Say I have the following C code:

int32_t foo(int32_t x) {
    return x + 1;

This is undefined behavior when x == INT_MAX. Now say I performed the addition with inline assembly instead:

int32_t foo(int32_t x) {
    asm("incl %0" : "+g"(x));
    return x;

Question: Does the inline assembly version still invoke undefined behavior when x == INT_MAX? Or does undefined behavior only apply to the C code?

  • it should set the overflow flag causing undefined behavior. If uint then flag wouldn't be set
    – Turtle
    Nov 12, 2016 at 17:51
  • Why do you suppose it does not invoke ub when it's asm? (Really asking)
    – LotoLo
    Nov 12, 2016 at 17:52
  • It doesn't have to be, you can test the overflow flag in your assembly code. What you'll do when it is set is still undefined :) You can't return from the function so you'll have to terminate the program. Which is roughly the reason that C made it UB, it was a lot easier that way. There are safeint libraries around that do this. Matters in critical fail-safe code, you can't launch a rocket with raw C code. Nov 12, 2016 at 17:55
  • 2
    The asm keyword is a compiler extension (§J.5.10). So anything and everything you do with inline assembly is implementation defined. Nov 12, 2016 at 18:33
  • 2
    @PeterCordes: Allowing compilers to treat the result of overflow as non-deterministically holding the arithmetically-correct value, a "wrapped" value, or any other mathematical integer which would wrap to the same value, is useful. Thus, given long long x, x+1>y could be changed to x>=y since in the overflow case the expression x+1 would be allowed to behave as though it held a value one larger than the max value of a long long. Nearly all of the useful optimizations I've seen based on overflow being UB would still be available under that model, but...
    – supercat
    Nov 13, 2016 at 0:59

2 Answers 2


No, there's no UB with this. C rules don't apply to the asm instructions themselves. As far as the inline-asm syntax wrapping the instructions, that's a well-defined language extension that has defined behaviour on implementations that support it.

See Does undefined behavior apply to asm code? for a more generic version of this question (vs. this one about x86 assembly and the GNU C inline asm language extension). The answers there focus on the C side of things, with quotes from the C and C++ standards that document how little the standard has to say about implementation-defined extensions to the language.

See also this comp.lang.c thread for arguments about whether it makes sense to say it has UB "in general" because not all implementations have that extension.

BTW, if you just want signed wraparound with defined 2's complement behaviour in GNU C, compile with -fwrapv. Don't use inline asm. (Or use an __attribute__ to enable that option for just the function that needs it.) wrapv is not quite the same thing as -fno-strict-overflow, which merely disables optimizations based on assuming the program doesn't have any UB; for example, overflow in compile-time-constant calculations is only safe with -fwrapv.

Inline-asm behaviour is implementation defined, and GNU C inline asm is defined as a black box for the compiler. Inputs go in, outputs come out, and the compiler doesn't know how. All it knows is what you tell it using the out/in/clobber constraints.

Your foo that uses inline-asm behaves identically to

int32_t foo(int32_t x) {
    uint32_t u = x;
    return ++u;

on x86, because x86 is a 2's complement machine, so integer wraparound is well-defined. (Except for performance: the asm version defeats constant propagation, and also gives the compiler no ability to optimize x - inc(x) to -1, etc. etc. https://gcc.gnu.org/wiki/DontUseInlineAsm unless there's no way to coax the compiler into generating optimal asm by tweaking the C.)

It doesn't raise exceptions. Setting the OF flag has no impact on anything, because GNU C inline asm for x86 (i386 and amd64) has an implicit "cc" clobber, so the compiler will assume that the condition codes in EFLAGS hold garbage after every inline-asm statement. gcc6 introduced a new syntax for asm to produce flag results (which can save a SETCC in your asm and a TEST generated by the compiler for asm blocks that want to return a flag condition).

Some architectures do raise exceptions (traps) on integer overflow, but x86 is not one of them (except when a division quotient doesn't fit in the destination register). On MIPS, you'd use ADDIU instead of ADDI on signed integers if you wanted them to be able to wrap without trapping. (Because it's also a 2's complement ISA, so signed wraparound is the same in binary as unsigned wraparound.)

Undefined (or at least implementation-dependent) Behaviour in x86 asm:

BSF and BSR (find first set bit forward or reverse) leave their destination register with undefined contents if the input was zero. (TZCNT and LZCNT don't have that problem). Intel's recent x86 CPUs do define the behaviour, which is to leave the destination unmodified, but the x86 manuals don't guarantee that. See the section on TZCNT in this answer for more discussion on the implications, e.g. that TZCNT/LZCNT/POPCNT have a false dependency on the output in Intel CPUs.

Several other instructions leave some flags undefined in some/all cases. (especially AF/PF). IMUL for example leaves ZF, PF, and AF undefined.

Presumably any given CPU has consistent behaviour, but the point is that other CPUs might behave differently even though they're still x86. If you're Microsoft, Intel will design their future CPUs to not break your existing code. If your code is that widely-relied-on, you'd better stick to only relying on behaviour documented in the manuals, not just what your CPU happens to do. See Andy Glew's answer and comments here. Andy was one of the architects of Intel's P6 microarchitecture.

