I've been working on a custom PE
binfmt handler for Ubuntu Linux 12.04, Intel x86_64 architecture (if this sounds familiar, I've posted a few questions related to this project already). I'll apologize in advance if the amount of information I'm giving is overkill.
binfmt handler is pretty standard; I read in the PE headers and sections and then write those sections into userspace memory at the addresses specified in the section table. Then, when everything is ready, I call
start_thread(regs, entry_addr, current->mm->start_stack);
exactly like the built-in Linux handlers do; in my case,
regs = 0xcf7dffb4,
entry_addr = 0x401000, and
start_stack = 0xbffff59b.
I have the following code, in Intel x86 assembly:
push ebp mov ebp, esp mov eax, 4 add eax, 5 pop ebp ret
I compile this program with fasm to a PE format executable (math1.exe) and install my
binfmt handler with
insmod. If I debug this program in
gdb, I see:
(gdb) set disassembly-flavor intel (gdb) x/6i 0x401000 0x401000: push ebp 0x401001: mov ebp,esp 0x401003: mov eax,0x4 0x401008: add eax,0x5 0x40100b: pop ebp 0x40100c: ret
so I know the code is loaded to the correct address. Then:
(gdb) run Starting program: /media/sf_Sandbox/math1.exe Program received signal SIGSEGV, Segmentation fault. 0x0040100c in ?? ()
When I do a register dump:
(gdb) info registers eax 0x9 9 ecx 0x81394e8 135501032 edx 0x8137808 135493640 ebx 0x8139548 135501128 esp 0xbfffe59b 0xbfffe59b ebp 0x0 0x0 esi 0x81394e8 135501032 edi 0x2f7ff4 3112948 eip 0x40100c 0x40100c ...other registers...
You can see that the code did execute because
eax = 0x9, as it should. On the surface, I can't find any reason for this to segfault at the
ret statement, though. Examining
dmesg, I found
math1.exe general protection ip:40100c sp:bffff5bd error:0
but I've found very little documentation on what might be causing this. I know the problem isn't the code itself, because the same code compiled with the same assembler to ELF format runs with no trouble whatsoever.
My current theories about this problem are:
- I don't really mess with the stack pointer in my handler. The built-in Linux handlers (for ELF, a.out, and flat formats, to name three) have a function
create_*_tables()that processes the
envparguments. I didn't include this function at first because the test program doesn't take any input, but implementing the
create_flat_tables()function (from the flat handler) doesn't solve the problem so far. (I know that blindly pasting and calling functions from other modules is a bad idea, but the a.out and flat versions of that function are essentially identical, so it doesn't seem to be very dependent on the executable format; I thought I'd give it a try.)
- I found this article about the chain of function calls that occurs prior to and following the execution of
objdumpof math1.exe contains only the assembly code given above, but the
objdumpof the same program after assembly to ELF format (which yields a
*.ofile) and linking with
gcc(to get an ELF binary) contains the other functions mentioned in the article (
__libc_start_main(), etc.). Perhaps those functions are more mandatory on the Linux platform than I previously thought.
I'm looking for any explanations/suggestions/further troubleshooting steps I could take. Thanks in advance!