8

I want a simple C method to be able to run hex bytecode on a Linux 64 bit machine. Here's the C program that I have:

char code[] = "\x48\x31\xc0";
#include <stdio.h>
int main(int argc, char **argv)
{
        int (*func) ();
        func = (int (*)()) code;
        (int)(*func)();
        printf("%s\n","DONE");
}

The code that I am trying to run ("\x48\x31\xc0") I obtained by writting this simple assembly program (it's not supposed to really do anything)

.text
.globl _start
_start:
        xorq %rax, %rax

and then compiling and objdump-ing it to obtain the bytecode.

However, when I run my C program I get a segmentation fault. Any ideas?

  • 5
    Even if your data segment is executable or you don't have NX enabled, what do you expect this to do? It executes one instruction and then the instruction afterwards (which you don't control) and then the instruction after that, until it reaches memory which doesn't represent legitimate code or code that triggers a segfault. – Niklas B. Mar 31 '12 at 23:55
  • 1
    You will need to add byte code for a ret because the indirect function call you do should be a call which pushes the return address onto the stack. Atleast, this is my best educated guess, I have never seen anything like this. – Chris Mar 31 '12 at 23:56
  • I expect this to do nothing, but I want it to be able to run without crashing. – Nosrettap Mar 31 '12 at 23:58
  • 2
    Do you mind about the \0 at the end of the string ? – BenjaminB Apr 1 '12 at 0:04
  • char code[] = "\x48\x31\xc0\xc3\0"; – LXSoft Jul 23 '14 at 12:14
16

You need the page containing the machine code to have execute permission. x86-64 page tables have a separate bit for execute separate from read permission, unlike legacy 386 page tables.

Here is a simple example:

#include <stdio.h>
#include <string.h>
#include <sys/mman.h>

int main ()
{
  char code[] = {
    0x8D, 0x04, 0x37,           //  lea eax,[rdi+rsi]       // retval = a+b;                    
    0xC3                        //  ret                                         
  };

  int (*sum) (int, int) = NULL;

  // copy code to executable buffer                                             
  sum = mmap (0,sizeof(code),PROT_READ|PROT_WRITE|PROT_EXEC,
              MAP_PRIVATE|MAP_ANON,-1,0);
  memcpy (sum, code, sizeof(code));

  // doesn't actually flush cache on x86
  // but is still necessary so memcpy isn't optimized away as a dead store.
  __builtin___clear_cache(sum, sum + sizeof(sum));  // GNU C

  // run code                                                                   
  int a = 2;
  int b = 3;
  int c = sum (a, b);

  printf ("%d + %d = %d\n", a, b, c);

  return 0;
}
  • Yes, the ret is important to return back into the calling function. – Chris Apr 1 '12 at 19:22
  • 2
    Thanks for the help. I just want to add that objdump -d <filename> can get you the byte code for an executable. – Jeff Oct 24 '13 at 19:00
  • static const char code[] is normally linked into the text segment of your executable, which is already mapped read-only + executable. You don't actually need to copy it. (Making it non-const would be a problem, though; the data segment isn't always executable.) The important part of this answer vs. the question is the ret. See also Why does const int main = 195 result in a working program but without the const it ends in a segmentation fault?. (195 = 0xC3 = ret). – Peter Cordes Jul 24 '18 at 15:24
  • This technique is independent of where the machine code comes from. I included a fragment known at compile time for simplicity, but the concept works with machine code generated at runtime, which is the main use case. You are quick to comment but I think you missed the point. – Antoine Mathys Jul 24 '18 at 18:01
  • 1
    @MaximEgorushkin and Antoine: update: This answer is still fine, but my static const code[] = ... suggestion is no longer sufficient. Current (2019) GNU Binutils ld now links .rodata into a separate segment that is read only without exec permission. It's still easier to use gcc -z execstack or mprotect() than to mmap+memcpy, though. I added an answer of my own with full details + working examples. – Peter Cordes Apr 28 at 19:23
4

Your machine code may be all right, but your CPU objects.

Modern CPUs manage memory in segments. In normal operation, the operating system loads a new program into a program-text segment and sets up a stack in a data segment. The operating system tells the CPU never to run code in a data segment. Your code is in code[], in a data segment. Thus the segfault.

