check. For instance, if you look further in your code, you'll see that the value at FS:0x28 is stored on the stack, and then the contents of the stack are recalled and an XOR is performed with the original value at FS:0x28. If the two values are equal, which means that the zero-bit has been set because XOR'ing two of the same values results in a zero-value, then we jump to the test routine, otherwise we jump to a special function that indicates that the stack was somehow corrupted, and the sentinel value stored on the stack was changed.

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Ok, that makes sense. How could I read this address and value with gdb? –  Mr.Student Apr 26 '12 at 1:18
The simplest way is to look at the contents of the RAX register directly after the MOV operation. –  Jason Apr 26 '12 at 1:37

Looking at http://www.imada.sdu.dk/Courses/DM18/Litteratur/IntelnATT.htm, I think %fs:28 is actually an offset of 28 bytes from the address in %fs. So I think it's loading a full register size from location %fs + 28 into %rax.

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This is just not correct. fs is not a "normal" register. It is a segment register. In protected mode, fs is a selector into the GDT. There are hidden "base" and "limit" registers associated with it, that you cannot see. So fs:0x28 is really [hidden_fs_base + 0x28]. –  Jonathon Reinhart Jan 21 '13 at 8:24

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