Why is f(i = -1, i = -1) undefined behavior?

I was reading about order of evaluation violations, and they give an example that puzzles me.

1) If a side effect on a scalar object is un-sequenced relative to another side effect on the same scalar object, the behavior is undefined.

``````// snip
f(i = -1, i = -1); // undefined behavior
``````

In this context, `i` is a scalar object, which apparently means

Arithmetic types (3.9.1), enumeration types, pointer types, pointer to member types (3.9.2), std::nullptr_t, and cv-qualified versions of these types (3.9.3) are collectively called scalar types.

I don’t see how the statement is ambiguous in that case. It seems to me that regardless of if the first or second argument is evaluated first, `i` ends up as `-1`, and both arguments are also `-1`.

UPDATE

I really appreciate all the discussion. So far, I like @harmic’s answer a lot since it exposes the pitfalls and intricacies of defining this statement in spite of how straight forward it looks at first glance. @acheong87 points out some issues that come up when using references, but I think that's orthogonal to the unsequenced side effects aspect of this question.

SUMMARY

Since this question got a ton of attention, I will summarize the main points/answers. First, allow me a small digression to point out that "why" can have closely related yet subtly different meanings, namely "for what cause", "for what reason", and "for what purpose". I will group the answers by which of those meanings of "why" they addressed.

for what cause

The main answer here comes from Paul Draper, with Martin J contributing a similar but not as extensive answer. Paul Draper's answer boils down to

It is undefined behavior because it is not defined what the behavior is.

The answer is overall very good in terms of explaining what the C++ standard says. It also addresses some related cases of UB such as `f(++i, ++i);` and `f(i=1, i=-1);`. In the first of the related cases, it's not clear if the first argument should be `i+1` and the second `i+2` or vice versa; in the second, it's not clear if `i` should be 1 or -1 after the function call. Both of these cases are UB because they fall under the following rule:

If a side effect on a scalar object is unsequenced relative to another side effect on the same scalar object, the behavior is undefined.

Therefore, `f(i=-1, i=-1)` is also UB since it falls under the same rule, despite that the intention of the programmer is (IMHO) obvious and unambiguous.

Paul Draper also makes it explicit in his conclusion that

Could it have been defined behavior? Yes. Was it defined? No.

which brings us to the question of "for what reason/purpose was `f(i=-1, i=-1)` left as undefined behavior?"

for what reason / purpose

Although there are some oversights (maybe careless) in the C++ standard, many omissions are well-reasoned and serve a specific purpose. Although I am aware that the purpose is often either "make the compiler-writer's job easier", or "faster code", I was mainly interested to know if there is a good reason leave `f(i=-1, i=-1)` as UB.

harmic and supercat provide the main answers that provide a reason for the UB. Harmic points out that an optimizing compiler that might break up the ostensibly atomic assignment operations into multiple machine instructions, and that it might further interleave those instructions for optimal speed. This could lead to some very surprising results: `i` ends up as -2 in his scenario! Thus, harmic demonstrates how assigning the same value to a variable more than once can have ill effects if the operations are unsequenced.

supercat provides a related exposition of the pitfalls of trying to get `f(i=-1, i=-1)` to do what it looks like it ought to do. He points out that on some architectures, there are hard restrictions against multiple simultaneous writes to the same memory address. A compiler could have a hard time catching this if we were dealing with something less trivial than `f(i=-1, i=-1)`.

davidf also provides an example of interleaving instructions very similar to harmic's.

Although each of harmic's, supercat's and davidf' examples are somewhat contrived, taken together they still serve to provide a tangible reason why `f(i=-1, i=-1)` should be undefined behavior.

I accepted harmic's answer because it did the best job of addressing all meanings of why, even though Paul Draper's answer addressed the "for what cause" portion better.

JohnB points out that if we consider overloaded assignment operators (instead of just plain scalars), then we can run into trouble as well.

