0

I am reading a book, Hacking: The Art of Exploitation 2nd Edition, and I'm at the chapter of format string vulnerability. I read the chapter multiple times but I'm unable to clearly understand it, even with some googling.

So, in the book there is this vulnerable code:

 char text[1024];
...
 strcpy(text, argv[1]);
 printf("The right way to print user-controlled input:\n");
 printf("%s", text);
 printf("\nThe wrong way to print user-controlled input:\n");
 printf(text);

Then after compiling,

reader@hacking:~/booksrc $ ./fmt_vuln $(perl -e 'print "%08x."x40')
The right way to print user-controlled input:
%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.
%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.
%08x.%08x.
The wrong way to print user-controlled input:
bffff320.b7fe75fc.00000000.78383025.3830252e.30252e78.252e7838.2e783830.78383025.3830252e.30252
e78.252e7838.2e783830.78383025.3830252e.30252e78.252e7838.2e783830.78383025.3830252e.30252e78.2
52e7838.2e783830.78383025.3830252e.30252e78.252e7838.2e783830.78383025.3830252e.30252e78.252e78
38.2e783830.78383025.3830252e.30252e78.252e7838.2e783830.78383025.3830252e.

The bytes 0x25, 0x30, 0x38, 0x78, and 0x2e seem to be repeating a lot.

reader@hacking:~/booksrc $ printf "\x25\x30\x38\x78\x2e\n"
%08x.

First, why is that value repeating itself?

As you can see, they’re the memory for the format string itself. Because the format function will always be on the highest stack frame, as long as the format string has been stored anywhere on the stack, it will be located below the current frame pointer (at a higher memory address).

But it seems to me this contradicts what he previously wrote and the way stack frames are organized

When this printf() function is called (as with any function), the arguments are pushed to the stack in reverse order.

So, shouldn't the format string be at a lower memory address since it is the first argument? And where is the format string stored?

reader@hacking:~/booksrc $ ./fmt_vuln AAAA%08x.%08x.%08x.%08x
The right way to print user-controlled input:
AAAA%08x.%08x.%08x.%08x
The wrong way to print user-controlled input:
AAAAbffff3d0.b7fe75fc.00000000.41414141

Here again, why is AAAA repeated in 41414141. From what I understand, the printf function prints AAAA first, then when it sees the first %08x, it gets a value from a memory address in the preceding stack frame, then does the same with the second %08x, thus the value of the second is located in a memory address higher than the first one, and finally returns to the value of AAAA located in a lower memory address, in the stack frame of printf function.

I debugged the first example with $(perl -e 'print "%08x."x40') as argument. I run: Linux 5.3.0-40-generic, 18.04.1-Ubuntu, x86_64

(gdb) run $(perl -e 'print "%08x." x 40')
Starting program: /home/kuro/fmt_vuln $(perl -e 'print "%08x." x 40')
The right way to print user-controlled input:
%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.%08x.
The wrong way to print user-controlled input:
07a51260.4b3eb8c0.4b10e154.00000000.4b16c3a0.9d357fc8.9d357b10.78383025.30252e78.2e783830.3830252e.252e7838.78383025.30252e78.2e783830.3830252e.252e7838.78383025.30252e78.2e783830.3830252e.252e7838.78383025.30252e78.2e783830.3830252e.252e7838.78383025.30252e78.2e783830.3830252e.252e7838.4b618d00.4b5fd000.00000000.9d357c80.00000000.00000000.00000000.4b3ef6f0.

