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In C++, does the following have undefined behaviour:

int i = 0;
(i+=10)+=10;

There was some debate about this in the comments to my answer to What's the result of += in C and C++? The subtlety here is that the default response seems to be "yes", whereas it appears that the correct answer is "it depends on the version of the C++ standard".

If it does depend on the version of the standard, please explain where it's UB and where it's not.

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Which C++, the current one or the old one? –  Fanael May 18 '12 at 15:23
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@JohnDibling: I take it you think the answer is "yes". There's a pretty convincing argument in the comments to stackoverflow.com/a/10653994/367273 that the answer is, in fact, "no". –  NPE May 18 '12 at 15:23
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@Fanael: Both. The more complete the answer, the better. –  NPE May 18 '12 at 15:26
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@OnorioCatenacci: buy him the spec, then we may talk start talking about downvoting. –  Fanael May 18 '12 at 15:31
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Arguably, this is a dupe of the FAQ question on sequence points, which itself should be updated to reflect C++11's new rules with sequence-before and -after. But I don't think I'm ready to argue that just yet, it might be better to mark the existing FAQ question clearly as C++03, and start all over again for C++11. –  Steve Jessop May 18 '12 at 16:14

3 Answers 3

up vote 30 down vote accepted

tl;dr: The sequence of the modifications and reads performed in (i+=10)+=10 is well defined in both C++98 and C++11, however in C++98 this is not sufficient to make the behavior defined.

In C++98 multiple modifications to the same object without an intervening sequence-point results in undefined behavior, even when the order of those modifications is well specified. This expression does not contain any sequence points and so the fact that it consists of two modifications is sufficient to render its behavior undefined.

C++11 doesn't have sequence points and only requires that the modifications of an object be ordered with respect to each other and to reads of the same object to produce defined behavior.

Therefore the behavior is undefined in C++98 but well defined in C++11.


C++98

C++98 clause [expr] 5 p4

Except where noted, the order of evaluation of operands of individual operators and subexpressions of individual expression, and the order in which side effects take place, is unspecified.

C++98 clause [expr.ass] 5.17 p1

The result of the assignment operation is the value stored in the left operand after the assignment has taken place; the result is an lvalue

So I believe the order is specified, however I don't see that that alone is enough to create a sequence point in the middle of an expression. And continuing on with the quote of [expr] 5 p4:

Between the previous and next sequence point a scalar object shall have its stored value modified at most once by the evaluation of an expression.

So even though the order is specified it appears to me that this is not sufficient for defined behavior in C++98.


C++11

C++11 does away sequence points for the much clearer idea of sequence-before and sequenced-after. The language from C++98 is replaced with

C++11 [intro.execution] 1.9 p15

Except where noted, evaluations of operands of individual operators and of subexpressions of individual expressions are unsequenced. [...]

If a side effect on a scalar object is unsequenced relative to either another side effect on the same scalar object or a value computation using the value of the same scalar object, the behavior is undefined.

C++11 [expr.ass] 5.17 p1

In all cases, the assignment is sequenced after the value computation of the right and left operands, and before the value computation of the assignment expression.

So while being ordered was not sufficient to make the behavior defined in C++98, C++11 has changed the requirement such that being ordered (i.e., sequenced) is sufficient.

(And it seems to me that the extra flexibility afforded by 'sequence before' and 'sequenced after' has lead to a much more clear, consistent, and well specified language.)


It seems unlikely to me that any C++98 implementation would actually do anything surprising when the sequence of operations is well specified even if that is insufficient to produce technically well defined behavior. As an example, the internal representation of this expression produced by Clang in C++98 mode has well defined behavior and does the expected thing.

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"whereas in C++98 the value assigned to j is indeterminate but the behavior is not undefined" - this is incorrect. C++98 says that the previous value of "i" shall only be read to determine the value to be stored in a modification when there's no intervening sequence point. But in "(i+=1) + i", it is unspecified whether the "+ i" reads the previous or the next value of "i", so the consequence is there's undefined behavior. –  Johannes Schaub - litb May 18 '12 at 20:21
    
@JohannesSchaub-litb Could you give me a citation so I can see it in the C++98 standard in context? –  bames53 May 18 '12 at 20:36
    
it is right after the text you quoted that ends with "... shall have its stored value modified at most once by the evaluation of an expression.". –  Johannes Schaub - litb May 18 '12 at 20:38
    
@JohannesSchaub-litb I think you're probably right that the language was intended to mean that and that the requirement I had thought was new in C++11 isn't actually new. But the C++98 language definitely needed cleaning up because as written, "the prior value shall be accessed only to [...]," does not mean the same thing as "only the prior value shall be accessed." –  bames53 May 18 '12 at 21:00
    
@JohannesSchaub-litb However, if the intended meaning is "only the prior value shall be accessed" then does that mean that there's no requirement to access the prior value "only to determine the value to be stored?" I.e. am I allowed to access the prior value for other purposes? –  bames53 May 18 '12 at 21:06

In C++11 the expression is well defined and will result in i == 20.

From [expr.ass]/1:

In all cases, the assignment is sequenced after the value computation of the right and left operands, and before the value computation of the assignment expression.

This means that the assignment i+=1 is sequenced before the value computation of the left hand side of (i+=10)+=10, which is in turn sequenced before the final assignment to i.


In C++03 the expression has undefined behavior, because it causes i to be modified twice with no intervening sequence point.

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Does this answer apply to C++11 only, or to C++ in general ? –  Paul R May 18 '12 at 15:22
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@PaulR: C++11 only. C++03 had no notion of "sequenced after", it used sequence points. And in fact, in C++03 it is undefined, because there's no intervening sequence point between the assignments. –  Fanael May 18 '12 at 15:23
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Thanks - this should really be clarified in the answer then, as the question does not specify C++11. –  Paul R May 18 '12 at 15:25
    
@PaulR In C++98 the paragraph says "The result of the assignment operation is the value stored in the left operand after the assignment has taken place;" I'm not sure if that technically means there's a sequence point between assignments. At the very least I think this is under-specified in C++98. –  bames53 May 18 '12 at 15:27
    
... maybe it's worthy to mention that because the result of i+=10 is lvalue (i.e the "i" object itself) the modification of i cannot be treated as "independed" side effect (which is not sequenced with anything until final ";" ) –  user396672 May 18 '12 at 15:44

Maybe. It depends on C++ version.

In C++03, it's an obvious UB, there's no intervening sequence point between the assignments.

In C++11, as Mankarse explains, it's not undefined anymore — the parenthesized compound assignment is sequenced before the outer one, so it's okay.

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The C++03 answer raises a new question -- why did the assignment operator return an lvalue in C++03 if it was indeed undefined to modify its result? –  Mankarse May 18 '12 at 15:32
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@Mankarse: Now, that's a great question. –  NPE May 18 '12 at 15:33
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@Mankarse: presumably for consistency with simple assignment, so you can do both f(x = 5) and f(x += 5) with f wanting a T&. –  Fanael May 18 '12 at 15:35
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@Fanael: I know you're just guessing, but I don't follow your logic. If the assignment operators did not return an lvalue, then neither f(x = 5) nor f(x += 5) would compile (for f wanting a int&). How would that be any less consistent? –  Mankarse May 18 '12 at 15:56
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@Mankarse The given justification (which I don't really agree with) is to support things like int& f(int& i) { return i += 2; } –  James Kanze May 18 '12 at 16:27

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