I am trying to understand how a system call is made in x86. I am reading Smashing the stack for fun and profit. There is a function given on page 7:

#include <stdio.h>
void main() {
    char *name[2];
    name[0] = "/bin/sh";
    name[1] = NULL;
    execve(name[0], name, NULL);

and below the function is given its assembly dump:

Dump of assembler code for function main:

0x8000130 : pushl %ebp
0x8000131 : movl %esp,%ebp
0x8000133 : subl $0x8,%esp
0x8000136 : movl $0x80027b8,0xfffffff8(%ebp)
0x800013d : movl $0x0,0xfffffffc(%ebp)
0x8000144 : pushl $0x0
0x8000146 : leal 0xfffffff8(%ebp),%eax
0x8000149 : pushl %eax
0x800014a : movl 0xfffffff8(%ebp),%eax
0x800014d : pushl %eax
0x800014e : call 0x80002bc <__execve> 
0x8000153 : addl $0xc,%esp
0x8000156 : movl %ebp,%esp
0x8000158 : popl %ebp
0x8000159 : ret

Dump of assembler code for function __execve:

0x80002bc <__execve>: pushl %ebp
0x80002bd <__execve+1>: movl %esp,%ebp
0x80002bf <__execve+3>: pushl %ebx
0x80002c0 <__execve+4>: movl $0xb,%eax
0x80002c5 <__execve+9>: movl 0x8(%ebp),%ebx
0x80002c8 <__execve+12>: movl 0xc(%ebp),%ecx
0x80002cb <__execve+15>: movl 0x10(%ebp),%edx
0x80002ce <__execve+18>: int $0x80
0x80002d0 <__execve+20>: movl %eax,%edx
0x80002d2 <__execve+22>: testl %edx,%edx
0x80002d4 <__execve+24>: jnl 0x80002e6 <__execve+42>
0x80002d6 <__execve+26>: negl %edx
0x80002d8 <__execve+28>: pushl %edx
0x80002d9 <__execve+29>: call 0x8001a34 <__normal_errno_location>
0x80002de <__execve+34>: popl %edx
0x80002df <__execve+35>: movl %edx,(%eax)
0x80002e1 <__execve+37>: movl $0xffffffff,%eax
0x80002e6 <__execve+42>: popl %ebx
0x80002e7 <__execve+43>: movl %ebp,%esp
0x80002e9 <__execve+45>: popl %ebp
0x80002ea <__execve+46>: ret
0x80002eb <__execve+47>: nop

However on writing the same code on my machine and compiling with

gcc test.c -m32 -g -o test -fno-stack-protector -static

and generating the dump with

objdump -S test > test.dis

I get the following dump for main:

void main(){
 8048e24:       55                      push   %ebp
 8048e25:       89 e5                   mov    %esp,%ebp
 8048e27:       83 e4 f0                and    $0xfffffff0,%esp
 8048e2a:       83 ec 20                sub    $0x20,%esp
        char *name[2];
        name[0] = "/bin/sh";
 8048e2d:       c7 44 24 18 e8 de 0b    movl   $0x80bdee8,0x18(%esp)
 8048e34:       08
        name[1] = NULL;
 8048e35:       c7 44 24 1c 00 00 00    movl   $0x0,0x1c(%esp)
 8048e3c:       00
        execve(name[0], name, NULL);
 8048e3d:       8b 44 24 18             mov    0x18(%esp),%eax
 8048e41:       c7 44 24 08 00 00 00    movl   $0x0,0x8(%esp)
 8048e48:       00
 8048e49:       8d 54 24 18             lea    0x18(%esp),%edx
 8048e4d:       89 54 24 04             mov    %edx,0x4(%esp)
 8048e51:       89 04 24                mov    %eax,(%esp)
 8048e54:       e8 17 34 02 00          call   806c270 <__execve>

And for __execve:

