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I'm reading up on smashing the stack and have found myself to be getting stuck on example3.c.

0x80004a3 <main+19>:    call   0x8000470 <function>
0x80004a8 <main+24>:    addl   $0xc,%esp
0x80004ab <main+27>:    movl   $0x1,0xfffffffc(%ebp)
0x80004b2 <main+34>:    movl   0xfffffffc(%ebp),%eax

The author indicates that we want to skip from 0x80004a8 to 0x80004b2 and that this jump is 8 bytes; how has the author determined this is 8 bytes? I have recreated the code and sent it through objdump and found that it's not 8 bytes (I am on a 64 bit machine but I've made sure to compile using 32 bit):

8048452:    e8 b5 ff ff ff          call   804840c <function>
8048457:    c7 44 24 1c 01 00 00    movl   $0x1,0x1c(%esp)
804845e:    00 
804845f:    8b 44 24 1c             mov    0x1c(%esp),%eax
8048463:    89 44 24 04             mov    %eax,0x4(%esp)
8048467:    c7 04 24 18 85 04 08    movl   $0x8048518,(%esp)

The author also said "How did we know to add 8 to the return address? We used a test value first (for example 1)" Where did he use this test value at?

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migrated from security.stackexchange.com Oct 22 '12 at 6:57

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Moving to StackOverflow by user request. (+1, good question.) –  Jeff Ferland Oct 22 '12 at 6:56
This has been of assistance: ethicalhacker.net/content/view/122/2 –  josten Oct 22 '12 at 15:14
If you subtract the addresses just like in that article, you get 10 bytes :) check the links at the end of my answer, the offset is wrong. –  mux Oct 22 '12 at 15:32

3 Answers 3

That's not how I interpret the article. The way I understand it he wants to modify the return address so that the x = 1; assignment is skipped, i.e. he wants function to return to where the printf would be executed.

As you can see in your disassembly, the assignment is 8 bytes (c7 44 24 1c 01 00 00 00), hence moving the return address 8 bytes forward would move it past this instruction. As for the "We used a test value first" comment.. maybe he just means that he looked at the code in a disassembler to figure out the length, or that he experimented with different offsets(?).

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The displacement in the article is wrong, it should be 10 bytes. When a function is called (or a jump is executed), the return address is set to equal the instruction pointer + the current instruction size:

ret = IP + Curr_Inst_size

So when the call to the function returns, the instruction pointer should equal 0x80004a8 (0x80004a3 + the call instruction size):

    0x80004a3 <main+19>:    call   0x8000470 <function>
--> 0x80004a8 <main+24>:    addl   $0xc,%esp            
    0x80004ab <main+27>:    movl   $0x1,0xfffffffc(%ebp)
    0x80004b2 <main+34>:    movl   0xfffffffc(%ebp),%eax

However, you want to set the instruction pointer to 0x80004b2 instead, to skip the assignment, you also, inevitably, have to skip another instruction (addl $0xc,%esp) to get there, or in other words, you need to add (0x80004b2-0x80004a8) bytes, or 10 bytes, to the instruction pointer to skip those two instructions:

    0x80004a3 <main+19>:    call   0x8000470 <function>
    0x80004a8 <main+24>:    addl   $0xc,%esp            
    0x80004ab <main+27>:    movl   $0x1,0xfffffffc(%ebp)
--> 0x80004b2 <main+34>:    movl   0xfffffffc(%ebp),%eax 

The actual instruction size depends on the operands, machine type etc.. But in this example, the addl is 3 bytes long, and the movl is 7 bytes long. You could check the x86 Instruction Set Reference for the exact instruction size, or you could compile and disassemble this code, you will see that those two instructions are 10 bytes long:

int main()
    asm("addl  $0xc,%esp\n\
         movl  $0x1,0xfffffffc(%ebp)");



0x08048397 <+3>: 83 c4 0c               add    $0xc,%esp
0x0804839a <+6>: c7 45 fc 01 00 00 00   movl   $0x1,-0x4(%ebp)

There's also a discussion here and here about this exact same issue in example 3.

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up vote -1 down vote accepted

After much time and thinking I have finally solved the problem. The resource that helped me solve this is Stack smashing code not working on Linux kernel Please help

The biggest change that helped me resolve this was using disassembly-flavor intel for gdb.

