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I am doing some x86 exercises; my assignment has me stepping through the assembly code for the write() library call in a debugger until we reach a SYSENTER instruction, but I get different results from that of some of my classmates. What I saw leading up to SYSENTER was:

   │0xf7fdf421 <__kernel_vsyscall+1>        push   %edx                                                                                            
   │0xf7fdf422 <__kernel_vsyscall+2>        push   %ebp                                                                                            
   │0xf7fdf423 <__kernel_vsyscall+3>        mov    %esp,%ebp                                                                                       
   │0xf7fdf425 <__kernel_vsyscall+5>        sysenter    

Is this what I should see? If so, why is it different from what some of my classmates saw? Also are %edx and %ebp registers saved on the stack before executing the sysenter instruction? (Would it not seem so according to the answer I got or am I wrong?)

Here's my original instructions from my assignment:

The assembly code:

.file    "A3Program2.c"
    .section    .rodata
.LC0:
    .string    "hello\n"
.LC1:
    .string    "xxxx\n"
    .text
.globl secondCall
    .type    secondCall, @function
secondCall:
    pushl    %ebp
    movl    %esp, %ebp
    subl    $40, %esp
    movl    $6, 8(%esp)
    movl    $.LC0, 4(%esp)
    movl    $1, (%esp)
    call    write
    movl    %eax, -12(%ebp)
    movl    $8, 8(%esp)
    movl    $.LC1, 4(%esp)
    movl    $1, (%esp)
    call    write
    addl    %eax, -12(%ebp)
    movl    12(%ebp), %eax
    movl    8(%ebp), %edx
    leal    (%edx,%eax), %eax
    addl    %eax, -12(%ebp)
    movl    -12(%ebp), %eax
    leave
    ret
    .size    secondCall, .-secondCall
.globl firstCall
    .type    firstCall, @function
firstCall:
    pushl    %ebp
    movl    %esp, %ebp
    subl    $40, %esp
    movl    $2, 4(%esp)
    movl    $4, (%esp)
    call    secondCall
    movl    %eax, -12(%ebp)
    movl    -12(%ebp), %eax
    leave
    ret
    .size    firstCall, .-firstCall
.globl main
    .type    main, @function
main:
    pushl    %ebp
    movl    %esp, %ebp
    andl    $-16, %esp
    subl    $16, %esp
    call    firstCall
    movl    %eax, 12(%esp)
    movl    $0, %eax
    leave
    ret
    .size    main, .-main
    .ident    "GCC: (Ubuntu/Linaro 4.4.4-14ubuntu5) 4.4.5"
    .section    .note.GNU-stack,"",@progbits

The following instructions are for Linux:

Find the line number of the second call to write, “call write”, in the secondCall function. Set a break point at this line. Which is 22 according to me.

Set a break point at this line.

 break 22

Run the program inside the debugger.

 run

The program will stop at the break point you set. Step into the code which does not have the debugging information.

  si 

You will see “[ No Source Available ]” in the source layout. So you need to view the disassembled instructions.

 layout asm

Repeatedly step into (si and then return/enter will execute the si command repeatedly) until you see “sysenter” appear in the asm layout section of the screen. I am trying to copy the instructions (including their addresses) from the top of the asm layout section, down to and including the sysenter instruction.

Hint: You can change the focus of the keyboard to the command area by typing Ctrl-x o. This way the arrow keys can be used to bring back earlier commands (it just saves some typing).

share|improve this question
1  
... what's your question, exactly? –  bdonlan Oct 16 '11 at 1:09
1  
I want to know if the answer I got is correct....I mentioned that in the question itself... –  Jay Oct 16 '11 at 1:11
1  
Please do not edit out the content of your question when you get the answer. If the answer can be found below, accept it; otherwise write the answer you found and accept your own answer. This will help future searchers with the same question. –  bdonlan Oct 16 '11 at 3:04
1  
so post your answer so others can benefit. Or leave the question alone, in hopes that someone will come along and post an answer that will be helpful for others. Don't just erase all the context. I spent quite some time on my answer, and I'd like to see it be helpful for someone else, even if you don't care for the answer. –  bdonlan Oct 16 '11 at 3:10
1  
please see meta.stackexchange.com/questions/36110/… –  bdonlan Oct 16 '11 at 3:11

1 Answer 1

You are tracing into what is called the 'virtual dynamic shared object' (VDSO) - the contents of which are an implementation detail of the linux kernel. There are a number of conditions that can cause the contents of the VDSO to change; as such there is no single correct answer here.

In particular, on 32-bit x86 systems, there are at least three different mechanisms that can be used to make a system call:

  • INT $0x80
  • SYSCALL (recent AMD CPUs)
  • SYSENTER (recent Intel CPUs)

You'll note that only INT $0x80 works on all CPUs (indeed, the kernel makes it available for legacy applications even when more modern alternatives are also available); however, it's also slow. The kernel will probe for which are supported at boot time, and select a version of the VDSO that uses the most efficient mechanism available.

As such, depending on your CPU model, you may see different code in the VDSO - in particular, if you have an AMD CPU, you're likely to see the SYSCALL path, and if you have a really old CPU you might even see the INT $0x80 path. If you're curious about the others, here's the source code:

Most likely, the other folks in your lab who got a different result had an AMD CPU and were looking at the SYSCALL path (or they had an antique PC, and were looking at the INT $0x80 path).

Note also that in a 64-bit process, SYSENTER will be used directly, without going through the VDSO at all.

share|improve this answer
    
I am not really lookin for this sort of answer. I just want to know if the answer I got is correct and if it is not then how to fix it. –  Jay Oct 16 '11 at 1:24
    
@Jay, there is no one 'correct answer' here. The contents of the VDSO are an implementation detail. The kernel people can change it at any time - and, as I said, it does indeed vary. If all you're interested in is whether this is 'correct', I think you have misunderstood the aim of your exercise - isn't it to understand the behavior you see? –  bdonlan Oct 16 '11 at 1:27
    
Also note that INT $0x80 is always available even if the kernel has selected another method in the VDSO. This is not an accident. –  Joshua Oct 16 '11 at 1:28
2  
@Jay, wow, bdonlan gives one of the best write-ups of this functionality I've ever seen -- and incidentally, provides you with reasons why you and your fellow tutorialists got different answers -- and you're unhappy?? –  sarnold Oct 16 '11 at 1:29
1  
The write up is fine. I have it in my notes. Thanks for th writeup though. –  Jay Oct 16 '11 at 1:32

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