• A scalar object is an object of scalar type. See 3.9/9: "Arithmetic types (3.9.1), enumeration types, pointer types, pointer to member types (3.9.2), `std::nullptr_t`, and cv-qualified versions of these types (3.9.3) are collectively called scalar types." Feb 10 '14 at 7:12
• Maybe there's an error on the page, and they actually meant `f(i-1, i = -1)` or something similar. Feb 10 '14 at 8:41
• Take a look at this question: stackoverflow.com/a/4177063/71074 Feb 10 '14 at 10:34
• @RobKennedy Thanks. Does "arithmetic types" include bool? Feb 10 '14 at 14:25
• SchighSchagh your update should be in answer section. Feb 13 '14 at 5:32

Since the operations are unsequenced, there is nothing to say that the instructions performing the assignment cannot be interleaved. It might be optimal to do so, depending on CPU architecture. The referenced page states this:

If A is not sequenced before B and B is not sequenced before A, then two possibilities exist:

• evaluations of A and B are unsequenced: they may be performed in any order and may overlap (within a single thread of execution, the compiler may interleave the CPU instructions that comprise A and B)

• evaluations of A and B are indeterminately-sequenced: they may be performed in any order but may not overlap: either A will be complete before B, or B will be complete before A. The order may be the opposite the next time the same expression is evaluated.

That by itself doesn't seem like it would cause a problem - assuming that the operation being performed is storing the value -1 into a memory location. But there is also nothing to say that the compiler cannot optimize that into a separate set of instructions that has the same effect, but which could fail if the operation was interleaved with another operation on the same memory location.

For example, imagine that it was more efficient to zero the memory, then decrement it, compared with loading the value -1 in. Then this:

``````f(i=-1, i=-1)
``````

might become:

``````clear i
clear i
decr i
decr i
``````

Now i is -2.

It is probably a bogus example, but it is possible.

• Very nice example of how the expression could actually do something unexpected while conforming to sequencing rules. Yes, a bit contrived, but so is the code snipped I'm asking about in the first place. :) Feb 10 '14 at 8:00
• And even if the assignment is done as an atomic operation, it is possible to conceive of a superscalar architecture where both assignments are made simultaneously causing memory access conflict that results in a failure. The language is designed so that compiler writers have as much freedom as possible in using the advantages of the target machine.
– ach
Feb 10 '14 at 8:22
• I really like your example of how even assigning the same value to the same variable in both parameters could result in an unexpected result because the two assignments are unsequenced Feb 10 '14 at 11:17
• +1e+6 (ok, +1) for the point that compiled code isn't always what you would expect. Optimizers are really good at throwing these sorts of curves at you when you don't follow the rules :P Feb 11 '14 at 6:34
• On the Arm processor a load 32bit can take up to 4 instructions: It does `load 8bit immediate and shift` up to 4 times. Usually the compiler will do indirect addressing to fetch a number form a table to avoid this. (-1 can be done in 1 instruction, but another example could be chosen). Feb 11 '14 at 12:26

First, "scalar object" means a type like a `int`, `float`, or a pointer (see What is a scalar Object in C++?).

Second, it may seem more obvious that

``````f(++i, ++i);
``````

would have undefined behavior. But

``````f(i = -1, i = -1);
``````

is less obvious.

A slightly different example:

``````int i;
f(i = 1, i = -1);
std::cout << i << "\n";
``````

What assignment happened "last", `i = 1`, or `i = -1`? It's not defined in the standard. Really, that means `i` could be `5` (see harmic's answer for a completely plausible explanation for how this chould be the case). Or you program could segfault. Or reformat your hard drive.

But now you ask: "What about my example? I used the same value (`-1`) for both assignments. What could possibly be unclear about that?"

You are correct...except in the way the C++ standards committee described this.

If a side effect on a scalar object is unsequenced relative to another side effect on the same scalar object, the behavior is undefined.

They could have made a special exception for your special case, but they didn't. (And why should they? What use would that ever possibly have?) So, `i` could still be `5`. Or your hard drive could be empty. Thus the answer to your question is:

It is undefined behavior because it is not defined what the behavior is.

(This deserves emphasis because many programmers think "undefined" means "random", or "unpredictable". It doesn't; it means not defined by the standard. The behavior could be 100% consistent, and still be undefined.)

Could it have been defined behavior? Yes. Was it defined? No. Hence, it is "undefined".

