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I've inherited some clever x64 machine code for GNU/Linux that creates a machine code wrapper around a c-function call. I guess that in higher language terms the code might be called a decorator or a closure. The code is functioning well, but with the unfortunate artifact that when the wrapper is called, it gobbles the stack trace in gdb.

From what I have learned from the net gdb uses https://en.wikipedia.org/wiki/DWARF as a guide for separating the stack frames in the stack. This works well for static code, but obviously code generated and called at run time isn't registered in the DWARF framework.

My question is if there is any way to rescue the stack trace in this situation?

Here is some similar c-code that shows the problem.

typedef int (*ftype)(int x);
int wuz(int x) { return x + 7; }
int wbar(int x) { return wuz(x)+5; }
int main(int argc, char **argv)
{
  const unsigned char wbarcode[] = {
    0x55 ,                            //  push   %rbp
    0x48,0x89,0xe5 ,                  //  mov    %rsp,%rbp
    0x48,0x83,0xec,0x08 ,             //  sub    $0x8,%rsp
    0x89,0x7d,0xfc ,                  //  mov    %edi,-0x4(%rbp)
    0x8b,0x45,0xfc ,                  //  mov    -0x4(%rbp),%eax
    0x89,0xc7 ,                       //  mov    %eax,%edi
    0x48,0xc7,0xc0,0xf6,0x04,0x40,00, // mov    $0x4004f6,%rax
    0xff,0xd0,                        //  callq  *%rax
    0x83,0xc0,0x05 ,                  //  add    $0x5,%eax
    0xc9 ,                            //  leaveq
    0xc3                              //  retq
  };

  int wb = wbar(5);
  ftype wf = (ftype)wbarcode;
  int fwb = wf(5);
}

Compile it by:

gcc -g -o mcode mcode.c
execstack -s mcode

and run it in gdb by:

$ gdb mcode
(gdb) break wuz

If we disassemble wbar we get something very similar to the byte sequence in wbarcode[]. The only difference is that I changed the calling convention for calling wuz().

(gdb) disas/r wbar
Dump of assembler code for function wbar:
   0x0000000000400505 <+0>: 55      push   %rbp
   0x0000000000400506 <+1>: 48 89 e5        mov    %rsp,%rbp
   0x0000000000400509 <+4>: 48 83 ec 08     sub    $0x8,%rsp
   0x000000000040050d <+8>: 89 7d fc        mov    %edi,-0x4(%rbp)
   0x0000000000400510 <+11>:        8b 45 fc        mov    -0x4(%rbp),%eax
   0x0000000000400513 <+14>:        89 c7   mov    %eax,%edi
   0x0000000000400515 <+16>:        e8 dc ff ff ff  callq  0x4004f6 <wuz>
   0x000000000040051a <+21>:        83 c0 05        add    $0x5,%eax
   0x000000000040051d <+24>:        c9      leaveq
   0x000000000040051e <+25>:        c3      retq
End of assembler dump.

If we now run the program it will stop twice in wuz(). The first time through our c-call and we can ask for a stack trace through bt.

Breakpoint 3, wuz (x=5) at mcode.c:2
=> 0x00000000004004fd <wuz+7>:    8b 45 fc    mov    -0x4(%rbp),%eax
   0x0000000000400500 <wuz+10>:    83 c0 07    add    $0x7,%eax
   0x0000000000400503 <wuz+13>:    5d    pop    %rbp
   0x0000000000400504 <wuz+14>:    c3    retq
(gdb) bt
#0  wuz (x=5) at mcode.c:2
#1  0x000000000040051a in wbar (x=5) at mcode.c:3
#2  0x00000000004005b0 in main (argc=1, argv=0x7fffffffe528) at mcode.c:20

This is a normal stack trace showing that we got from main()wbar()wuz().

But if we now continue we reach wuz() a second time, and we again request a stack trace:

(gdb) c
Continuing.