Breakpoint 1, main (argc=2, argv=0x7ffd9d357fc8) at fmt_vuln.c:19
19      printf("[*] test_val @ 0x%08x = %d 0x%08x\n", &test_val, test_val, test_val);
(gdb) x/-100xw $rsp
0x7ffd9d357940: 0x00000400  0x00000000  0x4b07c1aa  0x00007fb8
0x7ffd9d357950: 0x00000016  0x00000000  0x00000003  0x00000000
0x7ffd9d357960: 0x00000001  0x00000000  0x00002190  0x000003e8
0x7ffd9d357970: 0x00000005  0x00000000  0x00008800  0x00000000
0x7ffd9d357980: 0x00000000  0x00000000  0x00000400  0x00000000
0x7ffd9d357990: 0x00000000  0x00000000  0x5e970730  0x00000000
0x7ffd9d3579a0: 0x65336234  0x30663666  0x90890300  0x79e57be9
0x7ffd9d3579b0: 0x1cd79dbf  0x00000000  0x00000000  0x00000000
0x7ffd9d3579c0: 0x05cec660  0x000055ef  0x9d357fc0  0x00007ffd
0x7ffd9d3579d0: 0x00000000  0x00000000  0x00000000  0x00000000
0x7ffd9d3579e0: 0x9d357ee0  0x00007ffd  0x4b062f26  0x00007fb8
0x7ffd9d3579f0: 0x00000030  0x00000030  0x9d357be8  0x00007ffd
0x7ffd9d357a00: 0x9d357a10  0x00007ffd  0x90890300  0x79e57be9
0x7ffd9d357a10: 0x4b3ea760  0x00007fb8  0x07a51260  0x000055ef
0x7ffd9d357a20: 0x4b3eb8c0  0x00007fb8  0x4b0891bd  0x00007fb8
0x7ffd9d357a30: 0x00000000  0x00000000  0x4b3ea760  0x00007fb8
0x7ffd9d357a40: 0x00000d68  0x00000000  0x00000169  0x00000000
0x7ffd9d357a50: 0x07a51260  0x000055ef  0x4b08af51  0x00007fb8
0x7ffd9d357a60: 0x4b3e62a0  0x00007fb8  0x4b3ea760  0x00007fb8
0x7ffd9d357a70: 0x0000000a  0x00000000  0x05cec660  0x000055ef
0x7ffd9d357a80: 0x9d357fc0  0x00007ffd  0x00000000  0x00000000
0x7ffd9d357a90: 0x00000000  0x00000000  0x4b08b403  0x00007fb8
0x7ffd9d357aa0: 0x4b3ea760  0x00007fb8  0x9d357ee0  0x00007ffd
0x7ffd9d357ab0: 0x05cec660  0x000055ef  0x4b0808f5  0x00007fb8
0x7ffd9d357ac0: 0x00000000  0x00000000  0x05cec824  0x000055ef
(gdb) x/100xw $rsp
0x7ffd9d357ad0: 0x9d357fc8  0x00007ffd  0x9d357b10  0x00000002
0x7ffd9d357ae0: 0x78383025  0x3830252e  0x30252e78  0x252e7838
0x7ffd9d357af0: 0x2e783830  0x78383025  0x3830252e  0x30252e78
0x7ffd9d357b00: 0x252e7838  0x2e783830  0x78383025  0x3830252e
0x7ffd9d357b10: 0x30252e78  0x252e7838  0x2e783830  0x78383025
0x7ffd9d357b20: 0x3830252e  0x30252e78  0x252e7838  0x2e783830
0x7ffd9d357b30: 0x78383025  0x3830252e  0x30252e78  0x252e7838
0x7ffd9d357b40: 0x2e783830  0x78383025  0x3830252e  0x30252e78
0x7ffd9d357b50: 0x252e7838  0x2e783830  0x78383025  0x3830252e
0x7ffd9d357b60: 0x30252e78  0x252e7838  0x2e783830  0x78383025
0x7ffd9d357b70: 0x3830252e  0x30252e78  0x252e7838  0x2e783830
0x7ffd9d357b80: 0x78383025  0x3830252e  0x30252e78  0x252e7838
0x7ffd9d357b90: 0x2e783830  0x78383025  0x3830252e  0x30252e78
0x7ffd9d357ba0: 0x252e7838  0x2e783830  0x4b618d00  0x00007fb8
0x7ffd9d357bb0: 0x4b5fd000  0x00007fb8  0x00000000  0x00000000
0x7ffd9d357bc0: 0x9d357c80  0x00007ffd  0x00000000  0x00000000
0x7ffd9d357bd0: 0x00000000  0x00000000  0x00000000  0x00000000
0x7ffd9d357be0: 0x4b3ef6f0  0x00007fb8  0x4b6184c8  0x00007fb8
0x7ffd9d357bf0: 0x9d357c80  0x00007ffd  0x4b3ef000  0x00007fb8
0x7ffd9d357c00: 0x4b3ef914  0x00007fb8  0x4b3ef3c0  0x00007fb8
0x7ffd9d357c10: 0x4b617048  0x00007fb8  0x00000000  0x00000000
0x7ffd9d357c20: 0x00000000  0x00000000  0x4b6179f0  0x00007fb8
0x7ffd9d357c30: 0x4b0030e8  0x00007fb8  0x00000000  0x00000000
0x7ffd9d357c40: 0x4b3efa00  0x00007fb8  0x00000480  0x00000000
0x7ffd9d357c50: 0x00000027  0x00000000  0x00000000  0x00000000

The values, that appear before "%08x." in the Wrong way output, appear in lower addresses than "%08x." values. Why? The format string is supposed to be at the top of the stack.