That said, "undefined" doesn't mean that a compiler will format your hard drive...it means that it could and it would still be a standards-compliant compiler. Realistically, I'm sure g++, Clang, and MSVC will all do what you expected. They just wouldn't "have to".

A different question might be Why did the C++ standards committee choose to make this side-effect unsequenced?. That answer will involve history and opinions of the committee. Or What is good about having this side-effect unsequenced in C++?, which permits any justification, whether or not it was the actual reasoning of the standards committee. You could ask those questions here, or at programmers.stackexchange.com.

• @hvd, yes, in fact I know that if you enable `-Wsequence-point` for g++, it will warn you. Feb 10 '14 at 7:02
• "I'm sure g++, Clang, and MSVC will all do what you expected" I wouldn't trust a modern compiler. They're evil. For example they might recognize that this is undefined behaviour and assume this code is unreachable. If they don't do so today, they might do so tomorrow. Any UB is a ticking time bomb. Feb 10 '14 at 10:29
• @BlacklightShining "your answer is bad because it is not good" is not very useful feedback, is it? Feb 10 '14 at 13:06
• @BobJarvis The compiles has absolutely no obligation to generate even remotely correct code in the face of undefined behaviour. TIt can even assume that this code is never even called and thus replace the whole thing with a nop (Note that compilers actually make such assumptions in the face of UB). Therefore I'd say that the correct reaction to such a bug report can only be "closed, works as intended" Feb 10 '14 at 14:12
• @SchighSchagh Sometimes a rephrasing of the terms (which only on the surface appears to be a tautological answer) is what people need. Most people new to technical specifications think `undefined behavior` means `something random will happen`, which is far from the case most of the time. Feb 10 '14 at 17:38

A practical reason to not make an exception from the rules just because the two values are the same:

``````// config.h
#define VALUEA  1

// defaults.h
#define VALUEB  1

// prog.cpp
f(i = VALUEA, i = VALUEB);
``````

Consider the case this was allowed.

Now, some months later, the need arises to change

`````` #define VALUEB 2
``````

Seemingly harmless, isn't it? And yet suddenly prog.cpp wouldn't compile anymore. Yet, we feel that compilation should not depend on the value of a literal.

Bottom line: there is no exception to the rule because it would make successful compilation depend on the value (rather the type) of a constant.

EDIT

@HeartWare pointed out that constant expressions of the form `A DIV B` are not allowed in some languages, when `B` is 0, and cause compilation to fail. Hence changing of a constant could cause compilation errors in some other place. Which is, IMHO, unfortunate. But it is certainly good to restrict such things to the unavoidable.

• Sure, but the example does use integer literals. Your `f(i = VALUEA, i = VALUEB);` has definitely the potential for undefined behaviour. I hope you aren't really coding against values behind identifiers.
– Wolf
Feb 10 '14 at 10:38
• @Wold But the compiler doesn't see preprocessor macros. And even if this were not so, it is hard to find an example in any programming language, where a source code compiles until one changes some int constant from 1 to 2. This is simply unacceptable and unexplainable, while you see very good explanations here why that code is broken even with the same values.
– Ingo
Feb 10 '14 at 11:40
• Yes, the compiles does not see macros. But, was this the question?
– Wolf
Feb 10 '14 at 11:53
– Wolf
Feb 10 '14 at 12:45
• It could do `SomeProcedure(A, B, B DIV (2-A))`. Anyway, if the language states that CONST must be fully evaluated at compile time, then, of course, my claim is not valid for that case. Since it somehow blurs the distinction of compiletime and runtime. Would it also notice if we write `CONST C = X(2-A); FUNCTION X:INTEGER(CONST Y:INTEGER) = B/Y;` ?? Or are functions not allowed?
– Ingo
Feb 10 '14 at 13:08

The confusion is that storing a constant value into a local variable is not one atomic instruction on every architecture the C is designed to be run on. The processor the code runs on matters more than the compiler in this case. For example, on ARM where each instruction can not carry a complete 32 bits constant, storing an int in a variable needs more that one instruction. Example with this pseudo code where you can only store 8 bits at a time and must work in a 32 bits register, i is a int32:

``````reg = 0xFF; // first instruction
reg |= 0xFF00; // second
reg |= 0xFF0000; // third
reg |= 0xFF000000; // fourth
i = reg; // last
``````