Disassembled code (for reference):

0804840c <function>:
 804840c:   55                      push   ebp
 804840d:   89 e5                   mov    ebp,esp
 804840f:   83 ec 10                sub    esp,0x10
 8048412:   8d 45 f7                lea    eax,[ebp-0x9]
 8048415:   83 c0 14                add    eax,0x14
 8048418:   89 45 fc                mov    DWORD PTR [ebp-0x4],eax
 804841b:   8b 45 fc                mov    eax,DWORD PTR [ebp-0x4]
 804841e:   8b 00                   mov    eax,DWORD PTR [eax]
 8048420:   8d 50 05                lea    edx,[eax+0x5]
 8048423:   8b 45 fc                mov    eax,DWORD PTR [ebp-0x4]
 8048426:   89 10                   mov    DWORD PTR [eax],edx
 8048428:   c9                      leave  
 8048429:   c3                      ret    

0804842a <main>:
 804842a:   55                      push   ebp
 804842b:   89 e5                   mov    ebp,esp
 804842d:   83 e4 f0                and    esp,0xfffffff0
 8048430:   83 ec 20                sub    esp,0x20
 8048433:   c7 44 24 1c 00 00 00    mov    DWORD PTR [esp+0x1c],0x0
 804843a:   00 
 804843b:   c7 44 24 08 03 00 00    mov    DWORD PTR [esp+0x8],0x3
 8048442:   00 
 8048443:   c7 44 24 04 02 00 00    mov    DWORD PTR [esp+0x4],0x2
 804844a:   00 
 804844b:   c7 04 24 01 00 00 00    mov    DWORD PTR [esp],0x1
 8048452:   e8 b5 ff ff ff          call   804840c <function>
 8048457:   c7 44 24 1c 01 00 00    mov    DWORD PTR [esp+0x1c],0x1
 804845e:   00 
 804845f:   8b 44 24 1c             mov    eax,DWORD PTR [esp+0x1c]
 8048463:   89 44 24 04             mov    DWORD PTR [esp+0x4],eax
 8048467:   c7 04 24 18 85 04 08    mov    DWORD PTR [esp],0x8048518
 804846e:   e8 7d fe ff ff          call   80482f0 <printf@plt>
 8048473:   c9                      leave  
 8048474:   c3                      ret    
 8048475:   66 90                   xchg   ax,ax
 8048477:   66 90                   xchg   ax,ax
 8048479:   66 90                   xchg   ax,ax
 804847b:   66 90                   xchg   ax,ax
 804847d:   66 90                   xchg   ax,ax
 804847f:   90                      nop

There were two problems with my understanding on this:

A) My first problem was finding the amount of bytes to overrun ret inside function. Again; I did this by using intel syntax for disassembling and found that:

To set ret at the correct space in memory ret needs to be set to EIP when the function was called. The address space at 8048412 moves down the stack 0x9. Because this is 32-bit code; to get to ret we then add an additional 0x4 bytes for the word size. To get to ret that means that ret is set to 0x9 + 0x4 which is 13 in decimal.

This solves the first problem of getting to ret.

B) The second problem is skipping the 0x8048457 memory location. This is done by adding 7 bytes to (*ret) which makes the program skip and execute at 0x804845e which is 00 (NUL). This is just inefficient; so I added the additional byte and executed 8 bytes down the stack; thus resulting in x = 0;

I found the exact amount of bytes to be 8 (c7 44 24 1c 01 00 00 is 7 bytes) and 00 is one byte. This solved my last problem.

My modified C code:

void function(int a, int b, int c) {
        char buffer1[5];
        int *ret;

        ret = buffer1 + 13; //tried 11, 14, 20, 40, 38, 43
        (*ret) += 8; // tried 5, 8, 12; 8 is correct value!

void main() {
        int x;
        x = 0;
        x = 1;
        printf("%d\n", x);
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you realize that this just solves the problem on your machine, and does not explain why the displacement was 8 bytes in the article ? which was your question. –  mux Oct 23 '12 at 5:45
Yes, I believe I said that. That is why I included the disassembled code and C code for anyone else who comes across this problem in the future; that way they have something to reference. –  josten Oct 23 '12 at 5:58
you should accept an answer if you think it answers your question :) of course it's up to you, I'm just pointing that out. –  mux Oct 23 '12 at 6:04
I cant accept my own yet. –  josten Oct 23 '12 at 6:04
but your own answer doesn't answer the question, which was why the displacement was 8 bytes in the article, which was a wrong displacement, I believe, anyway, whatever helps you understand better. –  mux Oct 23 '12 at 6:08

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