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Can the program counter on Intel CPUs can be read directly (that is without 'tricks') in kernel mode or some other mode?

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    Related: Why can't you set the instruction pointer directly?. You can; the instruction is called jmp. My answer there explains why x86 machine code was designed so you can't encode a mov to eip, the way you can on ARM where PC is one of the general-purpose integer registers. Mar 23, 2018 at 11:23

7 Answers 7

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No, EIP / IP cannot be accessed directly, but in position-dependent code it's a link-time constant so you can use a nearby (or distant) symbol as an immediate.

   mov eax, nearby_label    ; in position-dependent code
nearby_label:

To get EIP or IP in position-independent 32-bit code:

        call _here
_here:  pop eax
; eax now holds the PC.

On CPUs newer than Pentium Pro (or PIII probably), call rel32 with rel32=0 is special-cased to not affect the return-address predictor stack. So this is efficient as well as compact on modern x86, and is what clang uses for 32-bit position-independent code.

On old 32-bit Pentium Pro CPUs, this would unbalance the call/return predictor stack, so prefer calling a function that does actually return, to avoid branch mispredicts on up to 15 or so future ret instructions in your parent functions. (Unless you're not going to return, or so rarely that it doesn't matter.) The return-address predictors stack will recover, though.

get_retaddr_ppro:
    mov  eax, [esp]
    ret                ; keeps the return-address predictor stack balanced
                       ; even on CPUs where  call +0 isn't a no-op.

In x86-64 mode, RIP can be read directly using a RIP-relative lea.

default rel           ; NASM directive: use RIP-relative by default

lea  rax, [_here]     ; RIP + 0
_here:

MASM or GNU .intel_syntax: lea rax, [rip]

AT&T syntax: lea 0(%rip), %rax

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    This code actually screws up the return value branch prediction and slows you down quite a lot. I'll try to find a reference for this... Mar 1, 2009 at 16:25
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    Don't know why this is the accepted answer over TrayMan's answer. TrayMan's version has no unexpected side effects and is shorter.
    – Skizz
    Jun 26, 2009 at 8:30
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    ptlsim.org/Documentation/html/node31.html has a good description on "return address stack"
    – mfazekas
    Apr 23, 2010 at 12:22
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    Re: This code actually screws up the return value branch prediction ... I'll try to find a reference for this... - the reference is "Intel's 64-ia-32 optimization manual" -> 3.4.1.4 Inlining, Calls and Returns -> "The return address stack mechanism augments the staticand dynamic predictors to optimize specifically for calls and returns. It holds 16 entries, which is large enough to cover the call depth of most programs. ... To enable the use of the return stack mechanism, calls and returns must be matched in pairs"
    – Xtra Coder
    Dec 16, 2013 at 6:36
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    @AdamRosenfield it's here blogs.msdn.microsoft.com/oldnewthing/20041216-00/?p=36973
    – phuclv
    Dec 6, 2016 at 6:54
28

If you need the address of a specific instruction, usually something like this does the trick:

thisone: 
   mov (e)ax,thisone

(Note: On some assemblers this might do the wrong thing and read a word from [thisone], but there's usually some syntax for getting the assembler to do the right thing.)

If your code is statically loaded to a specific address, the assembler already knows (if you told it the right starting address) the absolute addresses of all instructions. Dynamically loaded code, say as a part of an application on any modern OS, will get the right address thanks to address relocation done by the dynamic linker (provided the assembler is smart enough to generate the relocation tables, which they usually are).

