Several of the answers here and the code injection article you linked to in your answer cover chunks of what I consider the optimal
gdb-oriented solution, but none of them pull it all together or cover all the points. The code-expression of the solution is a bit long, so here's a summary of the important steps:
- Load the code to inject. Most of the answers posted here use what I consider the best approach -- call
dlopen() in the inferior process to link in a shared library containing the injected code. In the article you linked to the author instead loaded a relocatable object file and hand-linked it against the inferior. This is quite frankly insane -- relocatable objects are not "ready-to-run" and include relocations even for internal references. And hand-linking is tedious and error-prone -- far simpler to let the real runtime dynamic linker do the work. This does mean getting
libdl into the process in the first place, but there are many options for doing that.
- Create a detour. Most of the answers posted here so far have involved locating the PLT entry for the function of interest, using that to find the matching GOT entry, then modifying the GOT entry to point to your injected function. This is fine up to a point, but certain linker features -- e.g., use of
dlsym -- can circumvent the GOT and provide direct access to the function of interest. The only way to be certain of intercepting all calls to a particular function is overwrite the initial instructions of that function's code in-memory to create a "detour" redirecting execution to your injected function.
- Create a trampoline (optional). Frequently when doing this sort of injection you'll want to call the original function whose invocation you are intercepting. The way to allow this with a function detour is to create a small code "trampoline" which includes the overwritten instructions of the original function then a jump to the remainder of the original. This can be complex, because any IP-relative instructions in the copied set need to be modified to account for their new addresses.
- Automate it all. These steps can be tedious, even if doing some of the simpler solutions posted in other answers. The best way to ensure that the steps are done correctly every time with variable parameters (injecting different functions, etc) is to automate their execution. Starting with the 7.0 series,
gdb has included the ability to write new commands in Python. This support can be used to implement a turn-key solution for injecting and detouring code in/to the inferior process.
Here's an example. I have the same
b executables as before and an
inject2.so created from the following code:
int (*rand__)(void) = NULL;
int result = rand__();
printf("rand invoked! result = %d\n", result);
return result % 47;
I can then place my Python
detour command in
detour.py and have the following
(gdb) source detour.py
(gdb) exec-file a
(gdb) set follow-fork-mode child
(gdb) catch exec
Catchpoint 1 (exec)
Starting program: /home/llasram/ws/detour/a
[New process 8500]
process 8500 is executing new program: /home/llasram/ws/detour/b
[Switching to process 8500]
Catchpoint 1 (exec'd /home/llasram/ws/detour/b), 0x00007ffff7ddfaf0 in _start ()
(gdb) break main
Breakpoint 2 at 0x4005d0: file b.c, line 7.
Breakpoint 2, main (argc=1, argv=0x7fffffffdd68) at b.c:7
(gdb) detour libc.so.6:rand inject2.so:rand inject2.so:rand__
rand invoked! result = 392103444
Program exited normally.
In the child process, I create a detour from the
rand() function in
libc.so.6 to the
rand() function in
inject2.so and store a pointer to a trampoline for the original
rand() in the
rand__ variable of
inject2.so. And as expected, the injected code calls the original, displays the full result, and returns that result modulo 47.
Due to length, I'm just linking to a pastie containing the code for my
detour command. This is a fairly superficial implementation (especially in terms of the trampoline generation), but it should work well in a large percentage of cases. I've tested it with
gdb 7.2 (most recently released version) on Linux with both 32-bit and 64-bit executables. I haven't tested it on OS X, but any differences should be relatively minor.