37

I keep finding more idioms that lend themselves to std::exchange.

Today I found myself writing this in an answer:

do {
    path.push_front(v);
} while (v != std::exchange(v, pmap[v]));

I like it a lot more than, say

do {
    path.push_front(v);
    if (v == pmap[v])
        break;
    v= pmap[v];
} while (true);

Hopefully for obvious reasons.

However, I'm not big on standardese and I can't help but worry that lhs != rhs doesn't guarantee that the right-hand side expression isn't fully evaluated before the left-hand-side. That would make it a tautologous comparison - which would by definition return true.

The code, however, does run correctly, apparently evaluating lhs first.

Does anyone know

  • whether the standard guarantees this evaluation order
  • if it has changed in recent standards, which standard version first specified it?

PS. I realize that this is a special case of f(a,b) where f is operator!=. I've tried to answer my own query using the information found here but have failed to reach a conclusion to date:

14
  • 1
    Mmm... might be well formed if operator != is a member timsong-cpp.github.io/cppwp/n4868/expr.call#8 - It's certainly not more complex than the standard's own example Nov 28, 2022 at 14:08
  • 1
    I do not see any wording that mandates that the left side of != be sequenced before the right. C++17 added sequencing for some operations, but != does not appear to be among them. Nov 28, 2022 at 14:10
  • 1
    @rturrado I like to think that the loop is a lot clearer with the "atomic" (as in, single-statement) exchange. But yeah, it appears to be safer without. Which IMHO is the non-obvious part. The only reason I had the danger sensors going off is because I've learned painful C++ lessons in the past. But I expect the average programmer to have the same, completely intuitive expectation of what that code should do.
    – sehe
    Nov 28, 2022 at 14:49
  • 2
    @rturrado And yes, the double pmap[v] can be circumvented by adding a named variable. Alas, there is no way to constrain the scope of said variable. Re-writing as a for-loop (which is the usual) requires either making the push operation a side effect of the condition (which is objectively worse because that operation doesn't already exist with well-known semantics, unlike std::exchange) or ... duplicating that outside of the loop body... It's catch-22
    – sehe
    Nov 28, 2022 at 14:49
  • 1
    FWIW.
    – n. m.
    Nov 28, 2022 at 15:41

3 Answers 3

20

C++17 introduced rules on sequences. What was UB before is now well defined. This applies to arguments to function calls as well as a select assortment of operators:

sequenced before is an asymmetric, transitive, pair-wise relationship between evaluations within the same thread.

  • If A is sequenced before B (or, equivalently, B is sequenced after A), then evaluation of A will be complete before evaluation of B begins.

The built-in != however is not sequenced (see link above). A function call would be sequenced but the order of evaluation is not guaranteed:

  1. In a function call, value computations and side effects of the initialization of every parameter are indeterminately sequenced with respect to value computations and side effects of any other parameter.

(emphasis added)

To my reading, even if you wrote a wrapper function, your compiler would not be required to evaluate v first, then std::exchange(v, pmap[v]) and finally equal(..). And reversing the evaluation order, I believe, would change semantics in your example.

So sadly, as nice as std::exchange is, in this case, it is not guaranteed to do what you need it to.

6
  • Edit: Sorry I misread a point. Corrected answer.
    – bitmask
    Nov 28, 2022 at 14:17
  • 1
    Ha. I had that quote copied to comment just before you realized and started editing. Kinda sad. It looks like this is the state of affairs ¯\_(ツ)_/¯
    – sehe
    Nov 28, 2022 at 14:18
  • @sehe Yes, my brain somehow parsed the word "indeterminately" as "determinately". :)
    – bitmask
    Nov 28, 2022 at 14:19
  • 3
    @bitmask different calling conventions have different preferences for order of evaluation. One of the historically most popular is stack-based cdecl, which prefers right to left. Nov 28, 2022 at 14:23
  • 1
    @bitmask A long time ago, Hyman Rosen wrote a paper to mandate a strict right-to-left order of evaluation. That paper unfortunately went nowhere. Nov 28, 2022 at 15:52
16

For the built-in != operator, or an overload taking at least the first argument by value (i.e. operator !=(T, T)):

This is UB per [intro.execution]/10:

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

[...] If a side effect on a memory location is unsequenced relative to either another side effect on the same memory location or a value computation using the value of any object in the same memory location, and they are not potentially concurrent, the behavior is undefined.

(The != operator does not have any special sequencing properties.)

