8

I came across this code and need to understand what it is doing. It just seems to be declaring two bytes and then doing nothing...

uint64_t x;
__asm__ __volatile__ (".byte 0x0f, 0x31" : "=A" (x));

Thanks!

3
  • Interesting. It's been so long since I've looked at any of this, I'm not sure. You might specify what assembler you are using. I don't know if this is setting the content, the address, or both (!) of "x". It wouldn't surprise me if x points at a memory mapped port, updated by a device asynchronously, and thus the "volatile" keyword. Somebody who actually does this stuff will turn up soon, I suppose.
    – Roboprog
    Aug 13, 2009 at 17:27
  • 2
    Bet you wish the original programmer used comments! Aug 13, 2009 at 17:43
  • Easiest way: just compile it and then disassemble it. Jun 27, 2016 at 16:55

4 Answers 4

12

This is generating two bytes (0F 31) directly into the code stream. This is an RDTSC instruction, which reads the time-stamp counter into EDX:EAX, which will then be copied to the variable 'x' by the output constraint "=A"(x)

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  • Ah ok!! And the "=A" (x) syntax (I am using gcc4.1) to use %eax and %edx together - will it work on x86_64 arch? I think so but I dont know much about assembly.
    – MK.
    Aug 13, 2009 at 17:36
  • Yes -- the 'A' constraint means a 64-bit value in the EDX:EAX register pair in both i386 and x86_64 gcc machine descriptions
    – Chris Dodd
    Aug 14, 2009 at 19:49
  • @MK. and Chris: No, in 64bit code a uint64_t given an "=A" constraint will actually just choose one of rax or rdx, like if you'd used "=ad". It doesn't split values into two equal halves for you :( This version that ORs together the low and high half compiles to optimal code for -m32 and -m64, because in 32bit code the OR optimizes away. Jun 27, 2016 at 16:54
  • @PeterCordes: It used to work in older versions of gcc, but I guess they broke the A constraint in more recent versions.
    – Chris Dodd
    Jun 27, 2016 at 17:13
4

0F 31 is the x86 opcode for the RDTSC (read time stamp counter) instruction; it places the value read into the EDX and EAX registers.

The _ _ asm__ directive isn't just declaring two bytes, it's placing inline assembly into the C code. Presumably, the program has a way of using the value in those registers immediately afterwards.

http://en.wikipedia.org/wiki/Time_Stamp_Counter

2

It's inserting an 0F 31 opcode, which according to this site is:

0F 31   P1+   f2   RDTSC EAX EDX IA32_T...        Read Time-Stamp Counter 

Then it is storing the result in the x variable

1

It's inline asm for rdtsc, with the machine-code encoding written out to support really old assemblers that don't know the mnemonic.

Unfortunately, it only works correctly in 32bit code because "=A" doesn't split 64bit operands in half in 64bit code. (The gcc manual even uses rdtsc an an example to illustrate this)

The safe way to write this, which compiles to optimal code with gcc -m32 or -m64, is:

#include <stdint.h>
uint64_t timestamp_safe(void)
{
  unsigned long tsc_low, tsc_high;   // not uint32_t: saves a zero-extend for -m64 (but not x32 :/)
  asm volatile("rdtsc"  : "=d"(tsc_high), "=a" (tsc_low));
  return ((uint64_t)tsc_high << 32) | tsc_low;
}

In 32bit code, it's just rdtsc/ret, but in 64bit code it does the necessary shift/or to get both halves into rax for the return value.

See it on the Godbolt compiler explorer.

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