These examples are not the same thing as UB in C. They're more like what C would call "implementation defined", since we're just talking about one value that's unspecified, not the possibility of nasal demons. (Or the more plausible modifying other registers, or jumping somewhere).

For really undefined behaviour, you probably need to look at privileged instructions, or at least multi-threaded code. Self-modifying code is also potentially UB on x86: it's not guaranteed that the CPU "notices" stores to addresses that are about to be executed until after a jump instruction. This was the subject of the question linked above (and the answer is: real implementations of x86 go above and beyond what the x86 ISA manual requires, to support code that depends on it, and because snooping all the time is better for high-performance than flushing on jumps.)

Undefined behaviour in assembly language is pretty rare, especially if you don't count cases where a specific value is unspecified but the scope of the "damage" is predictable and limited.

  • 1
    Very well explained, thank you! I actually didn't know about the implicit cc clobber (I left it out by mistake, to be honest :-p); if anyone is curious you can find it at the end of the ix86_md_asm_adjust function in the GCC source code.
    – Andrew Sun
    Nov 12, 2016 at 20:03
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    @AndrewSun: re: "cc" clobbers: See also stackoverflow.com/questions/21541968/…. Also, I was digging in the mailing list archives of x86-64.org last year and came across a thread where they were deciding whether amd64 inline-asm would have the same implicit "cc" clobber, and they decided that yes, cost in missed optimizations is negligible since most asm statements would need it. And having it not be implicit had huge downsides in bugs. This was 15 years before gcc6 flag output were a thing. :P Nov 12, 2016 at 20:17
  • 1
    There is a huge difference between loading a register with an Unspecified value, versus Undefined Behavior. Some processors (e.g. DEC Alpha) have a category of Unpredictable behavior which is more constrained than Undefined Behavior, in that the former will remain bound by things like memory permissions, while the latter might not. Note that any Alpha instruction which could invoke Undefined behavior will trap unless executed from supervisor mode; user-mode instructions yield at worst Unspecified behavior.
    – supercat
    Nov 13, 2016 at 1:07
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    @PeterCordes: Since some platforms may not be able to efficiently support certain kinds of system programming, but could nonetheless usefully process many other kinds of C programs, the authors of the Standard didn't require that implementations provide everything needed to make system programming practical, but figured those implementations which could practically provide such features (e.g. the ability to safely perform relational comparisons on arbitrary pointers) would do so. If a piece of kernel code is supposed to be robust against being passed deliberately-malformed arguments, ...
    – supercat
    Nov 30, 2016 at 20:17
  • 1
    ...having a compiler omit certain checks on the basis that certain things "couldn't" happen would be decidedly unhelpful. At a certain level, security code needs to be able to see things as they actually are, not just as the compiler thinks they should be.
    – supercat
    Nov 30, 2016 at 20:20

Well, the C Standard doesn't define what inline assembler does, so any inline assembler is undefined behaviour according to the C Standard.

You are using a slightly different language "C with x86 32 bit inline assembler". You generated a valid assembler statement. The behaviour is presumably defined by Intel's reference manuals. And there the behaviour of an integer addition adding 1 to INT_MAX is well defined. It's defined in a way that it doesn't interfere with execution of your C program.

Inline assembler that tried to read a value via a null pointer would also be well defined on the assembler level, but it's behaviour would interfere with the execution of your program (a.k.a. crashing it).

  • A better way to put the first sentence would be that inline asm is implementation-defined behaviour. Although implementations can define behaviour for things that the C standard say is UB, if they want. (e.g. signed overflow). Nov 12, 2016 at 23:59
  • @PeterCordes asm("incl %0" : "+g"(x)); is absolutely UB. C does not specify asm as some ID. It is UB by omission. ID refers to code that all compliant compliers handle in some implementation way. A compliant compiler need not handle asm. Nov 13, 2016 at 3:15
  • @chux: We're talking about the GNU dialect of the C language, where asm is a keyword and signed overflow (with C operators) is UB (without -fwrapv), exactly like in ISO C11. Would you be happier if the OP had used __asm__, which GNU C compilers will accept even with -std=c11 (as opposed to -std=gnu11)? Nov 13, 2016 at 3:22
  • @PeterCordes It is not a question of my happiness. "C rules don't apply to the asm instructions." misleads. C defines the C language, not a GNU dialect of the C language. asm is UB per C. Of course it may be OK with GNU dialect of the C or other dialects. __asm__ is not specified the C spec either. Just because code is well specified by one complier does not make it OK for all C compliant compilers. Nov 13, 2016 at 3:32
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    @PeterCordes: C89 includes a list of "Common extensions" and doesn't say that such extensions, despite being common, are non-conforming. Combined with the requirement that extensions be documented, I think one could reasonably infer that the intention is that conforming implementations may extend the language in the indicated fashions provided that they document that they are doing so. That isn't how the Standard is interpreted nowadays, but would be consistent with common practices in the early 1990s.
    – supercat
    Nov 30, 2016 at 20:26

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