3

You need to include the assembly in-line via a special compiler directive so that it'll properly end up in a code segment. See this guide, for example: http://www.ibiblio.org/gferg/ldp/GCC-Inline-Assembly-HOWTO.html

2

This will take some effort.

Your code variable is stored in the .data section of your executable:

$ readelf -p .data exploit

String dump of section '.data':
  [    10]  H1À

H1À is the value of your variable.

The .data section is not executable:

$ readelf -S exploit
There are 30 section headers, starting at offset 0x1150:
Section Headers:
  [Nr] Name              Type             Address           Offset
       Size              EntSize          Flags  Link  Info  Align
[...]
  [24] .data             PROGBITS         0000000000601010  00001010
       0000000000000014  0000000000000000  WA       0     0     8

All 64-bit processors I'm familiar with support non-executable pages natively in the pagetables. Most newer 32-bit processors (the ones that support PAE) provide enough extra space in their pagetables for the operating system to emulate hardware non-executable pages. You'll need to run either an ancient OS or an ancient processor to get a .data section marked executable.

Because these are just flags in the executable, you ought to be able to set the X flag through some other mechanism, but I don't know how to do so. And your OS might not even let you have pages that are both writable and executable.

0

You may need to set the page executable before you may call it. On MS-Windows, see the VirtualProtect -function.

URL: http://msdn.microsoft.com/en-us/library/windows/desktop/aa366898%28v=vs.85%29.aspx

0

Two problems:

  • exec permission on the page, because you used an array that will go in the noexec read+write .data section.
  • your machine code doesn't end with a ret instruction so even if it did run, execution would fall into whatever was next in memory instead of returning.

And BTW, the REX prefix is totally redundant. "\x31\xc0" xor eax,eax has exactly the same effect as xor rax,rax.


You need the page containing the machine code to have execute permission. x86-64 page tables have a separate bit for execute separate from read permission, unlike legacy 386 page tables.

The easiest way to get static arrays to be in read+exec memory is to compile with gcc -z execstack. (Makes the stack and other section executable).

Until recently (2018 or 2019), the standard toolchain (binutils ld) would put section .rodata into the same ELF segment as .text, so they'd both have read+exec permission. Thus using const char code[] = "..."; was sufficient for executing manually-specified bytes as data.

But on my Arch Linux system with GNU ld (GNU Binutils) 2.31.1, that's no longer the case. readelf -a shows that the .rodata section went into an ELF segment with .eh_frame_hdr and .eh_frame, and it only has Read permission. .text goes in a segment with Read + Exec, and .data goes in a segment with Read + Write (along with the .got and .got.plt). (What's the difference of section and segment in ELF file format)

#include <stdio.h>

// can be non-const if you use gcc -z execstack.  static is also optional
static const char code[] = {
  0x8D, 0x04, 0x37,           //  lea eax,[rdi+rsi]       // retval = a+b;                    
  0xC3                        //  ret                                         
};

static const char ret0_code[] = "\x31\xc0\xc3";   // xor eax,eax ;  ret
                     // the compiler will append a 0 byte to terminate the C string,
                     // but that's fine.  It's after the ret.

int main () {
  // void* cast is easier to type than a cast to function pointer,
  // and in C can be assigned to any other pointer type.  (not C++)

  int (*sum) (int, int) = (void*)code;
  int (*ret0)(void) = (void*)ret0_code;

  // run code                                                                   
  int c = sum (2, 3);
  return ret0();
}

On older Linux systems: gcc -O3 shellcode.c && ./a.out (Works because of const on global/static arrays)

On older and current Linux: gcc -O3 -z execstack shellcode.c && ./a.out (works because of -zexecstack regardless of where your machine code is stored). Also works with clang -z execstack. gcc allows -zexecstack with no space, but clang doesn't.

These also work on Windows, where read-only data goes in .rdata instead of .rodata.