0806c270 <__execve>:
 806c270:       53                      push   %ebx
 806c271:       8b 54 24 10             mov    0x10(%esp),%edx
 806c275:       8b 4c 24 0c             mov    0xc(%esp),%ecx
 806c279:       8b 5c 24 08             mov    0x8(%esp),%ebx
 806c27d:       b8 0b 00 00 00          mov    $0xb,%eax
 806c282:       ff 15 f0 99 0e 08       call   *0x80e99f0
 806c288:       3d 00 f0 ff ff          cmp    $0xfffff000,%eax
 806c28d:       77 02                   ja     806c291 <__execve+0x21>
 806c28f:       5b                      pop    %ebx
 806c290:       c3                      ret
 806c291:       c7 c2 e8 ff ff ff       mov    $0xffffffe8,%edx
 806c297:       f7 d8                   neg    %eax
 806c299:       65 89 02                mov    %eax,%gs:(%edx)
 806c29c:       83 c8 ff                or     $0xffffffff,%eax
 806c29f:       5b                      pop    %ebx
 806c2a0:       c3                      ret
 806c2a1:       66 90                   xchg   %ax,%ax
 806c2a3:       66 90                   xchg   %ax,%ax
 806c2a5:       66 90                   xchg   %ax,%ax
 806c2a7:       66 90                   xchg   %ax,%ax
 806c2a9:       66 90                   xchg   %ax,%ax
 806c2ab:       66 90                   xchg   %ax,%ax
 806c2ad:       66 90                   xchg   %ax,%ax
 806c2af:       90                      nop

I understand that the article is very old so it may not match exactly with the current standards. In fact i am able make sense of most of the differences. Here is what is bothering me:

From what I know: to make the exec system call I need to put the arguments in specific registers and call the instruction

int 0x80

to send an interrupt. I can see this instruction at address 0x80002ce in the dump given in the article. But I cannot find the same instruction in mine. In place of it I find

call *0x80e99f0

and the address 0x80e99f0 doesn't even exists in my dump. What am I missing here? What is the point of a * before 0x80e99f0. Is the address 0x80e99f0 being dynamically loaded at runtime? If it is true then what is the use of -static flag during compilation and what can I do to make the dump similar to that of the article?

I am running 64 bit ubuntu 14.04 on Intel processor

Edit after getting suggestion to run objdump with -DS flag:

I finally get the hidden address:

080e99f0 <_dl_sysinfo>:
 80e99f0:       70 ed                   jo     80e99df <_dl_load_lock+0x7>
 80e99f2:       06                      push   %es
 80e99f3:       08 b0 a6 09 08 07       or     %dh,0x70809a6(%eax)

but still can't make any sense.

The address in jo 80e99df points again to something that is hidden in between these lines:

080e99d8 <_dl_load_lock>:
 80e99e4:       01 00                   add    %eax,(%eax)

As evident from the answer the code actually jumps to the address present in memory location 0x80e99f0 which eventually points to int $0x80 instruction.

  • You have to interpret the data at 80e99f0 as data, not as instructions. You get 70 ed 06 08 from that, which is memory address 806ed70 – Ctx Jan 12 '16 at 11:30
  • Why are you defining void main() rather than the correct int main(void)? – Keith Thompson Jan 12 '16 at 20:16
  • @KeithThompson I didn't think about it. In the original article its void main() only. Does it makes a difference to what my problem is? – siddhant Jan 13 '16 at 4:43
  • It's probably not relevant to your problem. But void main() is not portable, and there is no reason to use it rather than the correct and portable int main(void). – Keith Thompson Jan 13 '16 at 8:02
up vote 1 down vote accepted

Try to use objdump -DS or objdump -sS to include the address 0x80e99f0 in your dump.

Local example:

0806bf70 <__execve>:
806bf82:       ff 15 10 a3 0e 08       call   *0x80ea310

At address 0x80ea310 (shown with objdump -sS):

80ea310 10ea0608 60a60908 07000000 7f030000

10ea0608 is address 0x806ea10 little-endian in memory.

You will then see, that the address of _dl_sysinfo_int80 is located there:

0806ea10 <_dl_sysinfo_int80>:
 806ea10:       cd 80                   int    $0x80
 806ea12:       c3                      ret    

which calls the software interrupt 0x80 (executes the syscall) and returns to the caller then.

call *0x80ea310 is therefore really calling 0x806ea10 (dereferencing a pointer)

  • I edited the question with inputs from your suggestions. I still cant't make any sense.. – siddhant Jan 12 '16 at 11:27
  • @Siddhant tried to clarify – Ctx Jan 12 '16 at 11:35
  • Thank you. I got what you are trying to say. Why is gcc doing this all complications. Any ideas? And what exactly did -D flag do to the objdump command. – siddhant Jan 12 '16 at 11:43
  • This is standard linking procedure, dereference an address in the linkage table which is filled on executable linkage, not when compiling the object files. – Ctx Jan 12 '16 at 11:44
  • If I straightaway call int $0x80 after filling the appropriate registers. Will it still work? I think it should – siddhant Jan 12 '16 at 11:48

Traditionally, Linux used interrupt 0x80 to invoke system calls. Since the PentiumPro, there is an alternative way to invoke a system call: using the SYSENTER instruction (AMD also has its own SYSCALL instruction). This is a more efficient way to invoke a system call.