Whether != is overloaded for v's type does not affect sequencing rules (since you're not calling it using function call notation) ([over.match.oper]/2):

[...] the operator notation is first transformed to the equivalent function-call notation [...] However, the operands are sequenced in the order prescribed for the built-in operator.

(And even if you did use the function call notation, the operands would still be indeterminately sequenced, meaning no UB but no guarantee of consistent results either.)


In the case of an overload taking the operands by reference (such as operator !=(const T&, const T&) or T::operator !=(const T&) const):

The behavior is well-defined.

Binding a reference (directly) does not access the object (as in the case of v in your example), nor does calling a member function on it, so there's no conflict between the two operands. And the access that happens in the body of the function (the actual comparison) is sequenced after the initialization of its parameters ([intro.execution]/11):

When calling a function [...], every value computation and side effect associated with any argument expression [...] is sequenced before execution of every expression or statement in the body of the called function.

Which also means that the comparison will always take place after the side effects of both operands. In your example this means you'll always be comparing the post-exchange value of v to the value returned by exchange (v's previous one).


The above is true before C++17 as well, though for slightly different reasons.

In C++14, as opposed to C++17 ([expr]/2):

Overloaded operators obey the rules for syntax specified in Clause [expr], but the requirements of [...] evaluation order are replaced by the rules for function call.

...but the arguments in a function call are themselves unsequenced as opposed to indeterminately sequenced ([expr.call]/8):

The evaluations of the postfix expression and of the arguments are all unsequenced relative to one another.

(These quotes are from non-normative notes but they illustrate the point well.)

Which means the effect is still the same: operands are unsequenced, UB in the case where evaluating v accesses its value, well-defined otherwise. The only difference is that explicitly using function call syntax in the first case does not prevent UB.

2
  • Nice sources. It looks like c++17 made it unspecified rather than UB. That's an important difference. Is there a reason you call it UB?
    – sehe
    Nov 29, 2022 at 11:27
  • It's still UB if evaluating v accesses its value, which is true for the built-in operator or an overload which takes it by value. In the (typical) case of an overload that takes the operands by reference, the behavior is well-defined with predictable results. This is both pre- and post-C++17. I've expanded the answer slightly to elaborate more on the by-reference case.
    – duck
    Nov 29, 2022 at 14:10
2

Regardless of whether or not this works, it is almost completely unreadable code -- and remember that we write code mostly for humans, not compilers!

As a general rule, using conditionals that have side effects are often hard to read and understand because our brains are not equipped to do two things at once: Understand whether the condition is true or false, and also keep track of what changes. Do one thing at a time if you want others to easily understand what is happening. In your case, you are adding a third dimension to it: when something changes; using conditionals in which you have a function call that changes something, and comparing the changed result against something else is just impossible to read :-)

If you absolutely must use this idiom, separate the three parts:

do {
    path.push_front(v);
} while ([&v,&pmap]() mutable
         {
           auto old_v = v;  
           v = pmap[v];
           return v != old_v;
         } ());

This code is equivalent, of course, but I think it is far easier to read. Although I will claim that it is still harder to read than your alternative code without using std::exchange() :-)

5
  • Thank you +1. I came up with several versions not dissimilar to this one (though I like them all a bit better than the form presented here). Love that you unironically wrote an immediately invoked lambda in the condition of a do-while loop in c++ and called it "easier to read" :=P My version was a Very Bad Idea in C++. Readability wasn't the bad part. You can see which version I went with.
    – sehe
    Nov 29, 2022 at 2:02
  • (By the way I like your reasoning about what makes code understandable. I'm not sure what you refer to with "if you absolutely must use this idiom" - it seems you kept only the requirements/behavior, and yeah, that's a given of course)
    – sehe
    Nov 29, 2022 at 2:04
  • @sehe "this idiom" = "the do...while loop in which you do some work in the while condition". I wished that that could be done using a compound statement rather than having to declare then immediately invoke a lambda, but that's just how it is :-) Nov 29, 2022 at 3:45
  • 2
    I also wished that the condition in the trailing while would be in scope of the body of the loop, because then one could have moved the declaration of old_v into the body of the loop and referenced it from the while condition. That would also have avoided the lambda function. But that too just is what it is :-) Nov 29, 2022 at 3:46
  • 1
    [&]{ auto old_v = std::exchange(v, pmap[v]); return v != old_v; }() is a bit terser. Nov 29, 2022 at 10:51

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