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On x86-64 you can do for example:

lea rax,[rip] (48 8d 05 00 00 00 00)
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  • Thanks! What's the meaning of the numbers? Jun 26, 2009 at 14:26
  • thats the instruction encoding - theres an implicit 32-bit offset which is 0, i'm not sure if there is a shorter encoding
    – matja
    Jun 26, 2009 at 17:59
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    lea rax, [rip] did not work in NASM 2.10. It seems that RIP can only be used indirectly with rel as in lea rax, [rel _start]? May 10, 2015 at 21:31
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There is no instruction to directly read the instruction pointer (EIP) on x86. You can get the address of the current instruction being assembled with a little inline assembly:

// GCC inline assembler; for MSVC, syntax is different
uint32_t eip;
__asm__ __volatile__("movl $., %0", : "=r"(eip));

The . assembler directive gets replaced with the address of the current instruction by the assembler. Note that if you wrap the above snippet in a function call, you'll just get the same address (within that function) every time. If you want a more usable C function, you can instead use some non-inline assembly:

// In a C header file:
uint32_t get_eip(void);

// In a separate assembly (.S) file:
.globl _get_eip
_get_eip:
    mov 0(%esp), %eax
    ret

This means each time you want to get the instruction pointer, it's slightly less efficient since you need an extra function call. Note that doing it this way does not blow the return address stack (RAS). The return address stack is a separate stack of return addresses used internally by the processor to facilitate branch target prediction for RET instructions.

Every time you have a CALL instruction, the current EIP gets pushed onto the RAS, and every time you have a RET instruction, the RAS is popped, and the top value is used as the branch target prediction for that instruction. If you mess up the RAS (such as by not matching each CALL with a RET, as in Cody's solution), you're going to get a whole bunch of unnecessary branch mispredictions, slowing your program down. This method does not blow the RAS, since it has a matched pair of CALL and RET instructions.

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  • Many thanks for the info, I didn't know there were two stacks.. :) Mar 1, 2009 at 18:02
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    The RAS is an internal stack used by the processor; it's not accessible to code in any way. It's only used for branch target prediction. Without it, code would still function correctly, just more slowly. Mar 1, 2009 at 18:08
  • Thanks you so much. Does RAS mess up if you manually set the ESP after Push? Mar 8, 2009 at 8:11
  • Or to just get the address of the current function uintptr_t func_addr = (uintptr_t)&function_name;. On x86 C/C++ implementations, function pointers are simply code addresses. This will assemble to whatever is needed. Nov 19, 2017 at 21:52
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There is an architecture independent (but gcc dependent) way of accessing the address which is being executed by using labels as values:

http://gcc.gnu.org/onlinedocs/gcc/Labels-as-Values.html

void foo()
{
  void *current_address = $$current_address_label;
  current_address_label:
      ....
}
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    This isn't exactly assembly :-) Jun 14, 2012 at 9:09
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    it should be &&current_address_label, not $$
    – phuclv
    Jul 6, 2014 at 7:35
  • Isn't this a relative address (not IP)? Nov 19, 2017 at 20:54
  • @PeterMortensen: IDK what anyone can useful do with the address of some code inside a C function, but this seems just as good as the asm("movl $., %0", : "=r"(eip)) answer (if not better, because this one will work in PIC code, too. In that case, the compiler will have to use a RIP-relative LEA or a 32-bit PIC method of getting static addresses, but it will match EIP when execution passes through that label, unless you've copied code around in a way that broke static addressing.) Nov 19, 2017 at 21:56
0

You can also read this from /proc/stat. Check the proc manpages.

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  • I think you mean /proc/self/stat, it would also be cool to quote the manpage. May 12, 2015 at 8:21
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    /proc/self/stat there is a field according to man proc(5): kstkeip %lu : The current EIP (instruction pointer).
    – Paul Praet
    May 13, 2015 at 9:29
  • Can you expand this answer? E.g. including some context (is this for Linux only?) and consider the information in the other comments. Nov 19, 2017 at 20:53
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    If you do this the "normal" way, won't you always get the address of the syscall instruction in libc's read() function? Doesn't seem useful for finding out your own EIP/RIP value. Nov 19, 2017 at 21:29
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There is a simple way to change the program counter (eip)

When you call a function with 'call' the eip is pushed in the stack then when you ret the eip is just poped from the stack . so , all what you have to do is to push the value you want and then ret . for example:

mov eax, 0x100
push eax`
ret

and it's done.

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