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I am trying to understand how Mach-o files work, and have made a good deal of progress with the online resources available (In particular, the Apple page here: http://developer.apple.com/library/mac/#documentation/developertools/conceptual/MachORuntime/Reference/reference.html), but I have hit a roadblock on understanding how symbol stubs work.

Using "otool -l" I see the following section:

Section
  sectname __symbolstub1
   segname __TEXT
      addr 0x00005fc0
      size 0x00000040
    offset 20416
     align 2^2 (4)
    reloff 0
    nreloc 0
     flags 0x80000408

However when I look at the data from the binary file in a hex editor I see the following 4 bytes repeated again and again:

00005FC0  38 F0 9F E5 38 F0 9F E5  38 F0 9F E5 38 F0 9F E5  88
00005FD0  38 F0 9F E5 38 F0 9F E5  38 F0 9F E5 38 F0 9F E5  88
00005FE0  38 F0 9F E5 38 F0 9F E5  38 F0 9F E5 38 F0 9F E5  88  
00005FF0  38 F0 9F E5 38 F0 9F E5  38 F0 9F E5 38 F0 9F E5  88

This looks something like a LDR which increases the PC by a fixed amount, but I don't see why the amount is the same for each entry in the symbol table.

If someone can shed light on why this is so, or provide any resources that get this low level, please let me know.

Thanks!

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I think I figured out what is going on, each of the 4-byte entries in the table is pointing to a data region below which has a DCD instruction which stores the location of the function call. However I'm still a bit confused why this extra level of indirection is required, so if anyone can provide follow info I'd appreciate it. –  Locksleyu Jan 11 '12 at 19:48

1 Answer 1

up vote 7 down vote accepted

I will describe the situation with the current iOS, it's somewhat different in the old versions.

The symbol stubs indeed load into the PC a function pointer. For the standard "lazy" (on-demand) imports, the pointer resides in the __lazy_symbol section and initially points to a helper routine in the __stub_helper section, e.g.:

__symbolstub1 _AudioServicesAddSystemSoundCompletion
__symbolstub1 LDR  PC, _AudioServicesAddSystemSoundCompletion$lazy_ptr
__symbolstub1 ; End of function _AudioServicesAddSystemSoundCompletion

__lazy_symbol _AudioServicesAddSystemSoundCompletion$lazy_ptr DCD _AudioServicesAddSystemSoundCompletion$stubHelper

__stub_helper _AudioServicesAddSystemSoundCompletion$stubHelper
__stub_helper LDR R12, =nnn ; symbol info offset in the lazy bind table
__stub_helper B   dyld_stub_binding_helper

The function dyld_stub_binding_helper is the fist one in the __stub_helper section and essentially is just a trampoline to the dyld_stub_binder function in dyld, passing to it what I call "symbol info offset" value. That value is an offset inside the lazy binding info stream (pointed to by the LC_DYLD_INFO or LC_DYLD_INFO_ONLY load command), which is a sort of bytecode stream with commands for dyld. Typical sequence for a lazy import looks like this:

72: BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB(M, 0xYYYYY)
19: BIND_OPCODE_SET_DYLIB_ORDINAL_IMM(NNNN)
40: BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM(0x00, '_AudioServicesAddSystemSoundCompletion')
90: BIND_OPCODE_DO_BIND()

here dyld would do the following:

  1. look up function named '_AudioServicesAddSystemSoundCompletion' from a dylib number NNNN in the list of dylibs listed in the load commands.
  2. look up the executable's segment number M (most likely __DATA)
  3. write the function pointer at the offset YYYYY.
  4. jump to the looked up address so that the actual function does its job

The address written to happens to be the _AudioServicesAddSystemSoundCompletion$lazy_ptr slot. So, the next time the _AudioServicesAddSystemSoundCompletion is called, it will jump directly to the imported function, without going via dyld.

N.B.: you should not look at the offset 05fc0 in the file right away. The addr field is the virtual address, you should look up the containing segment command and see at what VA it starts and what is its file offset, then do the math. Usually the __TEXT segment starts at 1000.

However, the actual symbol stubs do look like you pasted, probably you have a fat mach-o with the fat header taking the first 1000 bytes, so the offsets line up.

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+1. Slow clap, standing ovation. Fantastic answer. I learnt a lot from that! –  mattjgalloway Jan 12 '12 at 14:58
    
Wow, amazing answer! I have to read it through a few times before I can fully understand, but Igor please tell me one thing. Where did you get this knowledge? By reading all the relevant ASM or is this documented fully anywhere? Thanks! –  Locksleyu Jan 12 '12 at 20:22
    
Mostly from the binaries, yes. However, in theory you can figure it out from the source code too - see Apple's sources for dyld, ld64 and Csu. –  Igor Skochinsky Jan 12 '12 at 20:28
    
Igor, I see that (as you mentioned) the lazy symbol section points to helper routines, but the documentation plus otool's output implies that __lazy_symbol is somehow pointing to the indirect symbol table, indexed by the reserved2 field (which is 16 in my case). I looked at the data in the indirect symbol table + 16 but I just see values like 0x0000001a, 0x0000001e, etc., and I'm not sure what these refer to. Could you please explain? Thanks! –  Locksleyu Jan 12 '12 at 21:06
2  
The names are encoded in a trie (prefix tree) structure, see here for a good description. –  Igor Skochinsky Jan 17 '12 at 17:56

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