You can imagine that if the compiler wants to optimize it may interleave the same sequence twice, and you don't know what value will get written to i; and let's say that he is not very smart:

``````reg = 0xFF;
reg |= 0xFF00;
reg |= 0xFF0000;
reg = 0xFF;
reg |= 0xFF000000;
i = reg; // writes 0xFF0000FF == -16776961
reg |= 0xFF00;
reg |= 0xFF0000;
reg |= 0xFF000000;
i = reg; // writes 0xFFFFFFFF == -1
``````

However in my tests gcc is kind enough to recognize that the same value is used twice and generates it once and does nothing weird. I get -1, -1 But my example is still valid as it is important to consider that even a constant may not be as obvious as it seems to be.

• I suppose that on ARM the compiler will just load the constant from a table. What you describe seems more like MIPS.
– ach
Feb 11 '14 at 20:04
• @AndreyChernyakhovskiy Yep, but in a case when it's not simply `-1` (that the compiler has stored somewhere), but it's rather `3^81 mod 2^32`, but constant, then the compiler might do exactly what's done here, and in some lever of omtimization, my interleave the call sequences to avoid waiting.
– yo'
Feb 14 '14 at 10:05
• @tohecz, yeah, I've checked it up already. Indeed, the compiler is too smart to load every constant from a table. Anyway, it would never use the same register to compute the two constants. This would just as surely 'undefine' the defined behaviour.
– ach
Feb 14 '14 at 13:25
• @AndreyChernyakhovskiy But you are probably not "every C++ compiler programmer in the world". Remember that there're machines with 3 short registers available for computations only.
– yo'
Feb 14 '14 at 13:26
• @tohecz, consider the example `f(i = A, j = B)` where `i` and `j` are two separate objects. This example has no UB. Machine having 3 short registers is no excuse for compiler to mix the two values of `A` and `B` in the same register (as shown in @davidf's answer), because it would break the program semantics.
– ach
Feb 15 '14 at 13:25

Behavior is commonly specified as undefined if there is some conceivable reason why a compiler which was trying to be "helpful" might do something which would cause totally unexpected behavior.

In the case where a variable is written multiple times with nothing to ensure that the writes happen at distinct times, some kinds of hardware might allow multiple "store" operations to be performed simultaneously to different addresses using a dual-port memory. However, some dual-port memories expressly forbid the scenario where two stores hit the same address simultaneously, regardless of whether or not the values written match. If a compiler for such a machine notices two unsequenced attempts to write the same variable, it might either refuse to compile or ensure that the two writes cannot get scheduled simultaneously. But if one or both of the accesses is via a pointer or reference, the compiler might not always be able to tell whether both writes might hit the same storage location. In that case, it might schedule the writes simultaneously, causing a hardware trap on the access attempt.

Of course, the fact that someone might implement a C compiler on such a platform does not suggest that such behavior shouldn't be defined on hardware platforms when using stores of types small enough to be processed atomically. Trying to store two different values in unsequenced fashion could cause weirdness if a compiler isn't aware of it; for example, given:

``````uint8_t v;  // Global

void hey(uint8_t *p)
{
moo(v=5, (*p)=6);
zoo(v);
zoo(v);
}
``````

if the compiler in-lines the call to "moo" and can tell it doesn't modify "v", it might store a 5 to v, then store a 6 to *p, then pass 5 to "zoo", and then pass the contents of v to "zoo". If "zoo" doesn't modify "v", there should be no way the two calls should be passed different values, but that could easily happen anyway. On the other hand, in cases where both stores would write the same value, such weirdness could not occur and there would on most platforms be no sensible reason for an implementation to do anything weird. Unfortunately, some compiler writers don't need any excuse for silly behaviors beyond "because the Standard allows it", so even those cases aren't safe.

The fact that the result would be the same in most implementations in this case is incidental; the order of evaluation is still undefined. Consider `f(i = -1, i = -2)`: here, order matters. The only reason it doesn't matter in your example is the accident that both values are `-1`.