The values, that appear after the "%08x." values in the Wrong way output, appear in higher addresses than"%08x." values. So in the preceding stack.

Why is it like this? Shouldn't the output begin from the format string values, or after?

Also, in the book, it doesn't print values after "%08x." values. But some are printed in my case. And some values in the output don't even figure in the stack, like 4b16c3a0.

6
  • 1
    Have you tried looking at stack memory in a debugger? The whole point of parts of the book that you quoted and the source you posted, is to demonstrate that you should never allow an untrusted user to input a format string into your code. When the author talks about the stack, its an abstract model. How that maps to memory is architecture dependent. Top of the stack is always the last thing pushed, which may be higher or lower than whatever was pushed prior, depending on the architecture.
    – jwdonahue
    Commented Apr 14, 2020 at 22:45
  • I debugged, and I even more confused. I edited the question to include the debugging.
    – Eye Patch
    Commented Apr 15, 2020 at 13:34
  • 1
    Do you know how variable arguments work, and how argument passing works in your platform? You may be interested in looking up the term "calling conventions". Note that printf("%s", string") copies string verbatim, while printf(string) passes string as a format string, so it parses and execute any format directives in it.
    – Oppen
    Commented Apr 15, 2020 at 14:13
  • 1
    Why are you doing this in Perl? You have a C tag and no perl tag. Perl isn't C. It's an interpreted language, there could be all sorts of run-time cruft on the stack. I don't see where you've compiled anything. What architecture are you running on?
    – jwdonahue
    Commented Apr 15, 2020 at 18:05
  • 1
    Looking up the term may help you get a more formal idea, but you're already in the right track with the things you said. Keep in mind that even when printf has its own frame, the stack itself is shared with the caller.
    – Oppen
    Commented Apr 15, 2020 at 21:02

1 Answer 1

3

I have to recommend against what you're doing. You're focussing on security vulnerabilities in C without a strong understanding of the language itself. That's an exercise in frustration. As evidence, I offer that every question you're posing about the exercise is answered by understanding printf(3), not stack vulnerabilities.

The output of your perl line (the contents of argv[1]) starts with, %08x.%08x.%08x.%08x.%08x. Thats a format string. Each %08x is looking for a further printf argument, an integer to print in hex representation. Normally, you might do something like,

int a = 'B';
printf( "%02x\n", a );

which produces 42 much faster than the computer in the Hitchhiker's Guide to the Galaxy.

What you've done is pass a long format string with zero arguments. printf(3) can't know how many arguments it was passed; it has to infer them from the format string. Your format string tells printf to print a long list of integers. Since none were provided, it looks for them "up the stack" (wherever they should have been). You print nonsense because the contents of those memory locations is unpredictable. Or, at any rate, weren't defined by you.

In the "good" case, the format string is "%s", declaring one argument of type string, which you provided. That works much better, yes.

Most compilers nowadays take special care with printf. They can produce warnings if the format string isn't a compile-time constant, and they can verify that each argument is of the correct type for its corresponding format specifier. The whole chapter in your book can thus be made moot simply by using the compiler's capabilities and paying attention to its diagnostics.

2
  • "Most compilers nowadays take special care with printf. They can produce warnings if the format string isn't a compile-time constant, and they can verify that each argument is of the correct type for its corresponding format specifier. The whole chapter in your book can thus be made moot simply by using the compiler's capabilities and paying attention to its diagnostics." That's true from a defensive point of view, but an attacker can still bite the unwary.
    – Oppen
    Commented Apr 15, 2020 at 21:04
  • Okay. However, 'it looks for them "up the stack" (wherever they should have been)', the place where they should have has a higher memory address because, in the "good case" they are pushed to the stack before the format string. So why does it print a value in a lower memory address like in "0x7ffd9d357a50".
    – Eye Patch
    Commented Apr 15, 2020 at 21:14

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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