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I have a question about the EXCEPTION_INT_OVERFLOW and EXCEPTION_INT_DIVIDE_BY_ZERO exceptions.

Windows will trap the #DE errors generated by the IDIV instruction and will end up generating and SEH exception with one of those 2 codes.

The question I have is how does it differentiate between the two conditions? The information about idiv in the Intel manual indicates that it will generate #DE in both the "divide by zero" and "underflow cases".

I took a quick look at the section on the #DE error in Volume 3 of the intel manual, and the best I could gather is that the OS must be decoding the DIV instruction, loading the divisor argument, and then comparing it to zero.

That seems a little crazy to me though. Why would the chip designers not use a flag of some sort to differentiate between the 2 causes of the error? I feel like I must be missing something.

Does anyone know for sure how the OS differentiates between the 2 different causes of failure?

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Do you have any documentation indicating that IDIV even can produce EXCEPTION_INT_OVERFLOW? I understand that INT_MIN / -1 is problematic, but the description of EXCEPTION_INT_OVERFLOW doesn't appear to include this case. – Ben Voigt Feb 15 '11 at 2:59
@Ben I verified it experimentally. When I do INT_MIN / -1 , the IDIV instruction results in an EXCEPTION_INT_OVERFLOW, and when I do INT_MIN/0 I get EXCEPTION_INT_DIVIDE_BY_ZERO. In both case the exception is thrown after attempted exececution of the IDIV instruction. – Scott Wisniewski Feb 15 '11 at 3:09
@Scott: Hmmm... MSDN documentation fail. Not that there's anything unusual about that. – Ben Voigt Feb 15 '11 at 3:11
@Ben I think the MSDN documentation does cover it. For example it says "The result of an integer operation caused a carry out of the most significant bit of the result." – Scott Wisniewski Feb 15 '11 at 3:16
@Scott: What "carry" is taking place? I've reported the shortcoming to MSDN feedback. – Ben Voigt Feb 15 '11 at 3:18
up vote 5 down vote accepted

Your assumptions appear to be correct. The only information available on #DE is CS and EIP, which gives the instruction. Since the two status codes are different, the OS must be decoding the instruction to determine which.

I'd also suggest that the chip makers don't really need two separate interrupts for this case, since anything divided by zero is infinity, which is too big to fit into your destination register.

As for "knowing for sure" how it differentiates, all of those who do know are probably not allowed to reveal it, either to prevent people exploiting it (not entirely sure how, but jumping into kernel mode is a good place to start looking to exploit) or making assumptions based on an implementation detail that may change without notice.

Edit: Having played with kd I can at least say that on the particular version of Windows XP (32-bit) I had access to (and the processor it was running on) the nt!Ki386CheckDivideByZeroTrap interrupt handler appears to decode the ModRM value of the instruction to determine whether to return STATUS_INTEGER_DIVIDE_BY_ZERO or STATUS_INTEGER_OVERFLOW.

(Obviously this is original research, is not guaranteed by anyone anywhere, and also happens to match the deductions that can be made based on Intel's manuals.)

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I'm not really looking for anything, other than to understand how it's implemented. I know it can be implemented by manually decoding the instruction and loading the argument but that just seems like a strange way to do it. – Scott Wisniewski Feb 15 '11 at 3:13
@Scott Since the processor doesn't provide any way to detect it apart from decoding the instructions, there is no alternative. The Intel docs say that no state modification occurs, and EIP isn't even advanced past the instruction. I imagine there's more than once case where this is relevant (illegal opcode is the most likely) and in any case, decoding a ModRM value isn't that hard - there'll be a function in the kernel that does it. – Zooba Feb 15 '11 at 5:39
I know it isn't hard. It just seems an efficient way to do it. Perhaps its not that bad, when compared to doing a stack walk. In any case, I read that page (the one about #DE)in the Intel Manual and thought "they must be decoding the instruction, that's interesting". I wanted to know if that's what it was really doing though. – Scott Wisniewski Feb 15 '11 at 12:34
@Scott I haven't traced it completely, but it seems that nt!Ki386CheckDivideByZeroTrap is the function you're looking for (at least on Windows XP 32-bit). Early on the default return value is set to STATUS_INTEGER_DIVIDE_BY_ZERO, followed by quite a large switch statement which appears to be decoding the instruction to find the divisor and testing whether or not it is actually zero. (I hope I haven't breached too many licences by doing that...) – Zooba Feb 15 '11 at 21:09
Thanks a bunch! – Scott Wisniewski Feb 15 '11 at 23:42

Zooba's answer summarizes the Windows parses the instruction to find out what to raise.

But you cannot rely on that the routine correctly chooses the code.

I observed the following on 64 bit Windows 7 with 64 bit DIV instructions:

  • If the operand (divisor) is a memory operand it always raises EXCEPTION_INT_DIVIDE_BY_ZERO, regardless of the argument value.
  • If the operand is a register and the lower dword is zero it raises EXCEPTION_INT_DIVIDE_BY_ZERO regardless if the upper half isn't zero.

Took me a day to find this out... Hope this helps.

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