The compiler-generated main looks like this (from objdump -drwC -Mintel). You can run it inside gdb and set breakpoints on code and ret0_code

(I actually used   gcc -no-pie -O3 -zexecstack shellcode.c  hence the addresses near 401000
0000000000401020 <main>:
  401020:       48 83 ec 08             sub    rsp,0x8           # stack aligned by 16 before a call
  401024:       be 03 00 00 00          mov    esi,0x3
  401029:       bf 02 00 00 00          mov    edi,0x2           # 2 args
  40102e:       e8 d5 0f 00 00          call   402008 <code>     # note the target address in the next page
  401033:       48 83 c4 08             add    rsp,0x8
  401037:       e9 c8 0f 00 00          jmp    402004 <ret0_code>    # optimized tailcall

Or use system calls to modify page permissions

Instead of compiling with gcc -zexecstack, you can instead use mmap(PROT_EXEC) to allocate new executable pages, or mprotect(PROT_EXEC) to change existing pages to executable. (Including pages holding static data.) You also typically want at least PROT_READ and sometimes PROT_WRITE, of course.

Using mprotect on a static array means you're still executing the code from a known location, maybe making it easier to set a breakpoint on it.

On Windows you can use VirtualAlloc or VirtualProtect.

In GNU C, you also need to use __builtin___clear_cache(buf, buf + len) after writing machine code bytes to a buffer, because the optimizer doesn't treat dereferencing a function pointer as reading bytes from that address. Dead-store elimination can remove the stores of machine code bytes into a buffer, if the compiler proves that the store isn't read as data by anything. https://codegolf.stackexchange.com/questions/160100/the-repetitive-byte-counter/160236#160236 and https://godbolt.org/g/pGXn3B has an example where gcc really does do this optimization, because gcc "knows about" malloc.

(And on non-x86 architectures where I-cache isn't coherent with D-cache, it actually will do any necessary cache syncing. On x86 it's purely a compile-time optimization blocker.)

My edit on @AntoineMathys's answer added this. gcc doesn't currently know about mmap, so it does happen to not optimize away the store into the pointer returned by mmap.

But you don't need it after mprotect on a page holding read-only C variables.

#include <stdio.h>
#include <sys/mman.h>
#include <stdint.h>

// can be non-const if you want, we're using mprotect
static const char code[] = {
  0x8D, 0x04, 0x37,           //  lea eax,[rdi+rsi]       // retval = a+b;                    
  0xC3                        //  ret                                         
};

static const char ret0_code[] = "\x31\xc0\xc3";

int main () {
  // void* cast is easier to type than a cast to function pointer,
  // and in C can be assigned to any other pointer type.  (not C++)
  int (*sum) (int, int) = (void*)code;
  int (*ret0)(void) = (void*)ret0_code;

   // hard-coding x86's 4k page size for simplicity.
   // also assume that `code` doesn't span a page boundary and that ret0_code is in the same page.
  uintptr_t page = (uintptr_t)code & -4095ULL;                  // round down
  mprotect((void*)page, 4096, PROT_READ|PROT_EXEC|PROT_WRITE);  // +write in case the page holds any writeable C vars that would crash later code.

  // run code                                                                   
  int c = sum (2, 3);
  return ret0();
}

I used PROT_READ|PROT_EXEC|PROT_WRITE in this example so it works regardless of where your variable is. If it was a local on the stack and you left out PROT_WRITE, call would fail after making the stack read only when it tried to push a return address.

Also, PROT_WRITE lets you test shellcode that self-modifies, e.g. to edit zeros into its own machine code, or other bytes it was avoiding.

$ gcc -O3 shellcode.c           # without -z execstack
$ ./a.out 
$ echo $?
0
$ strace ./a.out
...
mprotect(0x55605aa3f000, 4096, PROT_READ|PROT_WRITE|PROT_EXEC) = 0
exit_group(0)                           = ?
+++ exited with 0 +++

If I comment out the mprotect, it does segfault.

If I did something like ret0_code[2] = 0xc3;, I would need __builtin___clear_cache(ret0_code+2, ret0_code+2) after that to make sure the store wasn't optimized away, but if I don't modify the static arrays then it's not needed after mprotect. It is needed after mmap+memcpy or manual stores, because we want to execute bytes that have been written in C (with memcpy).

  • @AntoineMathys: The other reason is to test out a snippet of shellcode to make sure you've correctly turned an assembly program into part of an exploit payload. If you were JITing, you wouldn't have a C string like the OP's "\x48\x31\xc0", you'd just have bytes. – Peter Cordes Apr 29 at 17:15

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