Given that the expression is specified as one with an undefined behaviour, a maliciously compliant compiler might display an inappropriate image when you evaluate `f(i = -1, i = -1)` and abort the execution - and still be considered completely correct. Luckily, no compilers I am aware of do so.

It looks to me like the only rule pertaining to sequencing of function argument expression is here:

3) When calling a function (whether or not the function is inline, and whether or not explicit function call syntax is used), every value computation and side effect associated with any argument expression, or with the postfix expression designating the called function, is sequenced before execution of every expression or statement in the body of the called function.

This does not define sequencing between argument expressions, so we end up in this case:

1) If a side effect on a scalar object is unsequenced relative to another side effect on the same scalar object, the behavior is undefined.

In practice, on most compilers, the example you quoted will run fine (as opposed to "erasing your hard disk" and other theoretical undefined behavior consequences).
It is, however, a liability, as it depends on specific compiler behaviour, even if the two assigned values are the same. Also, obviously, if you tried to assign different values, the results would be "truly" undefined:

``````void f(int l, int r) {
return l < -1;
}
auto b = f(i = -1, i = -2);
if (b) {
formatDisk();
}
``````

C++17 defines stricter evaluation rules. In particular, it sequences function arguments (although in unspecified order).

`N5659 §4.6:15`
Evaluations A and B are indeterminately sequenced when either A is sequenced before B or B is sequenced before A, but it is unspecified which. [ Note: Indeterminately sequenced evaluations cannot overlap, but either could be executed first. —end note ]

`N5659 § 8.2.2:5`
The initialization of a parameter, including every associated value computation and side effect, is indeterminately sequenced with respect to that of any other parameter.

It allows some cases which would be UB before:

``````f(i = -1, i = -1); // value of i is -1
f(i = -1, i = -2); // value of i is either -1 or -2, but not specified which one
``````
• Thank you for adding this update for c++17, so I didn't have to. ;) Oct 26 '17 at 19:27
• Awesome, thanks a lot for this answer. Slight followup: if `f`'s signature were `f(int a, int b)`, does C++17 guarantee that `a == -1` and `b == -2` if called as in the second case? Nov 2 '17 at 2:46
• Yes. If we have parameters `a` and `b`, then either `i`-then-`a` are initialized to -1, afterwards `i`-then-`b` are initialized to -2, or the way around. In both cases, we end up with `a == -1` and `b == -2`. At least this is how I read "The initialization of a parameter, including every associated value computation and side effect, is indeterminately sequenced with respect to that of any other parameter". Nov 2 '17 at 22:25
• I think it has been the same in C since forever.
– fuz
Jul 13 '18 at 15:19

The assignment operator could be overloaded, in which case the order could matter:

``````struct A {
bool first;
A () : first (false) {
}
const A & operator = (int i) {
first = !first;
return * this;
}
};

void f (A a1, A a2) {
// ...
}

// ...
A i;
f (i = -1, i = -1);   // the argument evaluated first has ax.first == true
``````
• True enough, but the question was about scalar types, which others have pointed out means essentially int family, float family, and pointers. Feb 10 '14 at 14:30
• The real problem in this case is that the assignment operator is stateful, so even regular manipulation of the variable is prone to issues like this. Feb 10 '14 at 16:18

This is just answering the "I'm not sure what "scalar object" could mean besides something like an int or a float".

I would interpret the "scalar object" as a abbreviation of "scalar type object", or just "scalar type variable". Then, `pointer`, `enum` (constant) are of scalar type.

This is a MSDN article of Scalar Types.

• This reads a bit like a "link only answer". Can you copy the relevant bits from that link to this answer (in a blockquote)? Feb 10 '14 at 16:51
• @ColeJohnson This is not a link only answer. The link is only for further explanation. My answer is "pointer", "enum". Feb 10 '14 at 23:16
Actually, there's a reason not to depend on the fact that compiler will check that `i` is assigned with the same value twice, so that it's possible to replace it with single assignment. What if we have some expressions?
``````void g(int a, int b, int c, int n) {
• Don't need to prove Fermat's theorem: just assign `1` to `i`. Either both arguments assign `1` and this does the "right" thing, or the arguments assign different values and it's undefined behavior so our choice is still permitted.