Breakpoint 3, wuz (x=5) at mcode.c:2
=> 0x00000000004004fd <wuz+7>:    8b 45 fc    mov    -0x4(%rbp),%eax
   0x0000000000400500 <wuz+10>:    83 c0 07    add    $0x7,%eax
   0x0000000000400503 <wuz+13>:    5d    pop    %rbp
   0x0000000000400504 <wuz+14>:    c3    retq
(gdb) bt
#0  wuz (x=5) at mcode.c:2
#1  0x00007fffffffe419 in ?? ()
#2  0x0000000500000001 in ?? ()
#3  0x00007fffffffe440 in ?? ()
#4  0x00000000004005c6 in main (argc=0, argv=0xffffffff) at mcode.c:22
Backtrace stopped: frame did not save the PC

Even though we have done the same two hierarchical calls, we get a stack trace that contains the wrong frames. In my original inherited wrapper code the situation was even worse, as the the stack trace ended after 5 frames with the top level having address 0.

So the question is again, is there any extra code that can be added to wbarcode[] that will cause gdb to output a valid stacktrace? Or is there any other run time technique that may be used to make gdb recognize the stack frames?

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  • Hmm, the wbarcode dynamically-generated function does make a traditional stack frame (pushing %rbp). I guess that doesn't help if the caller was compiled with the default -fomit-frame-pointer, though, because the caller of wbarcode probably won't be keeping it's %rsp-on-entry in %rbp. What happens if you compile the whole thing with -fno-omit-frame-pointer? IDK if there would still be a .eh_frame_hdr section that gdb would still want to use... Jan 22, 2016 at 7:20
  • Not sure this is clever code since it uses a hard coded address in the encoded assembler. Jan 22, 2016 at 7:21
  • @MichaelPetch: he said this is just a MCVE, not that it's actually anything like his actual dynamically-generated function. Jan 22, 2016 at 7:22
  • @MichaelPetch: Yes, a MCVE. Unfortunately -fno-omit-frame-pointer doesn't help. Regarding a .eh_frame_hdr section, it can't help since it is static, whereas the code is dynamically generated at runtime. Jan 22, 2016 at 7:40
  • @DovGrobgeld: I meant if there was no .eh_frame_hdr section, then gcc might fall back to the old-fashioned way of walking the linked-list of stack frames that results from all functions using the standard push %rbp / mov %rsp, %rbp prologue. Jan 22, 2016 at 7:54

1 Answer 1

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On some architectures, you can just make the frame have the layout that is expected by gdb's default unwinder for that port. However, this isn't available on all architectures. Reading the x86-64 port (see gdb/amd64-tdep.c, in particular the function amd64_frame_cache_1), I think here gdb wants to know the function bounds, so it can try to analyze the prologue. But, the function bounds come from the (ELF) symbol table, so you're out of luck there.

There's still a way, though. Due to the recent (in gdb terms) rise of JIT compilers, gdb provides three other ways to deal with this problem.

One way is that your program can emit a special ELF object (really any object format that gdb understands, IIRC) in memory, and call a runtime hook to inform gdb of its existence. gdb will read this object, including any debug information it contains. This approach is rather heavy, but gives access to most of gdb's capabilities -- you can specify not just the unwinding but also types, local variables, etc.

A second way is somewhat similar. Your program still calls a special hook. However, you also provide a plugin that is loaded by gdb. This plugin can read symbols and other information from the inferior, but in this case the symbols and unwind information don't have to be in any particular format.

The final way (new in gdb 7.10) is that you can write an unwinder in Python. When working on my JIT unwinder, I chose this approach because it is simple to debug, simple to deploy, reasonably flexible, and does not require any particular changes in the inferior.

These methods are all documented in the gdb manual. In some cases, though, I think the documentation leaves a bit to be desired. You may have to find some example code or dig into the gdb sources to really understand how it's supposed to work.

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