Choosing which syscall mechanism to use

The linux kernel and glibc have a mechanism to choose between the different ways to invoke a system call.

The kernel sets up a virtual shared library for each process, it's called the VDSO (virtual dynamic shared object), which you can see in the output of cat /proc/<pid>/maps:

$ cat /proc/self/maps
08048000-0804c000 r-xp 00000000 03:04 1553592    /bin/cat
0804c000-0804d000 rw-p 00003000 03:04 1553592    /bin/cat
b7ee8000-b7ee9000 r-xp b7ee8000 00:00 0          [vdso]

This vdso, among other things, contains an appropriate system call invocation sequence for the CPU in use, e.g:

ffffe414 <__kernel_vsyscall>:
ffffe414:       51                      push   %ecx        ; \
ffffe415:       52                      push   %edx        ; > save registers
ffffe416:       55                      push   %ebp        ; /
ffffe417:       89 e5                   mov    %esp,%ebp   ; save stack pointer
ffffe419:       0f 34                   sysenter           ; invoke system call
ffffe41b:       90                      nop
ffffe41c:       90                      nop                ; the kernel will usually
ffffe41d:       90                      nop                ; return to the insn just
ffffe41e:       90                      nop                ; past the jmp, but if the
ffffe41f:       90                      nop                ; system call was interrupted
ffffe420:       90                      nop                ; and needs to be restarted
ffffe421:       90                      nop                ; it will return to this jmp
ffffe422:       eb f3                   jmp    ffffe417 <__kernel_vsyscall+0x3>
ffffe424:       5d                      pop    %ebp        ; \
ffffe425:       5a                      pop    %edx        ; > restore registers
ffffe426:       59                      pop    %ecx        ; /
ffffe427:       c3                      ret                ; return to caller

In arch/x86/vdso/vdso32/ there are implementations using int 0x80, sysenter and syscall, the kernel selects the appropriate one.

To let userspace know that there is a vdso, and where it is located, the kernel sets AT_SYSINFO and AT_SYSINFO_EHDR entries in the auxiliary vector (auxv, the 4th argument to main(), after argc, argv, envp, which is used to pass some information from the kernel to newly started processes). AT_SYSINFO_EHDR points to the ELF header of the vdso, AT_SYSINFO points to the vsyscall implementation:

$ LD_SHOW_AUXV=1 id    # tell the dynamic linker ld.so to output auxv values
AT_SYSINFO:      0xb7fd4414
AT_SYSINFO_EHDR: 0xb7fd4000

glibc uses this information to locate the vsyscall. It stores it into the dynamic loader global _dl_sysinfo, e.g.:

  case AT_SYSINFO:
    GL(dl_sysinfo) = av->a_un.a_val;
#if defined NEED_DL_SYSINFO || defined NEED_DL_SYSINFO_DSO
    GL(dl_sysinfo_dso) = (void *) av->a_un.a_val;


GLRO(dl_sysinfo) = GLRO(dl_sysinfo_dso)->e_entry + l->l_addr;

and in a field in the header of the TCB (thread control block):


_head->sysinfo = GLRO(dl_sysinfo)

If the kernel is old and doesn't provide a vdso, glibc provides a default implementation for _dl_sysinfo:

.hidden _dl_sysinfo_int80:
int $0x80

When a program is compiled against glibc, depending on circumstances, a choice is made between different ways of invoking a system call:

/* The original calling convention for system calls on Linux/i386 is
   to use int $0x80.  */
#ifdef I386_USE_SYSENTER
# ifdef SHARED
# else
#  define ENTER_KERNEL call *_dl_sysinfo
# endif
# define ENTER_KERNEL int $0x80
  • int 0x80 ← the traditional way
  • call *%gs:offsetof(tcb_head_t, sysinfo)%gs points to the TCB, so this jumps indirectly through the pointer to vsyscall stored in the TCB
  • call *_dl_sysinfo ← this jumps indirectly through the global variable

So, in x86:

                    system call
int 0x80 / call *%gs:0x10 / call *_dl_sysinfo
                    │            │
                      ↓          ↓         ↓
         (in vdso) int 0x80 / sysenter / syscall

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.